TPS9900TPZPRQ1 [TI]
适用于 DLP553x-Q1 芯片组的 DLP® 系统管理和照明控制器
| PZP | 100 | -40 to 105;型号: | TPS9900TPZPRQ1 |
厂家: | TEXAS INSTRUMENTS |
描述: | 适用于 DLP553x-Q1 芯片组的 DLP® 系统管理和照明控制器 | PZP | 100 | -40 to 105 控制器 |
文件: | 总89页 (文件大小:4934K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
Support &
Community
Product
Folder
Order
Now
Tools &
Software
Technical
Documents
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
TPS99000-Q1 系统管理和照明控制器
1 特性
3 说明
1
•
•
适用于汽车 应用
具有符合 AEC-Q100 标准的下列特性:
TPS99000-Q1 系统管理和照明控制器是 DLP553x-Q1
芯片组的组成部分,其中还包含 DLPC230-Q1 DMD
显示控制器。 该芯片组的亮度要求范围典型值为 3 至
15,000 尼特,具有严格的颜色点控制,能够为平视显
示屏 (HUD) 应用提供支持所需的所有功能和超越典型
5000:1 显示器的调光要求。
–
温度 2 级:-40℃ 至 105℃ 的环境运行温度范
围
–
–
器件 HBM ESD 分类等级 2
器件 CDM ESD 分类等级 C4B
适用于 DLP®产品的汽车系统管理器件:
•
集成式 DMD 高压稳压器电源可提供 DMD 镜像基准电
压,满足严格容差的要求。电源序列发生器和监控器为
整个芯片组的加电和断电事件提供可靠协同。
–
–
高级电源监控、排序和保护电路
两个裸片温度监控器、MCU 外部看门狗计时
器、时钟频率监控器
TPS99000-Q1 照明控制器集成了一个 12 位 ADC、两
个 DAC(12 位和 10 位)以及两个高性能光电二极管
信号调节和跨阻放大器 (TIA),照明控制系统的核心组
件之一。该 ADC 能够自动对每个视频帧进行高达 63
次事件采样。
–
–
系统过亮检测
具有奇偶校验、校验和密码寄存器保护的 SPI
端口
–
另一个用于独立系统监控的 SPI 端口
•
•
片上 DMD 镜像电压稳压器
可生成 +16V、+8.5V 和 -10V DMD 控制电压
–
先进的系统状态监控电路可提供实时图像,以显示子系
统的运行情况,包括两个处理器看门狗电路、两个裸片
温度监控器、用于过压和欠压检测的综合电源监控、在
SPI 总线事务上通过字节级奇偶校验获得的校验和以及
密码寄存器保护、高亮监视器电路以及其他内置测试功
能。
可实现超过 5000:1 的调光范围并具有高位深度和
白平衡的高动态范围调光和颜色控制:
–
两个具有宽动态范围并支持多种光学设计的跨阻
放大器 (TIA)
–
–
–
每帧高达 63 个时间序列样本的 12 位 ADC
适用于颜色和脉冲控制的 DAC 和比较器功能
适用于 LED 和并联控制的 FET 驱动器
器件信息(1)
器件型号
封装
封装尺寸(标称值)
2 应用
TPS99000-Q1
HTQFP (100)
14.00mm × 14.00mm
•
•
•
宽视野和增强现实抬头显示 (HUD) 系统
(1) 如需了解所有可用封装,请参阅数据表末尾的可订购产品附
录。
汽车高级照明 应用 (高分辨率前照灯)
自适应远光灯 (ADB)
典型的独立系统
1
本文档旨在为方便起见,提供有关 TI 产品中文版本的信息,以确认产品的概要。 有关适用的官方英文版本的最新信息,请访问 www.ti.com,其内容始终优先。 TI 不保证翻译的准确
性和有效性。 在实际设计之前,请务必参考最新版本的英文版本。
English Data Sheet: DLPS039
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
目录
Interface ................................................................... 23
6.17 Timing Requirements - ADC Interface.................. 23
6.18 Switching Characteristics...................................... 23
Detailed Description ............................................ 24
7.1 Overview ................................................................. 24
7.2 Functional Block Diagram ....................................... 25
7.3 Feature Description................................................. 26
7.4 Device Functional Modes........................................ 50
7.5 Register Maps ........................................................ 52
Application and Implementation ........................ 55
8.1 Application Information............................................ 55
8.2 Typical Applications ............................................... 55
Power Supply Recommendations...................... 66
9.1 TPS99000-Q1 Power Supply Architecture.............. 66
9.2 TPS99000-Q1 Power Outputs ................................ 66
9.3 Power Supply Architecture...................................... 66
1
2
3
4
5
6
特性.......................................................................... 1
应用.......................................................................... 1
说明.......................................................................... 1
修订历史记录 ........................................................... 2
Pin Configuration and Functions......................... 3
Specifications......................................................... 9
6.1 Absolute Maximum Ratings ...................................... 9
6.2 ESD Ratings............................................................ 10
6.3 Recommended Operating Conditions..................... 10
6.4 Thermal Information................................................ 10
7
8
9
6.5 Electrical Characteristics - Transimpedance Amplifier
Parameters............................................................... 11
6.6 Electrical Characteristics - Digital to Analog
Converters................................................................ 13
6.7 Electrical Characteristics - Analog to Digital
Converter ................................................................. 14
6.8 Electrical Characteristics - FET Gate Drivers ......... 15
6.9 Electrical Characteristics - Photo Comparator........ 15
6.10 Electrical Characteristics - Voltage Regulators..... 16
10 Layout................................................................... 70
10.1 Layout Guidelines ................................................. 70
11 器件和文档支持 ..................................................... 75
11.1 器件支持................................................................ 75
11.2 商标....................................................................... 75
11.3 静电放电警告......................................................... 75
11.4 术语表 ................................................................... 75
12 机械、封装和可订购信息....................................... 75
12.1 Package Option Addendum .................................. 76
6.11 Electrical Characteristics - Temperature and Voltage
Monitors ................................................................... 17
6.12 Electrical Characteristics - Current Consumption . 18
6.13 Power-Up Timing Requirements........................... 19
6.14 Power-Down Timing Requirements ...................... 20
6.15 Timing Requirements - Sequencer Clock ............. 22
6.16 Timing Requirements - Host / Diagnostic Port SPI
4 修订历史记录
Changes from Revision E (June 2018) to Revision F
Page
•
•
•
Deleted TYP VSAT because it is not applicable given VOUTDAC MAX ....................................................................................... 11
Deleted TSLEW because it is redundant given TSET ............................................................................................................... 13
Added footnote regarding capacitor characteristics for voltage regulators .......................................................................... 16
Changes from Revision D (May 2018) to Revision E
Page
•
已更改 将器件状态从“预告信息”更改为“P生产数据”................................................................................................................ 1
2
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
5 Pin Configuration and Functions
PZP Package
100-Pin HTQFP
Top View
Copyright © 2015–2019, Texas Instruments Incorporated
3
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
Pin Functions - Initialization, Clock, and Diagnostics
PIN
TYPE
DESCRIPTION
NO.
6
NAME
WD1
WD2
I
Watch Dog Interrupt Channel 1
Watch Dog Interrupt Channel 2
7
I
8
PARK_Z
RESET_Z
INT_Z
O
O
O
DMD Mirror Parking Signal (active low)
9
Reset output to the DLPC230-Q1. TPS99000-Q1 controlled.
10
Interrupt output signal to DLPC230-Q1 (open drain). Recommended to pull
up to the DLPC230-Q1 3.3 V rail controlled by the TPS99000-Q1's
ENB_3P3V signal.
11
16
17
40
41
57
61
PROJ_ON
SEQ_START
SEQ_CLK
DMUX0
I
Input signal to enable/disable the IC and DLP projector
PWM Shadow Latch Control; indicates a Start of Sequence
Sequencer Clock
I
I
O
O
O
O
Digital test point output
DMUX1
Digital test point output
AMUX1
Analog Test Mux Output 1
AMUX0
Analog Test Mux Output 0
4
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
Pin Functions - Power and Ground
PIN
TYPE
DESCRIPTION
NO.
NAME
VSS_IO
13, 35
GND
POWER
GND
Ground Connection for Digital IO Interface
3.3 V power input for IO rail supply
14, 36
VDD_IO
DVSS
24
Digital Core Ground Return
25, 60, 75, 99
PBKG
GND
Substrate Tie and ESD Ground Return
3.3 V power input for digital core supply
26
42
DVDD
POWER
POWER
DRVR_PWR
6 V or 3.3 V power input for FET driver power. Supply for S_EN1, S_EN2,
R_EN, G_EN, & B_EN outputs
48
49
50
51
VSS_DRVR
GND
Ground Connection for FET driver power
DMD_VOFFSET
DMD_VBIAS
POWER
POWER
POWER
VOFFSET output rail. Connect a 1μF ceramic capacitor to ground
VBIAS output rail. Connect a 0.47μF ceramic capacitor to ground
DMD_VRESET
VRESET output rail. Connect a 1μF ceramic capacitor to ground. Connect to
DRST_HS_IND through external diode. Connect anode of diode to
DMD_VRESET.
53
DRST_PGND
VIN_DRST
VSS_DRST
AVDD
GND
POWER
GND
Power ground for DMD power supply. Connect to ground plane
6 V input for DMD power supply
55
56
Ground Supply for DMD power supply
3.3 V power supply input for analog circuit
Dedicated TIA Interface –8 V LDO output
Filter Cap Interface for 5 V TIA LDO
6 V power input for 5 V TIA LDO
59
POWER
POWER
POWER
POWER
GND
63
VLDOT_M8
VLDOT_5V
VIN_LDOT_5V
GND_LDO
64
65
66
Power ground return for LDO
67
VIN_LDOT_3P3V
VLDOT_3P3V
VSS_TIA2
POWER
POWER
GND
6 V power input for 3.3 V TIA LDO
68
Filter Cap Interface for 3.3 V TIA LDO
TIA2 Dedicated Ground
71
72
VSS_TIA1
GND
TIA1 Dedicated Ground
78, 100
AVSS
GND
Analog Ground
79
VIN_LDOA_3P3
VLDOA_3P3
VSSL_ADC
ADC_VREF
POWER
POWER
GND
6 V power input for dedicated ADC interface 3.3 V LDO supply
Dedicated ADC Interface 3.3 V LDO Filter Cap Output
External ADC Channel Bondwire and Lead Frame Isolation Ground
ADC Reference voltage output
80
81, 84, 87, 89, 91
95
POWER
Copyright © 2015–2019, Texas Instruments Incorporated
5
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
Pin Functions - Power Supply Management
PIN
TYPE
DESCRIPTION
NO.
1
NAME
ENB_1P1V
ENB_1P8V
ENB_3P3V
DRST_LS_IND
O
O
External 1.1 V Buck Enable. 3.3 V Output
2
External 1.8 V Buck Enable. 3.3 V Output
External 3.3 V Buck Enable. 3.3 V Output
3
O
52
ANA
Connection for the DMD power supply inductor (10μH). Connect a 330pF 50
V capacitor to ground. X7R recommended
54
58
DRST_HS_IND
VMAIN
ANA
I
Connection for the DMD power supply inductor (10μH)
Main intermediate voltage monitor input. Use external resistor divider to set
voltage input for brownout monitoring
62
96
97
98
VIN_LDOT_M8
V3P3V
O
I
Dedicated TIA Interface –8 V LDO external regulation FET drive signal
External 3.3 V Buck Voltage Monitor Input
V1P8V
I
External 1.8 V Buck Voltage Monitor Input
V1P1V
I
External 1.1 V Buck Voltage Monitor Input
6
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
Pin Functions - Illumination Control
PIN
TYPE
DESCRIPTION
NO.
12
15
18
19
20
21
22
23
37
38
39
NAME
COMPOUT
SYNC
O
O
I
Photodiode (PD) Interface High-speed comparator output
External LED buck driver sync strobe output
D_EN
LED Interface; Buck High-Side FET Drive Enable
LED Bypass Shunt Strobe Input
LED Enable Strobe 0 Input
S_EN
I
LED_SEL_0
LED_SEL_1
LED_SEL_2
LED_SEL_3
EXT_SMPL
DRV_EN
CMODE
I
I
LED Enable Strobe 1 Input
I
LED Enable Strobe 2 Input
I
LED Enable Strobe 3 Input
I
Reserved. Connect to ground
Drive enable for LM3409
O
O
Capacitor selection output (allows for a smaller capacitance to be used in CM
mode for less over/under shoot). Open drain
43
44
45
46
47
69
70
73
74
76
77
S_EN1
S_EN2
R_EN
G_EN
B_EN
O
O
Low resistance shunt NFET drive enable [High means shunt active]
High resistance shunt NFET drive enable [High means shunt active]
Red channel select. Drive for low side NFET
O
O
Green channel select. Drive for low side NFET
O
Blue channel select. Drive for low side NFET
TIA_PD2_FILT
TIA_PD2
O
TIA2 External Filter Cap - Low Bandwidth Sampling
TIA2 Photodiode Cathode Driver
I
TIA_PD1
I
TIA1 Photodiode Cathode Driver
TIA_PD1_FILT
R_IADJ
O
TIA1 External Filter Cap - Low Bandwidth Sampling
External resistance for IADJ voltage to current transformation
Current output used to adjust external LED controller drive current set point
ANA
ANA
IADJ
Copyright © 2015–2019, Texas Instruments Incorporated
7
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
Pin Functions - Serial Peripheral Interfaces
PIN
TYPE
DESCRIPTION
NO.
27
NAME
SPI1_CLK
I
I
SPI Control interface (DLPC230-Q1 Master, TPS99000-Q1 slave), clock input
28
SPI1_SS_Z
SPI1_DOUT
SPI1_DIN
SPI Control interface (DLPC230-Q1 Master, TPS99000-Q1 slave), chip select
(active low)
29
30
O
I
SPI Control interface (DLPC230-Q1 Master, TPS99000-Q1 slave), Transmit
data output
SPI Control interface (DLPC230-Q1 Master, TPS99000-Q1 slave), Receive
data input
31
32
33
34
SPI2_DIN
I
O
I
SPI Diagnostic Port (slave), Receive data input. For read-only monitoring
SPI Diagnostic Port (slave), Transmit data output. For read-only monitoring
SPI Diagnostic Port (slave), chip select (active low). For read-only monitoring
SPI Diagnostic Port (slave), clock input. For read-only monitoring
SPI2_DOUT
SPI2_SS_Z
SPI2_CLK
I
8
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
Pin Functions - Analog to Digital Converter
PIN
TYPE
DESCRIPTION
NO.
NAME
4
ADC_MISO
O
ADC 2-wire Interface - data Output. DLPC230-Q1 master, TPS99000-Q1
slave.
5
ADC_MOSI
I
ADC 2-wire Interface - data Input. DLPC230-Q1 master, TPS99000-Q1
slave.
82
83
85
86
88
90
92
93
94
LS_SENSE_N
LS_SENSE_P
ADC_IN1
I
I
I
I
I
I
I
I
I
Low side current sense ADC negative input, see Table 2
Low side current sense ADC positive input, see Table 2
External ADC Channel 1, see Table 2
ADC_IN2
External ADC Channel 2, see Table 2
ADC_IN3
External ADC Channel 3, see Table 2
ADC_IN4
External ADC Channel 4, see Table 2
ADC_IN5
External ADC Channel 5, see Table 2
ADC_IN6
External ADC Channel 6, see Table 2
ADC_IN7
External ADC Channel 7, see Table 2
6 Specifications
6.1 Absolute Maximum Ratings
over operating free-air temperature range (unless otherwise noted)(1)
MIN
–0.3
–0.3
–0.3
–0.1
MAX
4
UNIT
VDD_IO to VSS_IO
DVDD to DVSS
4
AVDD to DVSS
4
All "VSS" to other "VSS" (grounds)
0.1
All digital input signals to ground (WD1, WD2, ADC_MOSI,
PROJ_ON, SEQ_START, SEQ_CLK, SPI1_CLK, SPI1_DIN,
SPI1_SS, SPI2_DIN, SPI2_CLK, SPI2_SS, EXT_SMPL)
–0.3
3.6
DRVR_PWR to ground
VIN_LDO_5V
–0.3
–0.3
–0.3
–0.3
–0.3
–0.3
–0.3
–0.3
–0.3
–0.3
–18
7.5
7.5
5
V3P3V to ground
Input
voltage
V1P8V to ground
5
V
V1P1V to ground
5
VIN_LDOA_3P3 to ground
VIN_LDOT_3P3 to ground
ADC_IN(7:1) to ground
IADJ to ground
7.5
7.5
3.6
18
5
R_IADJ to ground
VIN_LDOT_M8 to ground
DRST_LS_IND to DRST_PGND
VIN_DRST to ground
VMAIN
0.3
27
7.5
7.5
7.5
130
150
–0.3
–0.3
–0.3
–0.3
–40
Outputs
INT_Z
V
Operating junction temperature, TJ
Storage temperature, Tstg
°C
°C
–65
(1) Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings
only, which do not imply functional operation of the device at these or any other conditions beyond those indicated under Recommended
Operating Conditions. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
Copyright © 2015–2019, Texas Instruments Incorporated
9
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
6.2 ESD Ratings
VALUE
±2000
±500
UNIT
Human-body model (HBM), per AEC Q100-002(1)
Electrostatic
discharge
V(ESD)
All pins
V
Charged-device model (CDM), per AEC
Q100-011
Corner pins
±750
(1) AEC Q100-002 indicates that HBM stressing shall be in accordance with the ANSI/ESDA/JEDEC JS-001 specification.
6.3 Recommended Operating Conditions
over operating free-air temperature range (unless otherwise noted)
MIN
NOM
MAX
UNIT
TEMPERATURE
TA
Operating ambient temperature(1)
Operating junction temperature
–40
–40
105
125
°C
°C
TJ
VOLTAGE
VDD_IO
DVDD
IO 3.3 V Voltage Supply
Digital 3.3 V Supply
3
3
3.3
3.3
3.3
3.6
3.6
3.6
1.6
7
V
V
V
V
V
V
V
V
V
AVDD
Analog 3.3 V Supply
3
ADC
ADC(7:1) Inputs
0.1
5.5
5.5
5.5
5.5
3
VIN_DRST
VIN_LDOT_5V
DMD Reset Regulator Input
Power supply input to 5 V TIA LDO
6
6
6
6
6
7
VIN_LDOA_3P3V Power supply input to 3.3 V ADC LDO
VIN_LDOT_3P3V Power supply input to 3.3 V TIA LDO
7
7
DRVR_PWR
Gate driver power supply
7
(1) –40°C to 105°C ambient, free air convection, AEC Q100 grade 2.
6.4 Thermal Information
TPS99000-Q1
THERMAL METRIC(1)(2)
PZP (HTQFP)
UNIT
100 PINS
6.9
RθJC(top)
RθJB
Junction-to-case (top) thermal resistance
Junction-to-board thermal resistance
°C/W
°C/W
°C/W
°C/W
°C/W
8.3
ψJT
Junction-to-top characterization parameter
Junction-to-board characterization parameter
Junction-to-case (bottom) thermal resistance
0.1
ψJB
8.2
RθJC(bot)
0.4
(1) For more information about traditional and new thermal metrics, see the Semiconductor and IC Package Thermal Metrics application
report (SPRA953).
(2) Operating ambient temperature is dependent on system thermal design. Operating junction temperature may not exceed its specified
range across ambient temperature conditions.
10
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
6.5 Electrical Characteristics - Transimpedance Amplifier Parameters
over operating free-air temperature range (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
TIA1 AND TIA2
IIN_TOT
TIA1 and TIA2 Combined Input
Current
0
7(1)
mA
TRANSIMPEDANCE AMPLIFIER #1 (TIA1)
IIN
TIA Input Current
Total Input Capacitance(3)
RGB trim <= 0.5x(2)
0
0.6
50
4.8
mA
pF
CIN
Allowable input capacitances from
board, connectors, photo diode,
and cables
10
140
TRIMRGB
RGB Trim, normal flux system
TIA Gain Tolerance (absolute)
0.2
0.5
3%
1
V/V
GAINTOLABS
Tolerance to specified gain target
per setting
–20%
20%
GAINTOLREL
TIA Gain Tolerance (relative)
Tolerance as a ratio to other
settings
TIA1 SLEW RATE
TIASLEW1
Low Gain Slew Rate, Output
Referred
<= 96 kV/A gain
> 96 kV/A gain
12
5
V/µs
V/µs
ns
TIASLEW2
TIADELAY
High Gain Slew Rate, Output
Referred
TIA Pad to COMPOUT Pad Delay, max slew rate input, 20 pF load,
DM min, Falling Edge 100 mV minimum over trip point
40
64
TIADELAYCM
TIA Pad to COMPOUT Delay. CM CM max current
100
ns
TIA1 EFFECTIVE GAIN
Gain Setting 0
Trim set to 1.0
Trim set to 1.0
Trim set to 1.0
Trim set to 1.0
Trim set to 1.0
Trim set to 1.0
Trim set to 1.0
Trim set to 1.0
Trim set to 1.0
Trim set to 1.0
Trim set to 1.0
Trim set to 1.0
Trim set to 1.0
Trim set to 1.0
0.6
1.2
0.75
1.5
3
0.9
1.8
kV/A
kV/A
kV/A
kV/A
kV/A
kV/A
kV/A
kV/A
kV/A
kV/A
kV/A
kV/A
kV/A
kV/A
Gain Setting 1
Gain Setting 2
Gain Setting 3
Gain Setting 4
Gain Setting 5
Gain Setting 6
Gain Setting 7
Gain Setting 8
Gain Setting 9
Gain Setting 10
Gain Setting 11
Gain Setting 12
Gain Setting 13
2.4
3.6
4.8
6
7.2
7.2
9
10.8
14.4
21.6
28.8
43.2
57.6
86.4
115.2
172.8
345.6
9.6
12
18
24
36
48
72
96
144
288
14.4
19.2
28.8
38.4
57.6
76.8
115.2
230.4
(1) For applications requiring greater than 7 mA combined TIA current, contact TI for details.
(2) Maximum input current decreases linearly in proportion to the selected trim value, with a lower maximum value of 2.4 mA occurring
when the trim is 1.0×.
(3) Large capacitive loads could impact system performance.
Copyright © 2015–2019, Texas Instruments Incorporated
11
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
Electrical Characteristics - Transimpedance Amplifier Parameters (continued)
over operating free-air temperature range (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
TRANSIMPEDANCE AMPLIFIER #2 (TIA2)
IIN
TIA Input Current
RGB trim <= 0.5x(2)
0
4.8
1
mA
V/V
TRIMRGB
TIA2 SLEW RATE
TIA2SLEW
RGB Trim, normal flux system
0.2
Slew Rate, Output Referred
All gains
1
V/µs
TIA2 EFFECTIVE GAIN
Gain Setting 0
Trim set to 1.0
Trim set to 1.0
Trim set to 1.0
Trim set to 1.0
Trim set to 1.0
Trim set to 1.0
Trim set to 1.0
Trim set to 1.0
Trim set to 1.0
Trim set to 1.0
Trim set to 1.0
Trim set to 1.0
Trim set to 1.0
Trim set to 1.0
0.6
1.2
0.75
1.5
3
0.9
1.8
kV/A
kV/A
kV/A
kV/A
kV/A
kV/A
kV/A
kV/A
kV/A
kV/A
kV/A
kV/A
kV/A
kV/A
Gain Setting 1
Gain Setting 2
Gain Setting 3
Gain Setting 4
Gain Setting 5
Gain Setting 6
Gain Setting 7
Gain Setting 8
Gain Setting 9
Gain Setting 10
Gain Setting 11
Gain Setting 12
Gain Setting 13
2.4
3.6
4.8
6
7.2
7.2
9
10.8
14.4
21.6
28.8
43.2
57.6
86.4
115.2
172.8
345.6
9.6
12
18
24
36
48
72
96
144
288
14.4
19.2
28.8
38.4
57.6
76.8
115.2
230.4
12
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
6.6 Electrical Characteristics - Digital to Analog Converters
over operating free-air temperature range (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
PHOTO FEEDBACK 12 BIT DAC
VOUTDAC Max
VOUTDAC Min
tSET
Output Range max
1.96
–0.1
0
2
0
2.04
0.1
V
V
Output Range min
Settling Time
Full-range step response, To
within ±2%
500
ns
INL
Integral Non-Linearity
Differential Non-Linearity
Offset Error
–3.5
–3.5
–100
–100
–5
3.5
3.5
100
100
5
LSB
LSB
DNL
VOFF
mV
ZEROERR
GAINERR
FSERR
Zero-scale Error
mV
Gain Error
%V/code
%FSR
µV/°C
Full-scale Error
–2
2
ZEROERRDFT
GAINTEMP
Zero-scale Error Drift
Gain Temperature Coefficient
–50
–52
20
0
50
52
ppm
FSR/°C
CURRENT CONTROL 10 BIT DAC
VOUTDAC Max
VOUTDAC Min
tSET
Output Range max
1.96
–0.1
0
2
0
2.04
0.1
V
V
Output Range min
Settling Time
Full-range step response to within
±2%
1000
ns
INL
Integral Non-Linearity
Differential Non-Linearity
Offset Error
–2
–2
2
2
LSB
LSB
DNL
VOFF
–100
–100
–5
100
100
5
mV
ZEROERR
GAINERR
FSERR
Zero-scale Error
mV
Gain Error
%V/code
%FSR
µV/°C
Full-scale Error
–2
2
ZEROERRDFT
GAINTEMP
Zero-scale Error Drift
Gain Temperature Coefficient
–50
-–52
20
0
50
52
ppm
FSR/°C
OVERBRIGHTNESS DETECTOR 8 BIT DAC
VOUTDAC max
VOUTDAC min
tOBDAC
Output Range max
Output Range min
1.95
–0.1
2
0
2.05
0.1
V
V
Over-brightness DAC Adjustment
Time
From input code mux input change
to 90/10 settling at analog output
1000
µs
INL
Integral Non-Linearity
Differential Non-Linearity
Offset Error
–1
–0.5
–100
–100
–5
1
0.5
100
100
5
LSB
LSB
DNL
VOFF
mV
ZEROERR
GAINERR
FSERR
Zero-scale Error
mV
Gain Error
%V/code
%FSR
µV/°C
Full-scale Error
–3
3
ZEROERRDFT
GAINTEMP
Zero-scale Error Drift
Gain Temperature Coefficient
–50
–52
20
0
50
52
ppm
FSR/°C
Copyright © 2015–2019, Texas Instruments Incorporated
13
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
6.7 Electrical Characteristics - Analog to Digital Converter
over operating free-air temperature range (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
12 BIT ADC(1)
VINPUT
INL
Input Range(2)
0.1
–4
1.6
4
V
LSB
LSB
bits
µs
Integral Non-Linearity
Differential Non-Linearity
Effective Number Of Bits
S/H Sampling Period
S/H Delay before conversion starts
S/H Holding Period
Over valid input range VINPUT
DNL
–2.5
10
2.5
ENOB
tSAMPLE
tDELAY
tSHOLD
tCONV
12
0.4
0.4
5.2
12.8
2.8
µs
102.4
102.4
0.8
245
µs
Conversion Period
µs
VREF
Measurement Reference
ADC reference voltage is doubled
to 1.6 V
0.784
0.816
V
VOFFS
Offset
–20
2
20
2
LSB
Gain Error
"ADC_IN(7:1) Inputs
%FSR
(1) ADC specifications refer to ADC core behavior, presume ideal clocks and IC input power conditions, unless otherwise noted.
(2) Results in invalid ADC codes below 256.
14
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
6.8 Electrical Characteristics - FET Gate Drivers
over operating free-air temperature range (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
LED CONTROL SIGNAL FET GATE DRIVERS
QSEN
ZSEN
S_EN1/2 Load Gate Charge
12
12.3
10.7
4.85
4.6
16.5
nC
Ω
S_EN1/2 Pull-up Gate Drive Output
Impedance
3.3 V domain(1)
6 V domain(2)
3.3 V domain(1)
6 V domain(2)
Ω
ZSEN
S_EN1/2 Pull-down Gate Drive Output
Impedance
Ω
Ω
TSEN
S_EN1/2 Pull-up Transition Time
S_EN1/2 Pull-down Transition Time
3.3 V domain, with max total gate
charge load of 2.5 nF(1)
49.5
45
66
82.5
75
ns
6 V domain, with max total gate charge
load of 2.5 nF(2)
60
27
25
ns
ns
ns
TSEN
3.3 V domain, with max total gate
charge load of 2.5 nF(1)
20.25
18.75
33.75
31.25
6 V domain, with max total gate charge
load of 2.5 nF(2)
ZRGB
ZRGB
TRGB
RGB_EN Pull-up Output Impedance
RGB_EN Pull-down Output Impedance
3.3 V domain(1)
6 V domain(2)
3.3 V domain(1)
6 V domain(2)
50.8
43.6
4.85
4.6
Ω
Ω
Ω
Ω
RGB_EN Pull-up Falling Transition Time 3.3 V domain, with max total gate
charge load of 2.5 nF(1)
198.75
180
265
331.25
300
ns
6 V domain, with max total gate charge
load of 2.5 nF(2)
240
27
ns
ns
ns
TRGB
RGB_EN Pull-down Falling Transition
Time
3.3 V domain, with max total gate
charge load of 2.5 nF(1)
20.25
18.75
33.75
31.25
6 V domain, with max total gate charge
load of 2.5 nF(2)
25
(1) DRVR_PWR Supply Voltage is between 3 V and 3.6 V.
(2) DRVR_PWR Supply Voltage is between 5.5 V and 7.5 V.
6.9 Electrical Characteristics - Photo Comparator
over operating free-air temperature range (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
PHOTO FEEDBACK COMPARATOR
VOFF
Offset Voltage
Hysteresis
–10
10
10
mV
mV
THYST
20
Copyright © 2015–2019, Texas Instruments Incorporated
15
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
6.10 Electrical Characteristics - Voltage Regulators
over operating free-air temperature range (unless otherwise noted)
PARAMETER
VOFFSET REGULATOR
TEST CONDITIONS
MIN
TYP
MAX
UNIT
VOUT
Output Voltage
Output Current(1)
Across load conditions
8.25
0.1(2)
8.5
8.75
16.3
V
IOUT
mA
VPGTHRESHR
Powergood Threshold, VOUT
Rising
86%
66%
1
VPGTHRESHF
Powergood Threshold, VOUT
Falling
Output Capacitor(3)
COUT
µF
µs
TDISC
Discharge Time
COUT = 1 µF
260
VBIAS REGULATOR
VOUT
Output Voltage
Output Current(1)
15.5
0.1(2)
16
16.5
1.5
V
IOUT
mA
VPGTHRESHR
Powergood Threshold, VOUT
Rising
86%
66%
0.47
VPGTHRESHF
Powergood Threshold, VOUT
Falling
Output Capacitor(3)
COUT
µF
µs
TDISC
Discharge Time
COUT = 0.47 µF
260
VRESET REGULATOR
VOUT
Output Voltage
–10.5
–17.6
–10
–9.5
–0.1(2)
V
IOUT
Output Current(4)(1)
Powergood Threshold
Output Capacitor(3)
Discharge Time
mA
VPGTHRESHR
COUT
80%
1
µF
µs
TDISC
COUT = 1 µF
Unloaded
260
NEGATIVE 8 V PHOTO DIODE LDO
VIN
Input Voltage
Output Voltage
Output Current
Input Ripple
–10
–8
V
V
VOUT
IOUT
–8.5
–6
–7.5
100
mA
mVpp
VIRIPPLE
(1) VOFFSET, VBIAS, and VRESET are designed to supply the DMD and Negative 8 V LDO only, and should not be connected to
additional loads.
(2) Pull down resistors required to meet minimum current requirement.
(3) The capacitance value of some ceramic capacitor types can diminish drastically depending on the applied DC voltage and temperature.
TI recommends X7R dielectric capacitors to minimize capacitance loss over voltage bias and temperatures. Using a higher voltage rated
part and/or a larger package size also helps minimize the capacitance reduction at the applied DC voltage. Refer to the
DLP5531Q1EVM for suggested components.
(4) VRESET current supplies both DMD and Negative 8-V LDO.
16
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
6.11 Electrical Characteristics - Temperature and Voltage Monitors
over operating free-air temperature range (unless otherwise noted)
PARAMETER
TEMPERATURE MONITOR
TEST CONDITIONS
MIN
TYP
MAX
UNIT
TEMPWARN
TEMPEMRG
Thermal Warning Threshold
Junction Temperature
135
150
°C
°C
Thermal Emergency Threshold Junction Temperature
1.1 V SUPPLY MONITOR
VTRIPN
Negative Trip Threshold
Negative going only
0.95
0.98
2%
1.01
V
VTRIPHYST
Hysteresis
Positive going threshold,
amount higher than negative trip
voltage
tGLITCH
Glitch Suppression
Size of glitch ignored (no reset)
with 2% overdrive
20
1000
µs
V
1.8 V SUPPLY MONITOR
VTRIPN
Negative Trip Threshold
Negative going only
1.552
1.6
2%
1.648
VTRIPHYST
Hysteresis
Positive going threshold,
amount higher than negative trip
voltage
tGLITCH
Glitch Suppression
Size of glitch ignored (no reset)
with 2% overdrive
20
1000
3.03
µs
V
3.3 V SUPPLY MONITOR
VTRIPN
Negative Trip Threshold
Negative going only
2.852
2.93
2%
VTRIPHYST
Hysteresis
Positive going threshold,
amount higher than negative trip
voltage
tGLITCH
Glitch Suppression
Size of glitch ignored (no reset)
with 2% overdrive
20
1000
µs
VMAIN SYSTEM INPUT SUPPLY MONITOR
VMAINTHRSH
VMAIN Threshold
External resistor divider used to
translate VMAIN
1.2125
20
1.25
1.2875
1000
V
tMAINGLITCH
VMAIN Glitch Suppression
At 2% overdrive
µs
Copyright © 2015–2019, Texas Instruments Incorporated
17
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
UNIT
6.12 Electrical Characteristics - Current Consumption
PARAMETER
TEST CONDITIONS
MIN
TYP(1)
MAX(2)
SUM OF 3.3 V SUPPLY PINS: DVDD, VDD_IO, AND AVDD
System off
System on
TIA #1
PROJ_ON Low
1.5
3.5
1
2
4
1
1
mA
mA
mA
mA
Display On state, no TIAs enabled
Additional current from enabling TIA #1
Additional current from enabling TIA #2
TIA #2
1
SUM OF 6 V SUPPLY PINS: DRVR_PWR, VIN_DRST, VIN_LDOT_5V, VIN_LDOT_3P3V, AND VIN_LDOA_3P3V
System off
System on(3)
TIA #1
PROJ_ON Low
1
98
20
20
2
119
25
mA
mA
mA
mA
Display On state, no TIAs enabled
Additional current from enabling TIA #1
Additional current from enabling TIA #2
TIA #2
25
(1) Typical measurements performed at 25°C and nominal voltage.
(2) Measurements taken at –40°C, 25°C, and 105°C. 3.3 V inputs measured at 3 V, 3.3 V, 3.6 V. 6 V inputs measured at 5.5 V, 6 V, and 7
V. The maximum current draw of all these conditions is shown.
(3) This number represents the current at the input to the TPS99000-Q1 when the DMD voltage rails output the maximum current as listed
in the respective sections of this datasheet. This number is the combination of the measured current when the DMD voltage regulator is
unloaded (35 mA typical, 56 mA max) and the estimated current draw on the 6 V supply when the DMD voltage regulator outputs the
maximum current (63 mA). The estimated current draw is calculated by the equation I6V=[(16/6)*IVBIAS+(8.5/6)*IVOFFSET+(-
10/6)*IVRESET]/η where η = 0.9. In order to calculate the power dissipation of the TPS99000-Q1 in this condition, multiply the current from
the unloaded condition by the input voltage, and add the current from the DMD voltage regulator multiplied by the input voltage
multiplied by (1-η).
18
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
6.13 Power-Up Timing Requirements
TYP
UNIT
ten_dly
PROJ_ON to 1.1 V enable. This includes PROJ_ON tglitch Rising edge of PROJ_ON to rising edge of 1.1
11
ms
time.
V enable.
(1)(2)
tmon1
tmon2
tmon3
tw1
Maximum time for 1.1 V rail to reach voltage threshold
after enable has been asserted. This delay length will
occur even if 1.1 V meets threshold earlier.
Rising edge of ENB_1P1V to internal 1.1 V
monitor test.
10
10
10
10
ms
ms
ms
ms
(1)(2)
(1)(2)
Maximum time for 1.8 V rail to reach voltage threshold
after enable has been asserted. This delay length will
occur even if 1.8 V meets threshold earlier.
Rising edge of ENB_1P8V to internal 1.8 V
monitor test.
Maximum time for 3.3 V rail to reach voltage threshold
after enable has been asserted. This delay length will
occur even if 3.3 V meets threshold earlier.
Rising edge of ENB_3P3V to internal 3.3 V
monitor test.
RESETZ delay after voltage testing completion.
Completion of 3.3 V monitor test to RESETZ
rising edge.
(1) V1P1V, V1P8V, and V3P3V rails can be enabled prior to the TPS99000-Q1 assertion of their respective enable signal if required for
system power design. If necessary, ENB_1P1V may be connected to the 1.1 V, 1.8 V, and 3.3 V external supply enables.
(2) If any voltage threshold is not met within the specified time, the TPS99000-Q1 will not de-assert RESETZ. The power-up procedure
must be fully restarted in this situation.
Figure 1. Power Up Timing
Copyright © 2015–2019, Texas Instruments Incorporated
19
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
6.14 Power-Down Timing Requirements(1)
MIN
MAX
UNIT
tvhold1
Host voltage hold time after VMAIN minimum
threshold reached.
VMAIN threshold to 6 V and 3.3 V
power loss.(2)(3)
900
μs
tmon4(max) + tpark(max) + tw2(max)
tvhold2
Host voltage hold time after PROJ_ON de-
asserted.
tmon5(max) + tpark(max) + tw2(max)
VMAIN threshold to 6 V and 3.3 V
power loss.(2)(3)
1.78
52
ms
tmon4
tmon5
tpark
VMAIN monitoring time.
PROJ_ON de-assertion reaction time.
DMD Park time.
Minimum voltage trip threshold to
PARKZ falling edge.
120
1
μs
ms
μs
Falling edge of PROJ_ON to PARKZ
falling edge.
PARKZ falling edge to start
DMD_VOFFSET discharge.
280
260
tdischarge DMD voltage rail discharge time.
VOFFSET Cout= 1 μF
VRESET Cout= 1 μF
VBIAS Cout= 0.47 μF
μs
(4)
tw2
DMD voltage disable to RESETZ de-assertion. Start of DMD voltage rail discharge
to RESETZ falling edge.
500
μs
(1) There are two methods for initiating the power down sequence:
(a) VMAIN voltage decreases below its minimum threshold. This is typical if the TPS99000-Q1 is expected to initiate the power down
sequence when main power is removed from the system. Note that the 6 V and 3.3 V input rails must remain within operating range
for a specified period of time after the power-down sequence begins.
(b) PROJ_ON low. This is allows a host controller to initiate power down through a digital input to the TPS99000-Q1.
(2) 6 V input rails include DRVR_PWR, VIN_DRST, VIN_LDOT_5V, VIN_LDOA_3P3V, VIN_LDOT3P3V.
(3) 3.3 V input rails include VDD_IO, DVDD, AVDD.
(4) The DMD specifies a maximum absolute voltage difference between VBIAS and VOFFSET. In order to remain below this maximum
voltage difference, VBIAS must discharge faster than VOFFSET. This is accomplished by using a smaller Cout capacitance for VBIAS in
order to allow it to discharge quicker than VOFFSET.
20
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
Voltage Monitor
Threshold
VMAIN
6V In
tvhold1
Host
Control
3.3V In
PROJ ON
tmon4
PARKZ
DMD_VOFFSET
DMD_VBIAS
DMD_VRESET
RESETZ
tdischarge
tpark
tw2
ENB_1P1V
ENB_1P8V
ENB_3P3V
Figure 2. Power Down Timing - VMAIN Trigger
Copyright © 2015–2019, Texas Instruments Incorporated
21
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
Figure 3. Power Down Timing - PROJ_ON Trigger
6.15 Timing Requirements - Sequencer Clock
MIN
NOM
MAX
UNIT
ƒSEQ_CLK
tJPP
SEQ_CLK Frequency
30.00
MHz
SEQ_CLK Jitter (peak to peak)
–3%
–2%
25
3%
0%
ƒSS
SEQ_CLK allowable spread spectrum
SEQ_CLK Spread Spectrum Modulation Frequency
SEQ_CLK Spread Spectrum Modulation Frequency Steps
ƒSSMOD
ƒSSSTEPS
100
kHz
50
steps
22
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
6.16 Timing Requirements - Host / Diagnostic Port SPI Interface
MIN
31
10
10
0
NOM
MAX
UNIT
ns
tSPICPER
tSPICHIGH
tSPICLOW
tSPIDOUT
tSSSETUP
tSSHOLD
SPI CLK Cycle Time
33
SPI CLK High Time
ns
SPI CLK Low Time
ns
CLK Falling to DOUT
15
ns
SPI SS_Z to CLK Rising Setup Time
SPI CLK Rising to SS_Z Hold Time
SPI DIN to CLK Rising Setup Time
SPI CLK Rising to DIN Hold Time
5
ns
5
ns
tDINSETUP
tDINHOLD
5
ns
5
ns
Figure 4. DLPC230-Q1 Diagnostic Interface Timing
Figure 5. Chip Select Setup and Hold Timing
6.17 Timing Requirements - ADC Interface
MIN
5
NOM
MAX
UNIT
ns
tADCDINSETUP
tADCDINHOLD
tADCDOUT
ADC DIN to CLK Rising Setup Time
ADC CLK Rising to DIN Hold Time
CLK Rising to DOUT
5
ns
0
15
ns
6.18 Switching Characteristics
over operating free-air temperature range (unless otherwise noted)
PARAMETER
INTERNAL CLOCK
ƒOSC Internal Oscillator Frequency
TEST CONDITIONS
MIN
TYP
MAX
UNIT
1.76
2
2.24
MHz
Copyright © 2015–2019, Texas Instruments Incorporated
23
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
7 Detailed Description
7.1 Overview
The TPS99000-Q1 is an integral component of the DLP553x-Q1 chipset, which also includes the DLPC230-Q1
DMD display controller. It provides features to support ultra-wide dimming requirements, which are unique to
automotive. The TPS99000-Q1 also provides a high-voltage, high-precision, three-rail regulator to cost-effectively
create DMD mirror control voltages (16 V, 8.5 V, –10 V). A complete system power monitor and DMD mirror
parking solution is included to increase system robustness and reduce cost. In addition, the TPS99000-Q1
includes numerous system monitoring and diagnostic features, such as configurable ADCs, TIAs, and
watchdogs.
An integrated 12-bit ADC supports the illumination system control, and provides useful information about the
operating condition of the system. Several external ADC channels are included for general usage (LED
temperature measurement, etc). One of the external ADC channels includes a differential input amplifier and is
dedicated to LED current measurement. The DLPC230-Q1 and TPS99000-Q1 ADC control blocks support up to
63 samples per video frame, with precise hardware alignment of samples to the DMD sequence timeline. This
information is available to the color control software in the DLPC230-Q1 where it can be used to counteract
effects of temperature and LED aging to maintain brightness and white point targets.
Two SPI buses are included. The first bus is intended for command and control, and the second is a read-only
bus for optional redundant system condition monitoring. The SPI ports include support for byte-level parity
checking.
Two transimpedance amplifiers are included. The first TIA is dedicated to illumination control, and the second is
available and reconfigurable for general usage, such as redundancy, ambient light detection, and output light
validation. An over-brightness detector is included to provide a hardware redundant check of LED brightness.
Two windowed watchdog circuits are included to provide validation of DLPC230-Q1 microprocessor operation
and monitoring of DMD sequencer activity. The TPS99000-Q1 also includes on-die temperature threshold
monitoring and a monitor circuit to validate the external clock ratio (of the SEQ_CLK) against an internal
oscillator.
24
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
7.2 Functional Block Diagram
Copyright © 2015–2019, Texas Instruments Incorporated
25
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
7.3 Feature Description
7.3.1 Illumination Control
The illumination control function includes all blocks needed to generate light for the DLP subsystem. The system
is designed to support automotive applications requiring precise control of color and brightness over a wide
dimming range. The complete dimming solution consists of hardware features included in both the DLPC230-Q1
and TPS99000-Q1 along with DMD sequence data stored in the DLPC230-Q1. These elements work together to
provide a usable system dimming range of over 5000:1, with up to 8 bits per color supported.
The illumination control function operates in two distinct modes to cover the full dimming range. These modes
are referred to as continuous mode (CM) and discontinuous mode (DM).
~16:1, continuous mode
~16:1, discontinuous mode
Figure 6. Comparison of Continuous and Discontinuous Mode Operation
Continuous mode features:
•
•
•
High- to mid-brightness levels
Rectangular light pulses created for each color
Pulse amplitude and pulse width varied to adjust brightness level
Discontinuous mode features:
•
•
•
Mid- to low-brightness levels
A series of small triangular light pulses created for each color
Number of pulses, pulse height, and LED current varied to adjust brightness level
The illumination control loop regulates current supplied to the LEDs through a real-time photo feedback control
loop. A broadband photodiode is placed in the illumination path of the DLP subsystem in a location that receives
light from all three red/green/blue LEDs. For continuous mode operation, photo feedback is used to create a real-
time hysteretic control loop to set the brightness levels for each LED. In discontinuous mode, photo feedback is
used to set a peak brightness threshold for each light pulse.
To support illumination control, the TPS99000-Q1 includes numerous high performance analog and mixed signal
blocks. These blocks include:
•
A high performance, ultra-wide dynamic range transimpedance amplifier (TIA) to convert photodiode current
to a voltage, representing real-time LED brightness
•
•
•
•
•
•
A high-speed comparator for photo feedback control
A 12-bit DAC for photo feedback reference
A 10-bit DAC for peak current limit adjustment
Sync and drive enable outputs for synchronizing an external high-side PFET buck controller (LM3409)
External FET drivers and control logic for selection of LEDs (FETs are external, but the drivers are internal)
Two current shunt (by-pass) path FET controls, used to pre-regulate inductor current while light is disabled
between colors, and to enable discontinuous mode operation
•
•
•
A multi-purpose 12-bit ADC block with a dedicated two wire Kelvin input channel specifically for measuring
LED current
Hardware sample timer block that works in conjunction with DLPC230-Q1 to provide configurable hardware
timed samples of LED current and voltage, temperature, etc.
RGB specific multiplexed settings for most parameters, enabling independent control parameter optimization
per color
26
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
Feature Description (continued)
7.3.1.1 Illumination System High Dynamic Range Dimming Overview
This section provides a generalized overview, describing the concepts to provide a framework for understanding
how the functions within the TPS99000-Q1 support the high dynamic dimming scheme of the full chipset and
software.
A Head-Up Display (HUD) system must typically meet a target white point requirement over a wide range of
brightness. Covering a wide brightness range requires a combination of continuous and discontinuous modes.
Continuous mode will utilize different combinations of RGB sequence duty cycles, time attenuation, and
amplitude attenuation. Discontinuous mode will utilize different combinations of the number of discrete pulses of
light, photo feedback (TIA) gain, peak current limit settings, and light amplitude DAC settings. These adjustments
can be categorized as coarse adjustments and fine adjustments.
Coarse adjustments include:
•
•
Illumination Bin – Selects the DMD duty cycle, LED duty cycle, and the number of pulses (DM only).
LED Current Limits – In CM, this specifies the maximum current each LED can operate with. Used to
prevent damage to the LED. In DM, specifies pre-charge inductor current used to generate pulses.
Determines shape/overshoot of pulse.
•
TIA Gain – The TIA design supports a wide range of gain settings—14 in total—to cover a wide range of
photodiode current levels. Higher gain settings result in lower LED output for a given feedback voltage.
Fine adjustments include:
•
Photo Feedback DAC Settings – This function is implemented with a high speed 12-bit DAC. Sets the LED
target amplitude.
7.3.1.2 Illumination Control Loop
Figure 7 shows the illumination control loop. This loop consists of the following features:
•
An external buck controller (LM3409) and related discrete components which control the main LED drive
PFET and controls and limits peak current using a high side sense circuit. This circuit creates a controlled
current source that drives the LED high side connection (LED_ANODE).
•
•
A 10-bit peak current limit (ILIM) adjustment DAC included in the TPS99000-Q1.
Synchronization logic for external LED drive buck. SYNC pin to override the controlled off time pin of external
device, and DRV_EN to control enable of external device.
•
•
High speed comparator, used to compare photo feedback signal to programmable reference.
12-bit photo feedback comparison DAC. Sets reference for LED light pulse peak threshold in both continuous
and discontinuous operating modes.
•
A high speed, low noise, wide dynamic range transimpedance amplifier (TIA1) used for real time photo
feedback. Includes support for 0.75 V to 288 V/mA gains, with 14 discrete gain steps and additional RGB
specific trim of 1.0 to 0.2 gain. (Two TIAs included. TIA1 is dedicated to illumination control function).
•
•
•
Negative LDO for cost effective reverse bias of photodiodes.
12-bit ADC, with differential input dedicated to low side current measurements.
External FET gate drivers for RGB channel selection and two shunt path selections. Shunt paths provide a
conduction path around the LEDs. These paths are used to control inductor current while LEDs are not
emitting light. Control logic and firmware establishes appropriate current levels in inductor prior to enabling of
LED during gaps between light pulses.
Copyright © 2015–2019, Texas Instruments Incorporated
27
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
Feature Description (continued)
LM3409
en
VLED
DRV_EN
SYNC
38
15
sense
LED_SEL3
23
adjustable
high side peak
current limit
LED_SEL2
22
coff
LED_SEL1
21
ILIM
LED_ANODE
LED_SEL0
20
DAC
76
77
10 bit
D_EN
18
small
14 gain
settings
S_EN
19
illumination path
real-time light
sensing
TIA1
COMPOUT
11
adj 73
+
0.75-
288
V/mA
DAC
12 bit
-8V
63
LDO
27
28
29
30
big
used for
R_EN
G_EN
45
46
47
43
44
39
DM light
pulse edg
rate
B_EN
limiting
S_EN1
S_EN2
CMODE
ADC_MISO
4
83
82
ADC
ADC_MOSI
5
serial
control
ADC
sense
(optional)
SEQ_CLK
12 bit
17
bit slice-aligned low side current sense samples available to DLPC230 sofware:
information used to trim peak current limit values, fault detection
Figure 7. Illumination Control Loop
7.3.1.3 Continuous Mode Operation
When operating in continuous mode (continuous light output mode) a hysteretic control scheme is utilized. Real-
time analog light amplitude measurements are used in the photo feedback loop to maintain a target light level.
Figure 8 highlights the photo feedback control loop path in the driver for continuous mode.
LM3409
en
VLED
DRV_EN
38
15
sense
adjustable
high side peak
current limit
SYNC
logic
coff
ILIM
LED_ANODE
DAC
76
77
10 bit
small
14 gain
illumination path
TIA1
settings
real-time light
sensing
adj 73
+
0.75-
288
DAC
V/mA
Figure 8. Continuous Mode Photo Feedback Path
28
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
Feature Description (continued)
The on-chip analog comparator of the TPS99000-Q1 is used to compare desired target LED light amplitude to
actual LED light output voltage from the photodiode TIA circuit. When the light output is below the threshold (set
by the 12-bit photo feedback DAC output), the comparator will output a high level, causing DRV_EN to go high,
which creates a connection from the power rail to the LED drive inductor to be made through the LED drive
PFET. This connection will cause current flow to increase through the inductor. This current flows through an
LED when its FET is enabled. When the light value goes above the threshold, DRV_EN goes low and the PFET
is turned off, breaking the connection to the power rail with very little delay. Once the light level drops back below
the threshold, DRV_EN goes high again and the PFET is turned back on, delivering more power to the LED. This
process repeats as long as the LED circuit is enabled.
Hysteretic control results in ripple in the LED current. The amplitude and frequency of this ripple is a function of
inductor inductance, input voltage, comparator hysteresis, and loop latency. An advantage of this hysteretic
control approach is unconditional stability of the control loop.
Figure 9 shows the continuous mode signals and light output for a red, green, and blue bit slice. The signals,
including LED_SEL(3:0), D_EN, S_EN1, and S_EN2, are sent from the DLPC230-Q1.
1000
0010
0100
0001
1100
0011
LED_SEL(3:0)
D_EN
DLPC230
S_EN
G_EN
R_EN
B_EN
S_EN1
S_EN2
Photo Feedback
DAC output
and Light
DRV_EN
PFET gate
voltage
inductor
current
Figure 9. Continuous Mode Signal Example
Copyright © 2015–2019, Texas Instruments Incorporated
29
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
Feature Description (continued)
In continuous mode, dimming is accomplished through a combination of amplitude/flux dimming and pulse time
attenuation. Amplitude dimming is done by adjusting the photo feedback DAC output and TIA feedback gain.
Time attenuation is accomplished by adjusting the length of shunt enable (S_EN from DLPC230-Q1) and drive
enable (D_EN from DLPC230-Q1) (see Figure 10). Figure 10 shows an example with a 100% bit and a bit with
time and amplitude attenuation to achieve 32:1 dimming. Figure 11 is a more generic example showing how
many different dimming levels can be achieved with combinations of time and amplitude dimming.
max
Amplitude
100% light pulse
.25 flux * .125 time => 32:1
Figure 10. Continuous Mode Dimming Illustration 1
1.0
0.5
0.25
0.125
0.125
0.25
0.5
1.0
0.125 * 0.125
=> 64:1
DLCP120 Pulse Width Dimming
Figure 11. Continuous Mode Dimming Illustration 2
7.3.1.3.1 Output Capacitance in Continuous Mode
In continuous mode the CMODE signal from the TPS99000-Q1 is set low so the FET controlling the big (~1 µF)
capacitor is turned off leaving only a small (~ 0.1 µF) high frequency decoupling capacitance in parallel with the
LEDs and shunt FET paths (refer to Figure 7). Using a lower capacitance in continuous mode allows the voltage
across the capacitor and LED to charge up faster so that the current in the inductor does not overshoot the
desired current level before the LED light emission threshold is reached. This prevents the light pulse from
overshooting at the beginning of bit slices. (Discontinuous pulse mode requires a larger, ~1 µF capacitance as
will be discussed later in this document. CMODE pin is set high in discontinuous mode to enable higher
capacitance in parallel with LEDs).
7.3.1.3.2 Continuous Mode Driver Distortion and Blanking Current
G_EN
D_EN
S_EN
di/dt=V/L
I_Green
Tp1
Tp2
Tr
Tf
Figure 12. First Generation/Legacy System Pulse Distortion Example
As seen in Figure 12, the actual LED current pulse is distorted due to the rising (Tr) and falling (Tf) edges rates
not being equal, and/or the turn-on (Tp1) and turn-off (Tp2) propagation delays not being equal. The rising edge
turn-on time of the current pulse is primarily a function of the voltage across the inductor and the desired current,
plus the inductor current initial condition. This distortion causes both the time attenuation and amplitude
attenuation of the pulse to become non-linear functions of the control settings. This can lead to image artifacts.
Blanking time is the period of no light output in between two LED segments. The inductor current during this time
is called blanking current. This current is controlled to provide an optimized Tr and Tf.
Blanking current control reduces image artifacts by preventing light overshoot and undershoot.
30
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
Feature Description (continued)
The blanking current time periods are split into two parts. The first is a dissipation phase where the residual
current in the inductor from the previous light pulse is reduced using a dissipative shunt. The second phase is a
non-dissipative (low series resistance) shunt phase, where the inductor is charged up to the appropriate current
for the next light pulse before current is applied to the LED. This process is illustrated in Figure 13.
regulator switching synchronized to ... then resynchronized to
beginning of photo feedback phase
beginning of SEN1 phase
drive
disabled
SEN2
peak current
photo feedback control
control
photo feedback control
SEN1
I
lim
Inductor current
software coordinates I —blanking“
lim
inductor
low resistance
inductor
charging
current to match ideal initial
condition of next light pulse, using
ADC measurements and ILIM DAC
energy
dissipation
LED current
system begins photo
feedback regulation with
proper inductor initial current
for desired light level for next
LED in sequence
blanking
Figure 13. Blanking Current Discharge/Charge Cycles
During the first phase of the blanking time, shunt 2 (S_EN2) is enabled while the LEDs are disconnected. This
places a load with a higher effective resistance in place of the LEDs. The residual energy in the inductor is
dissipated into this load and the inductor current decreases rapidly. Without this feature, a high current in one
pulse could cause excessive brightness in the next pulse.
During the second phase of the blanking time, the LED driver charges the inductor through a short circuit shunt
(S_EN1). Charging continues until the peak current limit is reached. The peak current limit is set by the ILIM
DAC. The peak current limit setting is coordinated by DLPC230-Q1 software to match the expected operating
current during photo feedback operation. (The expected current level is determined from ADC measurements of
LED current during prior frames.) When the blanking current time period is over, the S_EN1 short circuit shunt is
turned off, the next LED is enabled, the DRV_EN signal is toggled, and the system reverts to photo feedback,
hysteretic operation. Because the inductor is pre-charged to the ideal current and the system capacitance is low,
light output rising edge is extremely fast, and the transition to stable hysteretic control is nearly immediate. This
results in a more rectangular pulse. An illustration of the current paths is shown in Figure 14.
Copyright © 2015–2019, Texas Instruments Incorporated
31
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
Feature Description (continued)
LM3409
en
VLED
DRV_EN
38
15
sense
LED_SEL3
23
adjustable
high side peak
current limit
LED_SEL2
LED_SEL1
LED_SEL0
D_EN
SYNC
22
21
20
18
19
coff
ILIM
LED_ANODE
DAC
76
77
10 bit
small
14 gain
settings
S_EN
illumination path
real-time light
sensing
TIA1
COMPOUT
adj 73
11
+
0.75-
288
V/mA
DAC
Inductor charge dump
1
2
12 bit
-8V
LDO
3
63
Recharge current
for next bit
27
28
29
30
big
2
R_EN
G_EN
B_EN
45
46
47
43
44
39
1
Quickly turns on light
to current level
3
S_EN1
S_EN2
CMODE
ADC_MISO
ADC_MOSI
SEQ_CLK
4
5
83
82
ADC
serial
control
(other options available
for S_EN2 load circuit)
ADC
sense
12 bit
17
bit slice-aligned low side current sense samples available to DLPC230 sofware:
information used to trim peak current limit values, fault detection
Figure 14. Blanking Current Paths
Precise control of the LED pulse shape results in greater dimming range, more display bit depth, and better color
and gray ramp accuracy.
7.3.1.3.3 Continuous Mode S_EN2 Dissipative Load Shunt Options
The dissipative shunt, enabled by S_EN2 high, can be implemented with a variety of circuit types.
The circuit type selected for the shunt must be able to discharge the inductor used in the LED drive circuit, as
well as protect against over voltage conditions on the LED anode voltage.
32
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
Feature Description (continued)
The recommended option is to combine the open circuit protection Zener diode with the S_EN2 dissipative shunt
functionality, as shown in Figure 15. This particular option does not connect the S_EN2 pin but still implements
the same functionality as the alternate circuits in Figure 14 and Figure 16 which do connect the S_EN2 pin.
Figure 15. Dissipative Shunt / LED Open Circuit Protection Combination 1
In this case, a low power Zener diode is used to turn on a FET when the LED anode voltage exceeds the Zener
voltage. The S_EN2 enable is not used in this configuration. Rather, the circuit intentionally is placed in an open
circuit condition during the S_EN2 blanking time period. Then the protection circuit turns on and drains energy
from the inductor (until the S_EN1 shunt is enabled and the LED anode voltage is reduced). The energy in this
case is dissipated in a combination of the load resistor and FET. Care must be taken in selection of the Zener
diode and resistor divider to ensure the LED anode voltage does not exceed the RGB select FET breakdown
voltage. (An option is to delete the load resistor entirely. Then the dissipation will occur only in the FET, and the
LED anode voltage will stay closer to the Zener voltage under all conditions). The Zener voltage must be higher
than the worst case voltage of input VLED power rail to avoid unintentional triggering of circuit. And Zener
voltage must be below the Vds breakdown voltage of the LED selection FETs.
Alternative circuits with the same functionality can be seen below.
Figure 16. Dissipative Shunt / LED Open Circuit Protection Combination 2
In this circuit, the inductor current is discharged through the resistive path controlled by S_EN2.
Copyright © 2015–2019, Texas Instruments Incorporated
33
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
Feature Description (continued)
Figure 17. Dissipative Shunt / LED Open Circuit Protection Combination 3
In this circuit, the inductor current is discharged through the power Zener diode.
7.3.1.3.4 Continuous Mode Constant OFF Time
A constant off time feature (see COMPOUT_LOW signal in Figure 18) is included in continuous mode operation.
During continuous mode operation, when the desired light level is achieved, the PFET gate drive is turned off by
control of the DRV_EN signal and the light level begins to decrease as the inductor current begins to decrease.
In a typical hysteretic controller, when a turn on threshold is reached, the PFET is turned on and the
light/inductor current increases again. The frequency of switching is dependent on the difference between the
turn on and turn off thresholds, loop delay and discrete component values (with the inductor inductance and
voltage being most dominant factors).
In the TPS99000-Q1, the control is modified to regulate the operating frequency. A constant off timer is included
in the TPS99000-Q1 control loop. When the photo feedback comparator threshold is achieved, a counter is
started. The length of the counter is adjustable. While this counter is active, the output of the photo feedback
comparator is ignored and the PFET drive (via DRV_EN output from TPS99000-Q1) is disabled. Once the
constant off time period counter has expired, the output of the photo feedback comparator is once again used to
control the LED current drive. The minimum off-time establishes an upper limit on the hysteretic control loop
switching frequency, separate from the natural frequency of the circuit. This feature is useful for assuring the
circuit will not operate in the AM radio frequency band, and can also enable the usage of lower inductance value
inductors (which can result in system cost savings and power efficiency improvements).
photo feedback
DAC threshold
LED light
(TIA1 output)
PFB comparator
output
COMPOUT_LOW(7:0)
charging time
DRV_EN
PFET gate
Switching period = COMPOUT_LOW(7:0) + charging times
Figure 18. COMPOUT_LOW Constant Off Time
34
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
Feature Description (continued)
7.3.1.3.5 Continuous Mode Current Limit
In continuous mode, a current limit feature prevents damage to LEDs if the requested light output cannot be
achieved within LED current specifications. This could happen due to high temperature, or when an LED ages
and requires more current to achieve the same brightness. Systems should be designed with sufficient thermal
and LED life time margin that this would not happen in practice.
The control scheme utilizes the built in current limit feature of the LM3409 device plus a 10-bit DAC based
adjustment feature included in the TPS99000-Q1. This serves as an alternate limit for the current for the LEDs –
inductor drive will be disabled if either the current limit is met or if the photo feedback limit is met, whichever is
lower. This peak current limit is configurable on a per LED basis, and is in use during the light-on active periods
only. (During blanking periods, this same structure is used to control the blanking current, but different values are
loaded onto the ILIM DAC).
The schematic for the current adjustment mechanism is shown in Figure 19.
VLED
10
VIN
9
VCC
1
2
3
UVLO
CSP
8
7
6
TPS99000
Sense
IADJ
EN
CSN
PGATE
5
DRV_EN 38
COFF GND
4
LED_ANODE
SYNC 15
ILIM DAC
10 bit
DAC
+
IADJ
76
77
R_IADJ
Figure 19. IADJ Peak Current Limit Schematic
By design, the LM3409 seeks to create a zero voltage difference between the CSP and CSN pins when IADJ pin
is held low and system is operating in peak current limit mode. If the CSP pin voltage is higher than the CSN pin
voltage, the PGATE driver is held high (PFET off).
When the ILIM DAC is set to a non-zero voltage, a current is established on the IADJ line of the TPS99000-Q1
device, which pulls the voltage of the CSP pin downward. If the LM3409 device is enabled and PFET drive not
held off by state of the COFF pin, then the current will go up until the voltage across the sense resistor is such
that the CSN pin is equal to or greater than the voltage on the CSP pin, at which point the PFET is turned off.
Care must be taken with the routing of the IADJ pin of the TPS99000-Q1 to insure that it is well isolated from
noisy switching nodes, such as the PFET drain node.
Copyright © 2015–2019, Texas Instruments Incorporated
35
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
Feature Description (continued)
7.3.1.4 Discontinuous Mode Operation
Discontinuous mode is used to achieve lower dimming levels. It replaces the constant block of light during a bit
slice with a series of light pulses of controlled amplitude, as illustrated in Figure 20. The number of pulses is
controlled by the DLPC230-Q1 software.
~16:1, continuous mode
~16:1, discontinuous mode
Figure 20. Comparison of Continuous and Discontinuous Operation at Equivalent Brightness
Figure 20 is an example diagram showing the Discontinuous Mode signals generating 8 pulses which are
equivalent in brightness.
In discontinuous mode, the controller produces discrete pulses of light with fixed off times between pulses. The
amount of light that these pulses produce can be precisely controlled to reach low dimming levels. Two control
loops are used to create uniform light pulses:
•
Peak current limit loop to create a desired current level in the inductor before it flows through the LED.
•
Photo feedback loop to terminate each pulse when the desired light pulse level is achieved.
The initial inductor current and peak light threshold are independently adjustable for each color. See Figure 21
and Figure 22.
0010 (green)
0001 (red)
0011 (blue)
LED_SEL(3:0)
S_EN
D_EN
photo feedback
DAC output
(dashed line)
Light
COMPOUT
(from TPS99000 to
DLPC230)
Figure 21. Discontinuous Operation DLPC230-Q1 to TPS99000-Q1 Signals
Sequence timing control
D_EN and
DRV_EN
PFET gate
Shunt
enable
S_EN1
Ilim
Inductor
current
LED
Vt
forward
voltage
Light
comparison
threshold
Light
Figure 22. Discontinuous Mode Operation Inductor Current/LED Voltage
36
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
Feature Description (continued)
Discontinuous mode consists of a series of triangular pulses of light. The DLPC230-Q1 is in charge of requesting
and counting the total number of pulses. A bit slice begins with the low resistance shunt enable (S_EN1) on, and
with an RGB color selected. Then DLPC230-Q1 asserts D_EN. This causes the TPS99000-Q1 to turn on the
LED current drive (DRV_EN) and the system charges the inductor into the low resistance shunt until the peak
current limit (as programmed with ILIM DAC) is reached. Then after a programmable amount of time the
DLPC230-Q1 drives S_EN low, forcing inductor current to flow through the selected LED.
The TPS99000-Q1 detects the falling edge of S_EN from the DLPC230-Q1 and issues an on/off/on toggle of the
DRV_EN signal. This allows current to flow through the inductor and increases the voltage at the LED anode.
When the LED forward voltage is achieved, it begins to emit light. Once the photo feedback loop (TIA, photo
feedback comparator, photo feedback DAC) senses the desired light threshold has been crossed, the S_EN1
signal is re-asserted high, and the light pulse is terminated.
The COMPOUT signal going low indicates to the DLPC230-Q1 that the pulse has been completed. The
DLPC230-Q1 immediately sets S_EN output high (which sets TPS99000-Q1 output S_EN1 high), then waits for
a programmable length of time. After that period of time, the DLPC230-Q1 will decide either to drive D_EN low
and wait for the next bit slice or issue a request for a new pulse by placing the S_EN output low. When S_EN
output is placed low, the TPS99000-Q1 places S_EN1 low (forcing current through LED) and toggles DRV_EN to
request a new peak limit current pulse cycle. This process repeats until the correct number of pulses for the
given bit slice have been completed.
In very low brightness operation, the TPS99000-Q1 SYNC (LM3409 COFF) timer is disabled. As a result,
DRV_EN is only toggled at the beginning of each light pulse. This synchronizes the inductor and LED current.
This synchronization keeps LED pulse heights very consistent from one video frame to the next, preventing
flicker.
7.3.1.4.1 Discontinuous Mode Pulse Width Limit
The TPS99000-Q1 has a feature which limits the time duration of each discontinuous mode pulse. A count
monitors the length of time current is applied to the LED during a pulse event and compares time to a
programmable time limit. If the time limit expires before the light output threshold is reached, the discontinuous
pulse is terminated. The pulses in both cases (photo level or time limit expiration) are terminated by enabling the
S_EN1 low resistance shunt. This limits maximum brightness in the event photo feedback threshold is not
reached. Independent RGB values for the discontinuous pulse width limit are supported. This process is
illustrated in Figure 23.
Light
Limit
Time
Limit
Time
Limit
Figure 23. Discontinuous Mode Pulse Width Time Limit
7.3.1.4.2 COMPOUT_LOW Timer in Discontinuous Operation
In discontinuous operation, the same COMPOUT_LOW parameter that sets the switching frequency for the
continuous mode case serves as a noise filter for discontinuous operation. The circuit triggers on the first falling
edge of the photo threshold comparator, which equates to the end of a pulse. Then all subsequent rising and
falling edges of the comparator output are ignored for a pre-defined amount of time, providing a glitch
suppression filter function for discontinuous operation, and controlling the timing between pulses.
Copyright © 2015–2019, Texas Instruments Incorporated
37
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
Feature Description (continued)
COMPOUT_LOW (7:0)
38 DRV_EN
Logic
Photofeedback
DAC
DAC
+
COFF
timer
COMPOUT
11
73
63
TIA1
-8 V LDO
Photo
feedback
comparator
output
COMPOUT
Only first falling edge affects counter
Figure 24. COMPOUT_LOW Timer as Glitch Filter in Discontinuous Operation
7.3.1.4.3 Dimming Within Discontinuous Operation Range
When operating in discontinuous mode, two methods of dimming are used concurrently to reduce brightness of
the display:
1. Amplitude dimming using the photo feedback DAC settings.
2. Controlling the number of pulses per bit slice (via commands to DLPC230-Q1, selecting specific lookup table
data).
Figure 25 is an example of the brightest LUT data table having 8 pulses per LSB (smallest bit slice). The LED
pulse height is modulated to achieve a 2:1 dimming ratio while still maintaining 8 pulses per LSB. To allow for a
seamless transition to lower dimming levels, a change to 4 pulses per LSB plus higher LED amplitude is made
as illustrated in Figure 26. The total light generated in both cases in Figure 26 is approximately equal. A system
calibration is used to determine this ½ LED amplitude photo feedback DAC setting.
~16:1
~32:1
Figure 25. 2:1 Dimming Within a Sequence
~32:1
~32:1
Figure 26. Discontinuous Operation Pulse Count Change
As a smooth dimming (brightness going down) sequence continues, the process above eventually results in
using a 1 pulse per LSB. Amplitude dimming is used to dim to the absolute minimum display brightness level as
illustrated in Figure 27.
38
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
Feature Description (continued)
~512:1
>5000:1
Figure 27. Discontinuous Dimming with One Pulse Per LSB Sequence
As shown in Figure 27, once a single pulse-per-LSB is selected, all remaining dimming must occur using only
pulse height threshold reduction.
7.3.1.4.4 Multiple Pulse Heights to Increase Bit Depth
With the TPS99000-Q1, up to four sets of photo feedback threshold settings are supported within a given
sequence. This is useful in discontinuous operation to create smaller sub-LSB bits (bits that are smaller than the
normal LSB).
The LED_SEL(3:0) lines are encoded to include group information as well as color selection (and blanking
current selection).
Each group can be defined to determine different behavior for specific color bits. For example, Group 0 can be
used for LSB, and Group 1 can be used to create LSB-1.
Table 1. LED Selection Table
LED_SEL(3:0)
"0000"
NAME
OFF
ACTION
Driver Disabled Mode S_EN1 forced high RGB selects low
"0100"
R BLANKING
G BLANKING
LED_SEL(1:0) - "00"=blanking
LED_SEL(3:2):
"01"=red
"1000"
"10"=green
"11"=blue
"1100"
B BLANKING
"0001"
"0010"
"0011"
"0101"
"0110"
"0111"
"1001"
"1010"
"1011"
"1101"
"1110"
"1111"
GRP0 RED
GRP0 GREEN
GRP0 BLUE
GRP1 RED
Driver Enabled Mode:
LED_SEL(3:2) - Define Group:
'00' - Group 0
'01' - Group 1
'10' - Group 2
'11' - Group 3
LED_SEL(1:0):
"01" - red
"10" - green
"11" - blue
GRP1 GREEN
GRP1 BLUE
GRP2 RED
GRP2 GREEN
GRP2 BLUE
GRP3 RED
GRP3 GREEN
GRP3 BLUE
Copyright © 2015–2019, Texas Instruments Incorporated
39
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
The group1-3 RGB selections may be used to create fractional LSBs in the sequence, as illustrated in Figure 28.
Normal LSB
(6th bit)
Blue Group 0
LED_SEL=0011
Normal LSB-1
(7th bit)
Normal LSB-2
(8th bit)
Blue Group 1
LED_SEL=0111
Blue Group 2
LED_SEL=1011
(group 3 œ spare)
Figure 28. Extended LSB Bit Depth in Discontinuous Operation
This feature, combined with ability to make smaller absolute size light pulses, provides a method to extend the
practical bit depth limit from the typical 6 bits per color, as is the case in legacy systems, to 7 or 8 bits with
TPS99000-Q1/DLPC230-Q1 second generation systems.
7.3.1.4.5 TIA Gain Adjustment
The gain of TIA1 can be adjusted to achieve a larger dimming range. Increasing the TIA gain reduces the light
output for a given photo feedback DAC level. A higher gain reduces the brightness range achievable but
increases the resolution within the desired range.
7.3.1.4.6 Current Limit in Discontinuous Mode
The current limit determines the maximum current allowed through the inductor. A higher current limit enables
higher pulse heights to be achieved. A lower current limit creates a slower rising edge on each pulse and
reduces the overshoot of the pulse. Therefore, at lower dimming levels the current limit is reduced.
7.3.1.4.7 CMODE Big Cap Mode in Discontinuous Operation
The TPS99000-Q1 provides an output signal, CMODE, that can be used to drive the gate of a FET that switches
in a larger capacitor for discontinuous operation. High capacitance mode is only used during discontinuous
operation. (High capacitance causes issues in continuous operation, minimizing capacitance is preferred for that
mode). The higher capacitance slows the rate at which the forward voltage of the LED increases during the pulse
creation process. The slower charge rate causes the transition from no light emission to full light emission to
extend in time. In selecting the proper capacitance, a balance between good edge rate control and total time for
pulse to reach threshold must be made. Attention should be paid to the temperature characteristics of this
capacitor. Less variation of capacitance over temperature will result in more accurate, repeatable results in
cold/hot conditions.
Benefits:
•
•
Pulse stability
Support for lower light output thresholds, due to slower pulse edge rates
The charge and discharge loops using the CMODE big cap are as follows:
40
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
Inductor current
Charge in Capacitors
Discharged
shunted to ground
PFET
0.1 µF
1 µF
S_EN1
Shunt
Fet
CMODE
R_EN
G_EN
B_EN
0.020
Figure 29. Discontinuous Mode Current Paths with Shunt Enabled
PFET
0.1 µF
1 µF
S_EN1
Shunt
Fet
R_EN
G_EN
B_EN
CMODE
0.020
Figure 30. Discontinuous Mode Current Paths with Shunt Disabled
7.3.2 Over-Brightness Detection
The TPS99000-Q1 has two methods for detecting over-brightness conditions. The first method uses a
combination of ADC measurements and photo feedback comparator output to detect breaks in the photo
feedback loop. Another method uses a secondary photodiode to detect over-brightness in the HUD image.
7.3.2.1 Photo Feedback Monitor BIST
A disconnection of the primary photodiode breaks the feedback loop used to regulate LED output. Any
disconnection of this photodiode should be detected so that the LEDs can be disabled.
The DLPC230-Q1 software and the TPS99000-Q1 implement a photo feedback monitor Built-In Self-Test (BIST)
to detect a disconnected photodiode. Every video frame, the DLPC230-Q1 software uses ADC measurements of
the LED current and TIA output, and COMPOUT falling edges to detect a disconnected photodiode.
In continuous mode, the DLPC230-Q1 software determines that the photodiode is disconnected if all the LED
currents are at maximum, but the TIA measurements are at a minimum. This indicates that the LEDs are
conducting current, but the photodiode is not responding to light output from the LEDs.
In discontinuous mode, COMPOUT edges are used to detect a photodiode disconnect. A falling edge on
COMPOUT indicates that an LED pulse has reached the desired threshold. This is only possible if the
photodiode is connected. Therefore, the COMPOUT edges are detected by the DLPC230-Q1 software to
determine if the photodiode is connected.
7.3.2.2 Excessive Brightness BIST
The excessive brightness BIST uses a secondary photodiode connected to TIA2 to detect over-brightness
conditions in the output image of the HUD.
The output of TIA2 is compared to a programmable threshold. If the output exceeds the threshold, the DLPC230-
Q1 software will log an error. TIA2 can be used in a high bandwidth or low bandwidth configuration for this BIST.
The low bandwidth mode provides an RC filter low-passed value of the TIA2 output. The resistor element of the
filter is embedded in the TPS99000-Q1, while the capacitor is an external component. If the low bandwidth input
is used, the value of the capacitor should be expected such that the time constant is longer than the frame time.
Copyright © 2015–2019, Texas Instruments Incorporated
41
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
The hardware controls for the threshold are not synchronized to the dimming functionality of the TPS99000-Q1.
Therefore, this feature may need to be enabled or disabled, or the thresholds may need to be adjusted based on
the dimming level of the HUD.
Figure 31. Excessive Brightness Detection Circuit
7.3.3 Analog to Digital Converter
The TPS99000-Q1 includes a 12-bit analog to digital converter block with a 32:1 input mux and dual sample-and-
hold circuits. It also includes a custom high speed serial control interface which when used in tandem with the
DLPC230-Q1 provides up to 63 DMD sequence-aligned samples per frame, with hardware-based sample timing
and shadow-latched results. The hardware sample timing and shadow latch relieves the DLPC230-Q1 processor
from ADC timing tasks, freeing up processor resources for other uses.
Figure 32 illustrates the structure of the ADC controller blocks in the two ASICs.
42
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
Figure 32. ADC Subsystem Block Diagram
The ADC block contains a dedicated channel reserved for differential low side LED current measurements. Two
sample-and-hold circuits are included to support paired LED current/voltage measurements. (Note: when
performing paired samples, they are sampled simultaneously, but converted sequentially, so the conversion time
doubles). An additional seven external ADC channels are supported. The remaining 24 multiplexer inputs enable
measurement of internal TPS99000-Q1 operating parameters.
The DLPC230-Q1 contains a custom ADC control block that supports up to 63 ADC samples per frame. The
samples are aligned with DMD sequencer activity, configurable through system configuration tools. This
alignment makes measurement of specific light pulses (LED current, voltage, and TIA output) within a sequence
possible, with precise repeatability from frame to frame. Up to 63 samples per frame are supported. The 63
sample buffer includes a shadow latch that updates each frame. This latched output is held constant for a
complete frame time, allowing time for the DLPC230-Q1 to collect and process the information.
A reference voltage output is also included in the ADC block. This provides a low current voltage reference which
matches the reference used by the ADC for conversion. This external reference can be used to bias thermistor
voltage dividers, providing greater accuracy than would be possible using a mix of external and internal
references. (Note: Current supply is limited. Loads which exceed the specified current maximum rating on
ADC_VREF output may result in unpredictable ADC behavior). Regardless of whether the reference voltage is
used, a 0.1uF capacitor should be connected from this pin to ground.
Copyright © 2015–2019, Texas Instruments Incorporated
43
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
7.3.3.1 Analog to Digital Converter Input Table
Table 2. Analog to Digital Converter Input Table
INTERNAL OR
EXTERNAL
PARAMETER
TEST CONDITIONS(1)
MIN
TYP
MAX
UNIT
Channel 0, Gain
Channel 0, Gain
Channel 0, Gain
Low side sense amp
External
External
External
Gain set to 24x
Gain set to 12x
Gain set to 9x
22.56
24
12
9
25.44 V/V
12.72 V/V
9.54 V/V
Low side sense amp
Low side sense amp
11.28
8.46
ADC_IN1_PAD
(LED_ANODE)
Channel 1, Gain
External
0.980
1.000
1.020 V/V
Channel 2, Gain
Channel 3, Gain
Channel 4, Gain
ADC_IN2_PAD (VLED)
ADC_IN3_PAD
External
External
External
0.980
0.980
0.980
1.000
1.000
1.000
1.020 V/V
1.020 V/V
1.020 V/V
ADC_IN4_PAD
ADC_IN5_PAD
(R_LED_THERM)
Channel 5, Gain
Channel 6, Gain
Channel 7, Gain
External
External
External
0.980
0.980
0.980
1.000
1.000
1.000
1.020 V/V
1.020 V/V
1.020 V/V
ADC_IN6_PAD
(G_LED_THERM)
ADC_IN7_PAD
(B_LED_THERM)
Channel 8, Gain
Channel 9, Gain
Channel 10, Gain
Channel 10, Offset
Channel 11, Gain
Channel 12, Gain
Channel 13, Gain
Channel 14, Gain
Channel 15, Gain
Channel 16, Offset
Channel 16, Gain
Channel 17, Gain
Channel 18, Gain
Channel 19, Gain
Channel 20, Gain
Channel 21, Gain
VBIAS
VOFFSET
VRESET
Internal
Internal
Internal
Internal
Internal
Internal
Internal
Internal
Internal
Internal
Internal
Internal
Internal
Internal
Internal
Internal
0.0596
0.1112
0.0621
0.117
0.0646 V/V
0.1218 V/V
–0.1978
–0.190 –0.1822 V/V
–1.169
VRESET
–1.217 –1.1935
V
VMAIN
0.52546
0.31302
0.65706
0.40326
0.2209
8.15
0.559 0.59254 V/V
0.333 0.35298 V/V
0.699 0.74094 V/V
0.429 0.45474 V/V
DVDD
V1.1
V1.8
V3.3
0.235
8.400
1.000
0.5
0.2491 V/V
8.65
M8 LDO offset
M8 LDO
V
0.980
1.020 V/V
0.51 V/V
ext ADC VREF
Driver Power
Die Temp1
Die Temp2
ILED Control DAC
0.49
0.20398
0.490
0.217 0.23002 V/V
0.500
0.500
0.500
0.510 V/V
0.510 V/V
0.510 V/V
0.490
0.490
Photo Feedback Control
DAC
Channel 22, Gain
Channel 23, Gain
Internal
Internal
0.490
0.490
0.500
0.500
0.510 V/V
0.510 V/V
Over-Brightness Control
DAC
Channel 24, Gain
Channel 25, Gain
Channel 26, Gain
Channel 27, Gain
Channel 28, Gain
Channel 29, Gain
Channel 30, Gain
Channel 31, Gain
TIA1 Real Time
TIA1 Low Bandwidth
TIA2 Real Time
Internal
Internal
Internal
Internal
Internal
Internal
Internal
Internal
0.490
0.490
0.490
0.490
0.500
0.500
0.500
0.500
0.510 V/V
0.510 V/V
0.510 V/V
0.510 V/V
TIA2 Low Bandwidth
Channel not used
Main Bandgap, 0.5 V
TIA1 Monitor
0.980
0.980
0.980
1.000
1.000
1.000
1.020 V/V
1.020 V/V
1.020 V/V
TIA2 Monitor
(1) Conversion formula is (X + Offset) * Gain. X is the input voltage. Offset is 0 V unless specified above.
44
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
7.3.4 Power Sequencing and Monitoring
The TPS99000-Q1 is specifically designed to perform correct power-up and power-down sequencing to ensure
long term reliable operation of the DMD. The high voltage DMD mirror supplies require special power sequencing
order, and restrictions on voltage differences between the power rails (VRESET, VBIAS, and VOFFSET)
throughout power up, power down, and normal operation. The TPS99000-Q1 handles these requirements for the
system designer.
7.3.4.1 Power Monitoring
Main asynchronous digital logic reset (DVDD_RSTZ) – Monitor of the main power of the 3.3 V power supply
input to the TPS99000-Q1. This monitor output is used as an asynchronous reset for all of the digital logic inside
TPS99000-Q1.
Figure 33. Internal DVDD Monitor
The PROJ_ON pin is the main on/off switch for DLP subsystem. 1 is ON, 0 is OFF. Once DVDD_ARSTZ is
released, TPS99000-Q1 will begin sampling the PROJ_ON pin. If it is low, system stays in the OFF state. If it
goes high, TPS99000-Q1 begins to progress through the power-on process.
The TPS99000-Q1 includes a VMAIN brown out monitor function. A voltage monitor observes the voltage on the
VMAIN input pin, as shown in Figure 34. The Zener may be necessary for over voltage protection of the pin, in
case the voltage being monitored has the potential to go high, such as a battery input.
Either PROJ_ON or VMAIN may be used to turn the system on and off, and doing so will remove power to the
DLPC230-Q1. For fast control of turning the display on and off without removing power to the DLPC230-Q1,
change the operating mode of the DLPC230-Q1 embedded software between 'Standby' and 'Display'.
main power after
preregulator/filter
R1
VMAIN
pwrgood1
voltage
monitor
if necessary
R2
Figure 34. VMAIN Brown Out Monitor
This monitor is used to provide the DLP subsystem with an early warning that power to the unit is going away.
The system will park the DMD mirrors and proceed to a ready for power-off state if the VMAIN input voltage falls
below a fixed threshold. External resistors should be used to divide the input power rail. Once a VMAIN brown
out occurs, the main power rails to the TPS99000-Q1 must remain within their operating ranges until the
TPS99000-Q1 power-down is complete.
The main power rails to the chipset (6 V, 3.3 V, 1.8 V and 1.1 V) are monitored with real time power monitors as
well. Each of these monitors is logically 'OR'ed together to produce the pwrgood2 signal in Figure 35.
Copyright © 2015–2019, Texas Instruments Incorporated
45
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
Figure 35. Real-Time Power Rail Monitors
Additionally, all power within the TPS99000-Q1 can be monitored by the ADC function. DLPC230-Q1 software
configures the ADC block to collect all voltage information in the system each frame. Any gross out of
specification issues are captured and reported as system errors in the DLPC230-Q1 system status.
7.3.5 DMD Mirror Voltage Regulator
The DMD mirror voltage regulator generates three high voltage supply rails: DMD_VRESET, DMD_VBIAS and
DMD_VOFFSET. The DMD regulator uses a switching regulator where the inductor is time shared between all
three supplies. The inductor is charged up to a certain current level and then discharged into one of the three
supplies. In cases where a supply does not need additional charge, the time slot normally allocated to that supply
is skipped and the supplies requiring more charge receive all of the charging time.
For proper operation, specific bulk capacitance values are required for each supply rail. Refer to Electrical
Characteristics - Temperature and Voltage Monitors for recommended values for the capacitors. The regulator
contains active power down/discharge circuits. To meet timing requirements, total capacitance (actual
capacitance, not the nominal) must not exceed these levels by substantial amounts, as defined in Electrical
Characteristics - Temperature and Voltage Monitors. Power down timing should be verified in each specific
system design. Too low of a total capacitance will result in excessive ripple on the supply rails which may impact
DMD mirror dynamic behavior. Care should be taken to use capacitors which maintain the recommended
minimum capacitance over the expected operating device temperature range. Large size packages are required
here that do not lose so much capacitance at high voltages.
Although the average current drawn by the DMD on these supplies is small (10’s of mA worst case), the peak
currents can be several amps over 10’s of nano-seconds. To supply this peak current, use of small value, high
frequency decoupling capacitors should be included as close as practical to the DMD power input pins.
46
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
VSS_DRST
VIN_DRST
56
55
54
53
6 V
> = 10 µF
DRST_HS_IND
DRST_PGND
VRESET
1 µF
DRST_LS_IND
DMD_VRESET
DMD_VBIAS
Note: Include
high frequency
decoupling
52
51
50
49
capacitors
close to DMD
power pins.
DMD
High-Voltage
Regulator
VBIAS
DMD_VOFFSET
VOFFSET
0.47 µF
1 µF
Figure 36. DMD Voltage Regulator Circuit
7.3.6 Low Dropout Regulators
The TPS99000-Q1 includes four low drop out regulators, dedicated to specific internal functions:
•
•
•
•
A fixed –8 V negative regulator for photodiode reverse biasing (VIN_LDOT_M8 input, VLDOT_M8 output)
A 5 V output regulator for internal analog circuits (VIN_LDOT_5V input, VLDOT_5V output)
A 3.3 V output regulator for internal analog (VIN_LDOT_3P3V input, VLDOT_3P3V output)
A 3.3 V output regulator dedicated to the ADC block (VIN_LDOA_3P3 input, VLDOA_3P3 output)
The positive output LDO regulators are all designed to operate from the same nominal 6 V input as is needed by
the LED selection FET gate driver supply input, DRVR_PWR and the DMD mirror voltage regulator, VIN_DRST.
However, care must be taken to isolate the sensitive analog circuit power supply inputs from switching noise,
through dedicated sub-planes and supply filtering techniques. Noise on the analog supply rails will directly impact
system dimming range performance, limiting stable operation at low brightness levels.
The negative 8 V LDO is designed to use the DMD_VRESET power rail as its power source. (Note that this
usage implies that the TIA/photodiode path will not be available for use until the DMD is in a powered up state.)
Copyright © 2015–2019, Texas Instruments Incorporated
47
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
M8V
63
VLDOT_M8
10 ꢀF
0.1ꢀF
20kꢁ
62
VIN_LDOT_M8
18kꢁ
162ꢁ
10 ꢁ
VRESET
2.2ꢀF
0.1ꢀF
Figure 37. Negative 8 V LDO Circuit
CAUTION
Applications that do not use a photodiode do not require the -8 V regulator.
VLDOT_M8 and VIN_LDOT_M8 may be left disconnected if the option in the DLPC230
SW to prevent enabling of the –8 V LDO is selected. If these pins are not connected,
care must be taken to confirm that the -8 V LDO is not enabled. If this regulator is
enabled while the pins are disconnected, permanent damage may be caused to the
device.
7.3.7 System Monitoring Features
7.3.7.1 Windowed Watchdog Circuits
The TPS99000-Q1 contains two windowed watchdog circuits that can be used to detect malfunctions within the
DLPC230-Q1.
Figure 38. Windowed Watchdog Function
The DLPC230-Q1 software uses both watchdog circuits. Watchdog #1 (WD1) monitors the internal
microprocessor of the DLPC230-Q1 through a wire connection to a dedicated GPIO line from DLPC230-Q1.
Watchdog #2 (WD2) is used to monitor the DLPC230-Q1 sequencer operation (through monitoring of the
SEQ_STRT pin, wired to WD2 input).
48
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
When this function is enabled, two registers control the timing of the opening and closing of a watchdog trigger
window. Process is initiated by a rising edge on the respective WDx pin. If another rising edge occurs before the
WD trigger window opens, a watchdog error is issued. If the end of the open window period is reached without
receiving a rising edge on WDx, an error is issued. The process restarts any time a WDx rising edge is received.
The two watchdogs are independent.
7.3.7.2 Die Temperature Monitors
The TPS99000-Q1 contains two on-chip die temperature monitors, for reduncy purposes, to monitor the internal
temperature of the TPS99000-Q1. Each monitor has an output that indicates whether the die temperature has
exceeded one of two thresholds. One monitors a warning threshold, and the other monitors an over-tempreature
error threshold. If the warning threshold is exceeded, a processor interrupt may be generated. If the over-
temperature error threshold is exceeded during operation, the TPS99000-Q1 will initiate an emergency shutdown
procedure and then wait for a toggle of the PROJ_ON pin to initiate a system restart while operating in a low
power state. The system will not proceed through the power on initialization steps unless the on die temperature
is below the warning threshold. The status of these temperature monitor output bits is available over the SPI
buses as long as DVDD and VDD_IO power supplies are up and stable.
7.3.7.3 External Clock Ratio Monitor
The TPS99000-Q1 operates from two primary clock sources: an internal low frequency oscillator (2 MHz, used
for system initialization and other maintenance purposes), and an external high speed (30 MHz) clock,
SEQ_CLK, used for most timing critical applications, such as the logic inside the illumination control block and
ADC. The TPS99000-Q1 includes a function that reports the ratio of this internal vs. external clock. This ratio is
available over the SPI bus. The DLPC230-Q1 can check this ratio and compare to expected value. If the ratio is
incorrect, there is a possibility the DLPC230-Q1 oscillator may have locked to an incorrect harmonic, or some
other fault condition has occurred.
7.3.8 Communication Ports
7.3.8.1 Serial Peripheral Interface (SPI)
The TPS99000-Q1 provides two four-wire SPI ports that support transfers up to 30 MHz clock rates. The primary
port (SPI1) supports register reads and writes, and serves as the primary set up and control interface for the
device. The DLPC230-Q1 is the master of SPI1 to control the TPS99000-Q1 during system operation. A
secondary read-only four wire SPI port (SPI2) is available to provide status information to an optional second
microcontroller in the system.
For both ports, the SPIx_SS_Z serves as the active low chip select for the SPI port. A SPI frame is initiated by
SPIx_SS_Z pin going low, and is completed when SPIx_SS_Z pin is driven high.
The secondary SPI port serves as a read-only system monitor port. All registers in the address space are read
accessible over this port. The protocol is effectively the same as the main port except for being read-only. Note
that data is clocked in on the rising edge of the SPI2_CLK.
When using this port, one must always transmit the full transaction packet. Failure to do so may result in
corruption of data.
SPI2_SS_Z
Header
Don‘t care 16 bit word
dummy
byte
address
SPI2_DIN
0
7
7
0
15
0
valid read cycle:
regdata(15:8)
regdata(7:0)
SPI2_DOUT
Figure 39. SPI Port 2 Protocol (Read Only)
Copyright © 2015–2019, Texas Instruments Incorporated
49
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
7.4 Device Functional Modes
The following diagram in Figure 40 illustrates the functional operating modes of the TPS99000-Q1.
ASYNC Reset
PROJ_ON Low
OFF
PROJ_ON Low or
Software Power Cycle or
Watchdog Error or
Main supplies sequenced on
RESETZ released
Power Good Low
STANDBY
Die Over-temp Error
DMD Enable
POWERING_DMD
DMD power up complete
DISPLAY_RDY
SHUTDOWN
LED Enable
Park Event
LED Disable
PARKING
DISPLAY_ON
Park Event
Park Events include:
Power good low
PROJ_ON Low
Die Over-Temp
Software Park
Watchdog Error
Figure 40. Top Level System States
7.4.1 OFF
The asynchronous internal reset of the device places system in this state. All supplies (DMD supplies, 1.1 V, 1.8
V, 3.3 V) are asynchronously disabled and RESETZ output to DLPC230-Q1 is held low. Once the internal reset
is released, communication over SPI2 is supported.
Exit from OFF state progresses to the STANDBY state. To exit OFF state, the following must all be true:
•
•
•
VMAIN input monitor must show good status.
PROJ_ON (projector on) input pin must be high.
The die temperature warning must indicate the die temperature is below the warning threshold. Upon exit of
OFF state and before entry to STANDBY, the external 1.1 V, 1.8 V, and 3.3 V supplies are powered on in
sequence – first 1.1 V, then 1.8 V, then 3.3 V.
Internal monitors of 1.1 V, 1.8 V, and 3.3 V (and 6 V input on VIN_LDOT_5V) will hold off progression to
STANDBY until all 4 rails are in operational range. After power is good, RESETZ output signal is held low for a
specific period to ensure a proper reset cycle for the DLPC230-Q1, and then it is released to transition to
STANDBY.
7.4.2 STANDBY
Upon entry to STANDBY state, RESETZ is set high and DLPC230-Q1 begins its boot process.
50
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
Device Functional Modes (continued)
Exit options from STANDBY state include:
•
A die over temp error sends system to SHUTDOWN state. An over temperature error in the STANDBY state
means something is wrong with the system.
•
•
•
PROJ_ON low sends to OFF state.
Software commanded power cycle. System proceeds to OFF state.
If either of the watchdog timers have been enabled by software and an error occurs, system proceeds to OFF
state.
•
•
If power unexpectedly goes bad, system proceeds to OFF state.
DLPC230-Q1 software begins to enable DMD voltages. Sends to POWERING_DMD state. This is the first
step in DMD voltage enabling process.
During the STANDBY phase, the DLPC230-Q1 software performs DMD and DLPC230-Q1 sequencer
configuration steps. The software is in charge of DMD voltage enable timing, interleaving necessary DMD
configuration register writes, and DLPC230-Q1 ASIC block configuration steps. After the DLPC230-Q1 software
begins enabling DMD voltages, the TPS99000-Q1 proceeds to POWERING_DMD state.
7.4.3 POWERING_DMD
Once the DLPC230-Q1 software begins enabling DMD voltages when in STANDBY, the system enters
POWERING_DMD state. In this state, the DLPC230-Q1 software performs all steps needed to properly configure
and power up the DMD safely.
Exiting from POWERING_DMD state, the DLPC230-Q1 software confirms that DMD is powered up. This sends
the TPS99000-Q1 to DISPLAY_RDY state. This is the last step in DMD voltage enabling process.
If a PROJ_ON low is received during power on, the TPS99000-Q1 will still complete the power on sequence.
7.4.4 DISPLAY_RDY
In the display ready state, the DLPC230-Q1 may enable illumination at any time.
Once the DLPC230-Q1 software enables illumination, the TPS99000-Q1 enters the DISPLAY state.
Exit conditions:
•
•
Illumination enabled: go to DISPLAY_ON state. (HUD only)
A DMD park event has occurred including power not good, PROJ_ON low, die over temp error, software park
initiated, or software power cycle initiated. These events send the TPS99000-Q1 to PARKING state.
Note: for headlight only applications the TPS99000-Q1 does not enter the DISPLAY_ON state. Illumination turns
on and off while remaining in DISPLAY_RDY.
7.4.5 DISPLAY_ON
System operational, image being displayed. Exit conditions:
•
•
Illumination disabled: go to DISPLAY_RDY state.
An internal DMD park event has occurred (including power not good or PROJ_ON low or die over temp error,
or software park initiated, or software power cycle initiated - sends TPS99000-Q1 to PARKING state.
7.4.6 PARKING
DMD parking is taking place. PARKZ output signal (to DLPC230-Q1) is asserted low in this state. Timers count
down time then the control for the DMD voltage regulators is disabled. Once the final hardware delay elapses,
the next state is STANDBY.
7.4.7 SHUTDOWN
The shutdown state is entered only when a die over temperature condition is experienced. All switchable on chip
activity is halted. The only exit conditions from this state are PROJ_ON low (0) or true power off. This state is
readable via the 2nd diagnostic SPI port. All power supplies are disabled.
Copyright © 2015–2019, Texas Instruments Incorporated
51
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
7.5 Register Maps
7.5.1 System Status Registers
ADDRESS
NAME
BITS
DESCRIPTION
Chip Revision ID, R-only, Reset Value 0000
Unused
Major
[15:8]
Unused
0x00
[7:4]
[3:0]
Major revision
Minor revision
Minor
Status Set, R/W, Reset Value 0000 (Writing a 1 to any bit field sets flag)
PG Fault Status
[15]
[14]
Asserted when any bin in user register 38h is set
DM Max width limit
Maximum DM pulse width achieved. This may or may not be an error, depending on
system operational mode
VXPG Init
[13]
[12]
Power good timer for VOFS, VRST, or VBIAS expired
Main SPI parity error
Parity error on a SPI1 port transaction occurred (command or write data) on previous
command
ADC block error
Checksum error 3
Checksum error 2
Checksum error 1
WD2
[11]
[10]
[9]
"OR" of all errors in ADC block. Refer to x0D to determine specific error.
Checksum error in LED / dimming controller section
Checksum error in light sensor conditioning section
Checksum error in ADC sub-system section
Watchdog #2 error
[8]
[7]
0x01
WD1
[6]
Watchdog #1 error
Top level state change
[5]
Indicates top level state machine has changed state. Can be used to indicate that the
TPS99000-Q1 has exited DISPLAY state unexpectedly due to a random fault
Excessive brightness
VXPG Fault
[4]
[3]
[2]
Excessive brightness detector indicates an over bright fault condition
Set 1 by hardware if power good fault occurs for VOFS, VRST, or VBIAS
DIE Over temp warning
Thermal conditions on chip have reached the warning level. If temperature continues
to rise, system will reach die over temp error temperature and emergency actions will
be taken by TPS99000-Q1
DIE Over temp error
PROJ_ON_LOW
[1]
[0]
Thermal conditions on chip have reached the emergency/error. Emergency actions will
be taken by TPS99000-Q1 to protect the system. This error bit is non-maskable for
PARKZ output
Projector ON input pin is low (produces a 1 on this status bit).
52
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
Register Maps (continued)
ADDRESS
NAME
BITS
DESCRIPTION
General Status 1, R-only, Reset Value 0000
Clock ratio monitor
[15:12] Mid-scale reading (1000 ± 1) indicate approximately 30-MHz external signal has been
applied
Open
[11:8]
[7:5]
Reserved
Last Reset (2:0)
Root cause of last reset cycle, last pass through the OFF state.
“000” – true power on cycle, internal reset set/release
“001” – PROJ_ON went low
“010” – watchdog timer 1 error
“011” – watchdog timer 2 error
“100” – die over temperature error
“101” – SW power cycle command
all others unused
Top State (4:0)
[4:0]
Top level state machine current state
0x00 = SHUTDOWN
0x01 = Internal initialization
0x02 = OFF
0x05
0x03 = Internal initialization
0x04 = Initializing 1P1V
0x05 = Initializing 1P8V
0x06 = Initializing 3P3V
0x07 = De-assert RESETZ
0x08 = STANDBY
0x09 = VOFFSET enabled
0x0A = VBIAS enabled
0x0B = VRESET enabled
0x0C = DISPLAY READY
0x0D = DISPLAY ON
0x0E = Parking initialized
0x0F = VBIAS and VRESET disabled
0x10 = VOFFSET disabled
0x11 = DMD voltage discharge
7.5.2 ADC Control
ADDRESS
NAME
BITS
DESCRIPTION
ADC Block Status SET, Read/Write, Reset Value 0000 (Writing 1 to any bit field sets flag. OR of all ADC error bits feed into single
ADC error bit in main status.)
Unused
[15:8] Reserved
AD3 Command Stop-bit
Error
[7]
Indicates that a stop bit was missing
ADC Timeline Error
[6]
Indicates that a new command was received while previous command
was still in progress
Command error
Parity error detected
Ch2 underflow
[5]
[4]
[3]
An error was detected on a serial bus command
A parity error in bit stream was detected
0x0D
ADC conversion results presented in channel two register experienced
an underflow
Ch2 saturated
Ch1 underflow
Ch1 saturated
[2]
[1]
[0]
ADC conversion results presented in channel two register are
saturated
ADC conversion results presented in channel one register
experienced an underflow
ADC conversion results presented in channel one register are
saturated
Copyright © 2015–2019, Texas Instruments Incorporated
53
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
7.5.3 General Fault Status
ADDRESS
NAME
BITS
DESCRIPTION
General Fault Status, R-only, Reset Value 0000, Value of 1 indicates a Fault
VBIAS Powergood Fault
VRST Powergood Fault
VOFS Powergood Fault
Powergood 1 Fault
[15]
[14]
[13]
[12]
VBIAS is below the minimum specified voltage
VRESET is below the minimum specified voltage
VOFFSET is below the minimum specified voltage
VMAIN or AVDD rail is below the minimum specified voltage (Logical
OR).
Powergood 2 Fault
[10]
[9]
[8]
[7]
[6]
[5]
[4]
[3]
At least one of 1.1 V, 1.8 V, 3.3 V, and 6 V supplies is below the
minimum specified voltage (Logical OR).
ADC 3V LDO
Powergood Fault
ADC 3V LDO is below the minimum specified voltage
ADC 3V LDO is above the maximum specified voltage
TIA 3V LDO is below the minimum specified voltage
TIA 3V LDO is above the maximum specified voltage
TIA 5V LDO is above the maximum specified voltage
ADC 3V LDO Over
Voltage Fault
TIA 3V LDO Powergood
Fault
0x38
TIA 3V LDO Over
Voltage Fault
TIA5 LDO Over Voltage
Fault
TIAM8 LDO Powergood
Fault
Negative 8 V Photo Diode Bias LDO is below the minimum specified
voltage
TIAM8 LDO Over
Voltage Fault
Negative 8 V Photo Diode Bias LDO is above the maximum specified
voltage
V3P3 Powergood Fault
V1P8 Powergood Fault
V1P1 Powergood Fault
[2]
[1]
[0]
3.3 V is below the minimum specified voltage
1.8 V is below the minimum specified voltage
1.1 V is below the minimum specified voltage
54
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
8 Application and Implementation
NOTE
Information in the following applications sections is not part of the TI component
specification, and TI does not warrant its accuracy or completeness. TI’s customers are
responsible for determining suitability of components for their purposes. Customers should
validate and test their design implementation to confirm system functionality.
8.1 Application Information
The DLP553x-Q1 chipset is designed to support projection-based automotive applications such as head-up
displays (HUD) and high resolution headlights.
The DLP553x-Q1 chipset consists of three components—the DLP553x-Q1 (DMD), the DLPC230-Q1, and the
TPS99000-Q1. The DMD is a light modulator consisting of tiny mirrors that are used to form and project images.
The DLPC230-Q1 is a controller for the DMD; it formats incoming video and controls the timing of the DMD
illumination sources and the DMD in order to display the incoming video. The TPS99000-Q1 is a controller for
the illumination sources (LEDs or lasers) and a management IC for the entire chipset. In conjunction, the
DLPC230-Q1 and the TPS99000-Q1 can also be used for system-level monitoring, diagnostics, and failure
detection features.
8.2 Typical Applications
There are two configurations for this chip, HUD and headlight. Table 3 shows the differences for the pin
connections between the two configurations.
Table 3. Pin Configuration Differences for HUD and Headlight
PIN
NAME
DESCRIPTION
HUD
HEADLIGHT
12 COMPOUT
Photodiode (PD) Interface High-
speed comparator output
Connect to DLPC230-Q1 GPIO_02
No connect
No connect
15 SYNC
External LED buck driver sync strobe See Setting the Current Limit
output
18 D_EN
LED Interface; Buck High-Side FET
Drive Enable
Connect to DLPC230-Q1 D_EN
(GPIO_04)
Connect to DLPC230-Q1 D_EN
(GPIO_04) or ground
19 S_EN
LED Bypass Shunt Strobe Input
LED Enable Strobe 0 Input
LED Enable Strobe 1 Input
LED Enable Strobe 2 Input
LED Enable Strobe 3 Input
Drive enable for LM3409
Connect to DLPC230-Q1 S_EN
(GPIO_03)
Connect to DLPC230-Q1 S_EN
(GPIO_03) or ground
20 LED_SEL_0
21 LED_SEL_1
22 LED_SEL_2
23 LED_SEL_3
Connect to DLPC230-Q1
PMIC_LEDSEL_0
Connect to DLPC230-Q1
PMIC_LEDSEL_0 or ground
Connect to DLPC230-Q1
PMIC_LEDSEL_1
Connect to DLPC230-Q1
PMIC_LEDSEL_1 or ground
Connect to DLPC230-Q1
PMIC_LEDSEL_2
Ground
Connect to DLPC230-Q1
PMIC_LEDSEL_3
Ground
38 DRV_EN
39 CMODE
Driver select enable
Resistor to ground
No connect
Capacitor selection output (allows for See CMODE Big Cap Mode in
a smaller capacitance to be used in
CM mode for less over/under shoot).
Open drain
Discontinuous Operation
40 DMUX0
41 DMUX1
43 S_EN1
44 S_EN2
45 R_EN
Digital test point output
Either connect to test point or leave
unconnected. Do not ground.
Either connect to test point or leave
unconnected. Do not ground.
Digital test point output
Either connect to test point or leave
unconnected. Do not ground.
Either connect to test point or leave
unconnected. Do not ground.
Low resistance shunt NFET drive
enable [High means shunt active]
See Continuous Mode S_EN2
Dissipative Load Shunt Options
Shunt enable / No connect
High resistance shunt NFET drive
enable [High means shunt active]
See Continuous Mode S_EN2
Dissipative Load Shunt Options
No connect
Red channel select. Drive for low
side NFET
FET enable
FET enable / No connect
Copyright © 2015–2019, Texas Instruments Incorporated
55
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
Typical Applications (continued)
Table 3. Pin Configuration Differences for HUD and Headlight (continued)
PIN
NAME
DESCRIPTION
HUD
HEADLIGHT
46 G_EN
47 B_EN
57 AMUX1
61 AMUX0
Green channel select. Drive for low
side NFET
FET enable
FET enable
FET enable / No connect
Blue channel select. Drive for low
side NFET
FET enable / No connect
Analog Test Mux Output 1
Either connect to test point or leave
unconnected. Do not ground.
Either connect to test point or leave
unconnected. Do not ground.
Analog Test Mux Output 0
Either connect to test point or leave
unconnected. Do not ground.
Either connect to test point or leave
unconnected. Do not ground.
62 VIN_LDOT_M8 Dedicated TIA Interface –8 V(nom)
LDO external regulation FET drive
Refer to Low Dropout Regulators
Connect as described inLow Dropout
Regulators or do not connect (select
NC option in SW).
signal for -8 V regulator
63 VLDOT_M8
Dedicated TIA Interface –8 V(nom)
LDO filtered supply (regulated
voltage feedback)
Refer to Low Dropout Regulators
Connect as described inLow Dropout
Regulators or do not connect (select
NC option in SW).
76 R_IADJ
77 IADJ
External resistance for IADJ voltage See Setting the Current Limit
to current transformation
Ground
Current output used to adjust
external LED controller drive current
set point
See Setting the Current Limit
Ground
85 ADC_IN1
86 ADC_IN2
88 ADC_IN3
90 ADC_IN4
92 ADC_IN5
93 ADC_IN6
94 ADC_IN7
External ADC Channel 1, see
Table 2
Connect to LED anode with voltage
divider
No connect / Optional (customer use)
No connect / Optional (customer use)
External ADC Channel 2, see
Table 2
Optional (LED input voltage)
External ADC Channel 3, see
Table 2
No connect / Optional (customer use) No connect / Optional (customer use)
No connect / Optional (customer use) No connect / Optional (customer use)
External ADC Channel 4, see
Table 2
External ADC Channel 5, see
Table 2
No Connect / Optional (Thermistor)
No Connect / Optional (Thermistor)
No Connect / Optional (Thermistor)
No connect / Optional (customer use)
No connect / Optional (customer use)
No connect / Optional (customer use)
External ADC Channel 6, see
Table 2
External ADC Channel 7, see
Table 2
Pulldown resistors are required on the pins in the below table to avoid a floating input during the power-up and
power-down conditions.
Table 4. Pulldown Resistor Requirements
PIN
5
NAME
TYP
ADC_MOSI
WD1
10 kΩ
10 kΩ
10 kΩ
10 kΩ
10 kΩ
10 kΩ
10 kΩ
10 kΩ
10 kΩ
10 kΩ
10 kΩ
10 kΩ
6
16
17
18
19
20
21
22
23
27
30
SEQ_START
SEQ_CLK
D_EN(1)
S_EN(1)
LED_SEL_0(1)
LED_SEL_1(1)
LED_SEL_2(1)
LED_SEL_3(1)
SPI1_CLK
SPI1_DIN
(1) If these pins are not connected to the DLPC230-Q1 (as in a Headlight configuration) then they may be tied directly to ground without a
pulldown resistor.
56
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
Table 4. Pulldown Resistor Requirements (continued)
PIN
31
34
49
50
51
NAME
TYP
10 kΩ
10 kΩ
56 kΩ
110 kΩ
68 kΩ
SPI2_DIN
SPI2_CLK
DMD_VOFFSET(2)
DMD_VBIAS(2)
DMD_VRESET(2)
(2) Resistor pull downs are required to create a minimum load for DMD_VOFFSET, DMD_VBIAS, and DMD_VRESET. Each of these
pulldowns should provide a load from 0.1mA to 1mA. If the -8 V LDO is used, then the pull down for DMD_VRESET may be eliminated.
If only one or zero TIAs are used, then these pull downs may draw up to 1mA of current.
8.2.1 HUD
Figure 41. HUD System Block Diagram
8.2.1.1 Design Requirements
The DLPC230-Q1 is a controller for the DMD and the timing of the RGB LEDs in the HUD. It requests the proper
timing and amplitude from the LEDs to achieve the requested color and brightness from the HUD across the
entire operating range. It synchronizes the DMD with these LEDs in order to generate full-color video requested
from the host.
The DLPC230-Q1 receives inputs from a host processor in the vehicle. The host provides commands and input
video data. Read and write (R/W) commands can be sent using either the I2C bus or SPI bus. The bus that is not
being used for R/W commands can be used as a read-only bus for diagnostic purposes. Input video can be sent
over an OpenLDI bus or a parallel 24-bit bus. The SPI flash memory provides the embedded software for the
DLPC230-Q1’s ARM core, color calibration data, and default settings. The TPS99000-Q1 provides diagnostic
and monitoring information to the DLPC230-Q1 using an SPI bus and several other control signals such as
PARKZ, INTZ, and RESETZ to manage power-up and power-down sequencing. The DLPC230-Q1 interfaces to
a TPM411 via I2C for temperature information.
Copyright © 2015–2019, Texas Instruments Incorporated
57
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
The outputs of the DLPC230-Q1 are LED drive information to the TPS99000-Q1, control signals to the DMD, and
monitoring and diagnostics information to the host processor. Based on a host requested brightness and the
operating temperature, the DLPC230-Q1 determines the proper timing and amplitudes for the LEDs. It passes
this information to the TPS99000-Q1 using an SPI bus and several additional control signals such as D_EN,
S_EN, and SEQ_START. It controls the DMD mirrors by sending data over a sub-LVDS bus. It can alert the host
about any critical errors using a HOST_IRQ signal.
The TPS99000-Q1 is a highly-integrated mixed-signal IC that controls DMD power, the analog response of the
LEDs, and provides monitoring and diagnostics information for the HUD system. The power sequencing and
monitoring blocks of the TPS99000-Q1 properly power up the DMD and provide accurate DMD voltage rails, and
then monitor the system’s power rails during operation. The integration of these functions into one IC significantly
reduces design time and complexity. The highly accurate photodiode (PD) measurement system and the
dimming controller block precisely control the LED response. This enables a DLP technology HUD to achieve a
very high dimming range (> 5000:1) with accurate brightness and color across the temperature range of the
system. Finally, the TPS99000-Q1 has several general-purpose ADCs that designers can use for system-level
monitoring, such as over-brightness detection.
The TPS99000-Q1 receives inputs from the DLPC230-Q1, power rail voltages for monitoring, a photodiode that
is used to measure LED response, the host processor, and potentially several other ADC ports. The DLPC230-
Q1 sends commands to the TPS99000-Q1 over a SPI port and several other control signals. The TPS99000-Q1
includes watchdogs to monitor the DLPC230-Q1 and ensure that it is operating as expected. The power rails are
monitored by the TPS99000-Q1 to detect power failures or glitches and request a proper power down of the
DMD in case of an error. The photodiode’s current is measured and amplified using a transimpedance amplifier
(TIA) within the TPS99000-Q1. The host processor can read diagnostics information from the TPS99000-Q1
using a dedicated SPI bus. Additionally the host can request the system to be turned on or off using a PROJ_ON
signal. The TPS99000-Q1 has several general-purpose ADCs that can be used to implement other system
features such as over-brightness and over-temperature detection.
The outputs of the TPS99000-Q1 are LED drive signals, diagnostic information, and error alerts to the DLPC230-
Q1. The TPS99000-Q1 has signals connected to the LM3409 buck controller for high power LEDs and to
discrete hardware that control the LEDs. The TPS99000-Q1 can output diagnostic information to the host and the
DLPC230-Q1 over two SPI busses. It also has signals such as RESETZ, PARKZ, and INTZ that can be used to
trigger power down or reset sequences.
The DMD is a micro-electro-mechanical system (MEMS) device that receives electrical signals as an input (video
data) and produces a mechanical output (mirror position). The electrical interface to the DMD is a sub-LVDS
interface driven with the DLPC230-Q1. The mechanical output is the state of more than 1.3 million mirrors in the
DMD array that can be tilted ±12°. In a projection system, the mirrors are used as pixels in order to display an
image.
8.2.1.2 Application Design Considerations
8.2.1.2.1 Photodiode Considerations
Placement of the photodiode within the optical path is critical to system performance. Carefully optimizing the
placement and electrical response of the photodiode will yield the widest dynamic range for dimming. Treatment
of photodiode considerations are addressed in the Photodiode Selection and Placement Guide (DLPA082).
Several factors for the photodiode should be considered:
•
Position:
–
Ideally, a position in the illumination path (Figure 42) should be located that produces strong, but also
balanced amplitude signal responses from each of the three LEDs at the system's target white point.
Imbalance between the three channels due to non-ideal placement of the detector will limit dynamic range
of the dimming system. The TIA supports an RGB trim function to help re-balance an imbalanced system.
This feature is useful for completing the process of optimizing the balance of the amplitude signal
responses from each LED. But it is still advisable to take care in the design of the illumination path such
that the natural balance of the colors is as ideal as practical.
–
An additional consideration when determining position of photodiode is back scattered light from the
projection path. Some amount of on state light will reflect backwards from the surfaces of the projection
lens and other objects in the light path after the DMD. If the photodiode is placed in a position that is
illuminated by this back scattered light, the photodiode will see a mixture of true illumination light plus this
back scattered output light. If the back scattered light is significant, the illumination control loop will be
58
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
impacted. Also, the back scatter is dependent on the video content (i.e. a solid white pattern may cause
more back scatter than a solid black pattern), which impacts the full-on full-off contrast.
•
Irradiance on the Photodiode:
–
It is also important that the irradiance on the photodiode is not too high or too low. A high magnitude of
irradiance can cause saturation and slower response from the photodiode. This varies depending on the
specific photodiode selected for use. The TPS99000-Q1 provides a negative LDO and negative voltage
source to provide a low noise –8 V reference for reverse biasing the photodiode. Reverse biasing the
photodiode (photo conductive mode) increases the amount of irradiance the photodiode can accept
without saturating as compared to a zero bias case (photovoltaic mode). On the other hand, a low
magnitude of irradiance can make the system more susceptible to noise, including photodiode dark
current. It is best to operate at photodiode current levels high enough so that dark current is negligible to
avoid potential issues due to other noise sources (noise on cabling, grounding, etc).
•
Cable to remote PD placement:
–
If the photodiode is located remotely it is recommended to use a low capacitance cable and minimize the
cable length. At a minimum: for noise rejection, use a one conductor shielded cable with the photodiode
bias (cathode) connected to the cable shield and the photodiode output (anode) connected to the inner
conductor. Better noise rejection is possible using shielded two conductor cables with the shield tied to a
low noise ground. Experiments may be necessary to determine an optimal photodiode position to achieve
adequate response balance between the colors and an acceptable irradiance level. Care must be taken to
not exceed the maximum total photodiode capacitance (diode plus cable and connectors) as specified in
Electrical Characteristics - Transimpedance Amplifier Parameters. TIA design includes adjustable
feedback capacitance to optimize response for specific solutions. DLPC230-Q1 flash configuration options
allow tuning of this feedback capacitance for optimal slew rate and stability performance.
Light to DMD
Photo diode located
in illumination path
LED
LED
Figure 42. Photodiode Placement
The photodiode conditioning circuits include several features to improve performance and integration:
•
•
•
Independent red, green and blue parameters for gain and offset
Selectable feedback capacitance
Integrated negative LDO, to provide photodiode reverse bias
8.2.1.2.2 LED Current Measurement
The TPS99000-Q1 includes a dedicated ADC channel for LED current measurement. The blanking current
management process in system software, described in the Continuous Mode Operation section, relies on this
measurement to coordinate the blanking current to the photo feedback current. The software measures the
actual LED current in photo feedback (per color) and also measures the blanking current. The blanking current
setting is fine trimmed during system operation to a level ideal for optimizing the initial current of each light pulse.
As such, it is critical to system performance that this LED current measurement is as noise free as practical.
Using a Kelvin connection to the low side sense resistor, and an RC filter is recommended to filter switching
ripple, as illustrated in Figure 43. The Kelvin resistors should be < 100 Ω each and should have a tolerance of
less than 0.5% matched resistors.
Copyright © 2015–2019, Texas Instruments Incorporated
59
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
83
82
ADC/
mux
12 bit
Figure 43. LED Current Measurement Wiring
8.2.1.2.3 Setting the Current Limit
The current limit of the LM3409 is determined by the current draw of the IADJ pin of the TPS99000-Q1, which is
controlled by an internal DAC and an external resistor connected to the R_IADJ pin of the TPS99000-Q1. The
approximate peak current limit can be calculated by the following equation:
V
____ ____
RADJ RHSS
R
CSP
DAC
ILIM
=
*
Where:
•
•
VDAC is the voltage of the current control DAC.
RADJ is the resistor attached to the R_IADJ pin of the LM3409. Do to the max current this circuit can output, it
is recommended that this value be 1 kΩ or higher
•
•
RSCP is the resistor attached to the CSP pin of the LM3409. Use the same value for RCSN
RHSS is the high side sense resistor of the LM3409 control circuit.
.
60
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
Figure 44. Current Limit Configuration Circuit
8.2.1.2.4 Input Voltage Variation Impact
Although the blanking current control makes the TPS99000-Q1-based systems less susceptible to ill effects from
input voltage variations, it is still recommended that a stable, pre-regulation voltage source be used to supply the
VLED power rail (as shown in the functional block diagram). Changes in input voltage to the driver will have
impact on slew rates or rising edges of ripple waveforms in continuous operation mode. These variations will
slightly alter the total integrated light output per pulse, which can cause noticeable variations in color balance and
brightness as input voltage changes.
8.2.1.2.5 Discontinuous Mode Photo Feedback Considerations
System designs should consider the amount of additional capacitance placed in parallel with the photodiode, and
the capacitance of the photodiode itself. While the TPS99000-Q1 is designed to function with a very wide range
of total capacitance, the lowest light level brightness performance is directly impacted by this capacitance. Higher
TIA1 input capacitance will result in a brighter minimum brightness achievable by the system due to this light
pulse overrun phenomenon. This results in a reduction of dimming range. (For highest performance, system
designer should minimize total capacitance of the photodiode, photodiode cable and connector system).
Copyright © 2015–2019, Texas Instruments Incorporated
61
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
The leading edge of the light pulse in discontinuous mode is controlled by the charging rate of the capacitance in
parallel with the LED. The photo feedback DAC sets the threshold to turn on the shunt FET which shunts the
current away from the LED. Latency in the photo feedback loop will result in the light climbing higher than the
threshold as shown in Figure 45. The amount of light that occurs after the threshold is reached (shown as
hashed green area) is the majority of the light at the lowest discontinuous mode brightness levels. Figure 45 also
shows that a reduction in photo feedback DAC level by a factor of two does not reduce the total light pulse power
by a factor of two because of the light that occurs after the threshold. The amount of light overrun after the
threshold is a function of the photo feedback latency, inductor initial current, capacitance in parallel with the LED,
LED voltage to current characteristics and shunt FET timing.
PFB DAC
Light
threshold X
Latency
PFB DAC
Light
threshold X/2
Latency
Figure 45. Discontinuous Pulse Overrun
8.2.1.2.6 Transimpedance Amplifiers (TIAs, Usage, Offset, Dark Current, Ranges, RGB Trim)
The TPS99000-Q1 includes support for up to 2 system photodiode inputs.
TIA1 is used as the primary photo feedback channel. It supports 14 unique gain settings, spanning 0.75 kV/A to
288 kV/A. In addition, these gain settings can be adjusted downward by a high resolution trim function, in a range
of 1.0x to 0.2x. This trim function has independent RGB settings, supporting color rebalancing (such as trimming
RGB feedback signals so that white light produces roughly equal voltages at TIA output for each color). Color
rebalancing helps keep all three color channels in the working voltage range to maximize dynamic range.
Figure 46 shows the TIA1 model.
62
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
TIA_GAIN(3:0) GAIN#1 GAIN#2 GAIN#3 GAIN2*3
V/A
750
1.5k
3k
6k
9k
12k
18k
24k
36k
48k
72k
96k
144k
288k
—0000“
—0001“
—0010“
—0011“
—0100“
—0101“
—0110“
—0111“
—1000“
—1001“
—1010“
—1011“
—1100“
—1101“
375
750
750
750
750
750
750
750
750
3k
2
2
4
8
4
4
8
8
4
4
8
8
4
8
1
1
1
1
3
4
3
4
12
4
2
2
4
8
Stage#1
Gain
12
16
24
32
48
16
24
32
48
96
(mA)
(mV)
70
GAIN#1
375,
750,
3k
3k
3k
3k
3
4
12
12
true
photo
signal
dark
current
3kW
photodiode signals
RGB
trim
Dark Stage#2
Gain
Dark
+
Offset
Stage#3
Gain
-
Offset
+
A
B
C
D
+
+
+
TIA
output
+
Input
Offset
+
-
œ
GAIN#2
2 ,4 ,8
GAIN#3
1 ,3 ,4 , 12
0.2-1.0 ( 1 to 256)*1.5mV
TIA1_INP_OFF_R/G/B(2:0) *20mV TIA1_TRIM_R/G/B(7:0)
TIA1_DARKOFF_R/G/B(7:0)
00
01
10
11
A
ADC
channel
30
B
C
D
(TIA1)
ADC_TIA1_SM_SEL(1:0)
Figure 46. TIA1 Trim, Offset, and Gain Stages
TIA2 supports a single trim value and single darkoffset value, but is otherwise identical to TIA1.
NOTE
TIA2 shall only be used for diagnostic purposes, and it is not recommended to use for
primary photo feedback amplification. If TIA2 is used to measure projector output or
illumination light, this lack of multiplexed RGB parameters for trim and dark offset will limit
its usage to looking only at one color at a time for situations where highest gain settings
are used in combination with high color to color electrical response imbalance. For lower
gain settings or situations where the photodiode responses are naturally balanced, all 3
colors likely can be monitored with TIA2.
The trim settings may be used to lower the total gain of the TIA amplifiers. This provides flexibility to allow higher
photo diode currents to be used without saturating the TIA. For example, with the trim setting limited to 0.5×, a
0.75-kV/A gain selection can be considered a 0.375-kV/A effective gain setting. The supported maximum photo
diode current doubles in this case.
Both TIAs are designed to support a wide range of photo diode capacitances. A variable, internal compensation
capacitor network is available to tune the circuit for maximum performance for a given photo diode and cable
combination.
Copyright © 2015–2019, Texas Instruments Incorporated
63
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
Both TIAs can be independently enabled or disabled. When a TIA is disabled, it is placed in a low power mode to
optimize power consumption.
TIA2 can be used for an over-brightness detection input or ADC measurements. It supports two outputs: 1) a
higher bandwidth output, optimized for measuring photo diode response of CM bit slice light pulses, and 2) a
much lower bandwidth output, optimized for measuring light flux filter over periods spanning at least one video
frame. TIA1 supports these same two outputs, plus one more: a very high bandwidth output used for the real-
time color control loop photo feedback. See Electrical Characteristics - Transimpedance Amplifier Parameters for
BW and slew rate specifications for this use case.
One potential use for TIA2 is for system level brightness detection.
8.2.2 Headlight
Figure 47. Headlight System Block Diagram
8.2.2.1 Design Requirements
The DLPC230-Q1 is a controller for the DMD and the light sources in headlight applications. It receives input
video from the host and synchronizes DMD and light source timing in order to achieve the desired video. The
DLPC230-Q1 formats input video data that is displayed on the DMD. It synchronizes these video segments with
light source timing in order to create video with grayscale shading.
The DLPC230-Q1 receives inputs from a host processor in the vehicle. The host provides commands and input
video data. R/W commands can be sent using either the I2C bus or SPI bus. The bus that is not being used for
R/W commands can be used as a read-only bus for diagnostic purposes. Input video can be sent over an
OpenLDI bus or a parallel 24-bit bus. The 24-bit bus can be limited to only 8-bits of data for single light source
systems such as headlights. The SPI flash memory provides the embedded software for the DLPC230-Q1’s
ARM core, any calibration data, and default settings. The TPS99000-Q1 provides diagnostic and monitoring
information to the DLPC230-Q1 using an SPI bus and several other control signals such as PARKZ, INTZ, and
RESETZ to manage power-up and power-down sequencing. The TMP411 uses an I2C interface to provide the
DMD array temperature to the DLPC230-Q1.
64
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
The outputs of the DLPC230-Q1 are configuration and monitoring commands to the TPS99000-Q1, timing
controls to the LED or laser driver, control signals to the DMD, and monitoring and diagnostics information to the
host processor. The DLPC230-Q1 communicates with the TPS99000-Q1 over an SPI bus. It uses this to
configure the TPS99000-Q1 and to read monitoring and diagnostics information from the TPS99000-Q1. The
DLPC230-Q1 sends drive enable signals to the LED or laser driver, and synchronizes this with the DMD mirror
timing. The control signals to the DMD are sent using a sub-LVDS interface.
The TPS99000-Q1 is a highly integrated mixed-signal IC that controls DMD power, the timing and amplitude of
the LEDs or lasers, and provides monitoring and diagnostics information for the headlight system. The power
sequencing and monitoring blocks of the TPS99000-Q1 properly power up the DMD and provide accurate DMD
voltage rails, and then monitor the system’s power rails during operation. The integration of these functions into
one IC significantly reduces design time and complexity. The TPS99000-Q1 also has several output signals that
can be used to control a variety of LED or laser driver topologies. The TPS99000-Q1 also has several general-
purpose ADCs that designers can use for system level monitoring, such as over-brightness detection.
The TPS99000-Q1 receives inputs from the DLPC230-Q1, the power rails it monitors, the host processor, and
potentially several other ADC ports. The DLPC230-Q1 sends configuration and control commands to the
TPS99000-Q1 over an SPI bus and several other control signals. The TPS99000-Q1 includes watchdogs to
monitor the DLPC230-Q1 and ensure that it is operating as expected. The power rails are monitored by the
TPS99000-Q1 in order to detect power failures or glitches and request a proper power down of the DMD in case
of an error. The host processor can read diagnostics information from the TPS99000-Q1 using a dedicated SPI
bus. Additionally the host can request the image to be turned on or off using a PROJ_ON signal. Lastly, the
TPS99000-Q1 has several general-purpose ADCs that can be used to implement system level monitoring
functions.
The outputs of the TPS99000-Q1 are diagnostic information and error alerts to the DLPC230-Q1, and control
signals to the LED or laser driver. The TPS99000-Q1 can output diagnostic information to the host and the
DLPC230-Q1 over two SPI busses. In case of critical system errors, such as power loss, it outputs signals to the
DLPC230-Q1 that trigger power down or reset sequences. It also has output signals that can be used to
implement various LED or laser driver topologies.
The DMD is a micro-electro-mechanical system (MEMS) device that receives electrical signals as an input (video
data), and produces a mechanical output (mirror position). The electrical interface to the DMD is a sub-LVDS
interface with the DLPC230-Q1. The mechanical output is the state of more than 1.3 million mirrors in the DMD
array that can be tilted ±12°. In a projection system the mirrors are used as pixels in order to display an image.
Copyright © 2015–2019, Texas Instruments Incorporated
65
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
9 Power Supply Recommendations
The TPS99000-Q1 requires two power inputs and also provides several power outputs, as well as controlling
additional external power supplies. The power supply architecture is explained in Power Supply Architecture.
9.1 TPS99000-Q1 Power Supply Architecture
•
6.5 V is the recommended operating voltage for HUD designs because the LM3409 locks out at voltages
below 6 V; therefore, the system designer may choose 6.5 V to power both devices. If the LM3409 is not
used with the TPS99000 (as in most headlight designs), then any voltage may be used that meets the
Recommended Operating Conditions of the device.
•
3.3 V (LDO recommended)
9.2 TPS99000-Q1 Power Outputs
•
DMD Required Voltages:
–
–
–
DMD_VOFFSET
DMD_VBIAS
DMD_VRESET
•
•
–8 V Photodiode Bias
Internally used LDOs. These are not designed to be used externally, but are listed here as they require
external bypass capacitors:
–
–
–
5 V
3.3 V TIA
3.3 V ADC
9.3 Power Supply Architecture
The power supply architecture depends on the amount of power required for the illumination source. For HUD
applications which require precise color and white point control, it is highly recommended to pre-regulate the
illumination power supply, as voltage variations can cause variations in the LED output. For non-color critical
applications, the designer may choose to completely isolate the illumination driver. In addition, if 2 or more LEDs
are driven in series, then the pre-regulated voltage must be higher than the voltage of the LEDs. The different
architectures are shown below.
Note that the architectures make use of the LM25118 as a pre-regulator. This part uses a buck-boost
architecture which allows it to supply the required 6.5 V with a battery voltage input of 6 V to 18 V. If the battery
input can be assured to be above the 6.5 V output voltage, then a buck architecture can be used instead,
resulting in BOM savings.
66
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
Power Supply Architecture (continued)
Figure 48. Architecture Number 1: HUD Application with LED Forward Voltage Less Than 5 V
In this application, the same pre-regulator is used to power the 6.5 V rail as well as the LM3409. Since the
LM3409 input voltage must be kept above 6 V, the pre-regulator is set to 6.5 V.
Copyright © 2015–2019, Texas Instruments Incorporated
67
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
Power Supply Architecture (continued)
Figure 49. Architecture Number 2: HUD Application with Two LEDs in Series Configuration
In this application, the pre-regulator must be designed to operate at a higher output voltage in order to drive 2
LEDs in series. Because the TPS99000-Q1 requires a VIN from 5.5 V to 7 V, a small buck regulator is used to
generate a 6 V power rail.
68
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
Power Supply Architecture (continued)
Figure 50. Architecture Number 3: Headlight Application with Independent Illumination
In this application, the power used to drive the illumination is separate from the TPS99000-Q1. This is possible in
applications where the illumination driver can be very simple. Although the LM25118 is shown here, a different
regulator would likely be selected in this application because the maximum current requirements are much less
with the illumination power path removed.
Copyright © 2015–2019, Texas Instruments Incorporated
69
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
10 Layout
10.1 Layout Guidelines
The TPS99000-Q1 is both a power and precision analog IC. As such, care must be taken to the layout of certain
signals and circuits within the system. Along with general layout best practices, pay attention to the following
areas of detail, which are discussed in this document.
•
•
•
•
•
•
Power/high current signals
Sensitive analog signals
High speed digital signals
High power current loops
Kelvin sensing connections
Ground separation
10.1.1 Power/High Current Signals
The TPS99000-Q1 contains two blocks that switch a relatively high amount of current. The first of these is the
switching regulator which generates the voltages used by the DMD. The second is the integrated LED FET gate
drivers.
The DMD regulator consists of the following pins of the TPS99000-Q1:
Table 5. TPS99000-Q1 DMD Regulator Pins
PIN
49
50
51
52
53
54
55
56
NAME
PEAK BOARD CURRENT
800 mA
DMD_VOFFSET
DMD_VBIAS
DMD_VRESET
DRST_LS_IND
DRST_PGND
DRST_HS_IND
VIN_DRST
800 mA
800 mA
800 mA
800 mA
800 mA
800 mA
VSS_DRST
800 mA
The value of 800 mA for these pins relates to the peak current through the inductor due to the nature of the
switching regulator architecture. The DC current for these paths will be closer to the load current drawn by the
DMD.
The high current LED gate drive pins consist of the following pins of the TPS99000-Q1:
Table 6. TPS99000-Q1 High Current LED Gate Driver Pins
PIN
42
43
44
45
46
47
48
NAME
DRVR_PWR
S_EN1
PEAK BOARD CURRENT
1 A
1 A
S_EN2
1 A
R_EN
100 mA
100 mA
100 mA
1 A
G_EN
B_EN
VSS_DRVR
Again, these values are for peak currents. In a typical application, these signals will be driven at a relatively low
average frequency, about 10 kHz. Assuming a FET gate capacitance of 2 nF and that the FETS are driven at 6
V, the magnitude of the DC current draw of these signals is approximately:
I = 2 × C × deltaV × f = 2(2 nF)(6 V)(10 kHz) = 240 µA
(1)
For the power and ground signals, this number should be multiplied by the number of active FETs, giving a value
around 1.25 mA.
70
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
In addition to these high current signals that are driven by the TPS99000-Q1, the LED driver electronics will likely
have other circuits which handle the high currents required by the LEDs. These currents may be as high as 6 A
and therefore will also require special consideration by the layout engineer. As a guide for the PCB trace width
requirements, the reader is referred to TI’s Application Note (SLUA366). The PCB trace widths used in TI’s
design were:
Table 7. PCB Trace Widths
SIGNAL GROUP
DMD Regulator
Gate Drivers
PCB TRACE WIDTH
10 mils
5 mils
LED Driver
200 mils minimum, but maximize where possible to decrease power loses
10.1.2 Sensitive Analog Signals
The following signals are analog inputs to TPS99000-Q1. Most of these analog inputs are DC levels and are
somewhat insensitive to noise, but others are part of the real-time color control algorithm of the TPS99000-Q1
and therefore must be kept immune from noise injection from other signals. The list of analog input pins is as
follows:
Table 8. TPS99000-Q1 Analog Input Pins
PIN
70
73
82
83
85
86
88
90
92
93
94
96
97
98
NAME
TIA_PD2
TIA_PD1
LS_SENSE_N
LS_SENSE_P
ADC_IN1
ADC_IN2
ADC_IN3
ADC_IN4
ADC_IN5
ADC_IN6
ADC_IN7
V3P3V
SIGNAL TYPE
Real-time
Real-time
Real-time
Real-time
Real-time
DC
DC
DC
DC
DC
DC
DC
V1P8V
DC
V1P1V
DC
In particular, the photodiode inputs TIA_PD1 and TIA_PD2 are especially sensitive to noise as they are inputs to
very high gain amplifiers. It is recommended to shield these signals from noise with a ground trace next to the
signal.
10.1.3 High Speed Digital Signals
The TPS99000-Q1 has three serial interfaces that are used to transmit data into and out of the device. All these
of these interfaces have a maximum clock speed of 30 MHz. In order to help prevent against high levels of EMI
emissions, these signals should be laid out with impedance matched, low inductance traces. In particular, the
three clocks for these interfaces should be low inductance, and if a cable or a connector is used, the clock signal
should be adjacent to the ground signal return.
Table 9. SPI1 Interface from DLPC230-Q1 to TPS99000-Q1
PIN
27
28
29
30
NAME
FUNCTION
Clock (30 MHz)
Slave Select
Data
SPI1_CLK
SPI1_SS_Z
SPI1_DOUT
SPI1_DIN
Data
Copyright © 2015–2019, Texas Instruments Incorporated
71
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
Table 10. SPI2 Interface from Customer MCU to TPS99000-Q1
PIN
31
32
33
34
NAME
FUNCTION
Data
SPI2_DIN
SPI2_DOUT
SPI2_SS_Z
SPI2_CLK
Data
Slave Select
Clock (Up to 30 MHz)
Table 11. ADC3 Interface from DLPC230-Q1 to TPS99000-Q1
PIN
4
NAME
FUNCTION
Data
ADC_MISO
ADC_MOSI
5
Data
17
SEQ_CLK
Clock (30 MHz)
To avoid crosstalk, a PCB trace spacing requirement is suggested, such as the “3 W rule” which specifies that if
the trace width is 5 mils, then traces should be spaced out at least 15 mils from center to center. On TI’s PCB
design, the typical trace spacing was 20 mils.
As explained in the Discontinuous Mode Operation section, the COMPOUT signal indicates to the DLPC230-Q1
that the discontinuous mode light pulses have been completed. It is critical that this signal has a fast response
time in order to create small light pulses. For this reason, it is recommended that this signal has a limited trace
capacitance, as mentioned in Table 12.
Table 12. Trace Capacitance
PIN
NAME
PARAMETER
TYP
MAX
UNIT
12
COMPOUT
Trace capacitance
20
50
pF
10.1.4 High Power Current Loops
Due to the architecture of switched mode power supplies used to power the LED driver, there exist several
current loops which can create interference. The best way to mitigate the effects of these loops is to minimize the
area. Since the location of these loops is dependent on the LED drive architecture, the reader is referred to the
data sheets of those parts for specific layout recommendation guidelines.
However, the TPS99000-Q1 does add an additional current loop which is specific to how it enables the LEDs in
low brightness conditions. When operating the TPS99000-Q1 in discrete pulsed mode to achieve low light levels
of LEDs, current flows through a shunt FET in the LED driver, creating a current loop which can inject noise into
other circuits. The current loop is shown in Figure 51.
Inductor current
Charge in Capacitors
shunted to ground
Discharged
PFET
0.1 µF
1 µF
S_EN1
Shunt
Fet
CMODE
R_EN
G_EN
B_EN
0.020
Figure 51. Discontinuous Mode Current Loop
72
Copyright © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
Here, the net LED_COMMON_ANODE is at the forward voltage of the LED when it is conducting current, and
LOW_SIDE_SENSE is at near ground potential. When forming pulses in discrete pulsed mode, the S_EN1 FET
redirects the current from the LED, causing it to turn off quickly. This has the added effect of discharging the 1 µF
capacitor, creating a brief, high current loop consisting of the S_EN1 FET, the CMODE FET, and the 1 µF
capacitor. There is also a secondary loop created by the S_EN1 FET and the 0.1 µF capacitor. This set of
components should be placed in a way to keep these loops small. One such possible placement is shown in
Figure 52.
Figure 52. High Power Layout
10.1.5 Kelvin Sensing Connections
There are many places in the system design where the current through a signal path is measured by use of a
sense resistor in series with the signal path. In these cases, the resistor should be connected by use of a “Kelvin”
connection, or a “Force-Sense” connection. This means that two connections are made to the resistor that carry
the high level of current, and two connections are made separately to measure the voltage across the resistor.
This prevents the sense lines from being affected by the extra resistance of the copper traces, and makes the
measurement more accurate. An example of the “Force-Sense” connection is shown in Figure 53.
Figure 53. Kelvin Sensing Layout
Copyright © 2015–2019, Texas Instruments Incorporated
73
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
The TPS99000-Q1 uses a sense resistor to measure the current delivered to the LEDs. These differential sense
lines are the inputs to the part LS_SENSE_P and LS_SENSE_N. It is important to notice that although
LS_SENSE_N may be electrically connected to ground by the netlist, this signal must be routed as a separate
trace to prevent it from being affected by changes in the ground plane.
10.1.6 Ground Separation
Separated ground planes are good for isolating noise from different parts of the circuit to other. However, when
designing with separate ground planes, one must be careful of how the signals are routed to avoid large
inductive loops. If separate ground planes are used, TI recommends the following ground connections to the
TPS99000-Q1. In addition, the grounds should be connected electrically by a via or 0 Ω resistor. If a unified
ground plane is used, the following can be used as a guideline for which groups of signals should be routed
apart from other signals.
Table 13. TPS99000-Q1 Ground Separation
PIN
NAME
VSS_IO
GROUND
Digital
13, 35
24
DVSS
Digital
25, 60, 75, 99
PBKG
Analog
Power
Power
Power
Analog
Analog
Analog
Analog
Analog
48
VSS_DRVR
DRST_PGND
VSS_DRST
GND_LDO
VSS_TIA
AVSS
53
56
66
71, 72
78, 100
81, 84, 87, 89, 91
Thermal Pad
VSSL_ADC
DAP
74
版权 © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
11 器件和文档支持
11.1 器件支持
11.1.1 第三方产品免责声明
TI 发布的与第三方产品或服务有关的信息,不能构成与此类产品或服务或保修的适用性有关的认可,不能构成此类
产品或服务单独或与任何 TI 产品或服务一起的表示或认可。
11.2 商标
DLP is a registered trademark of Texas Instruments.
All other trademarks are the property of their respective owners.
11.3 静电放电警告
这些装置包含有限的内置 ESD 保护。 存储或装卸时,应将导线一起截短或将装置放置于导电泡棉中,以防止 MOS 门极遭受静电损
伤。
11.4 术语表
SLYZ022 — TI 术语表。
这份术语表列出并解释术语、缩写和定义。
12 机械、封装和可订购信息
以下页面包含机械、封装和可订购信息。这些信息是指定器件的最新可用数据。数据如有变更,恕不另行通知,且
不会对此文档进行修订。如需获取此数据表的浏览器版本,请查阅左侧的导航栏。
版权 © 2015–2019, Texas Instruments Incorporated
75
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
12.1 Package Option Addendum
12.1.1 Tape and Reel Information
REEL DIMENSIONS
TAPE DIMENSIONS
K0
P1
W
B0
Reel
Diameter
Cavity
A0
A0 Dimension designed to accommodate the component width
B0 Dimension designed to accommodate the component length
K0 Dimension designed to accommodate the component thickness
Overall width of the carrier tape
W
P1 Pitch between successive cavity centers
Reel Width (W1)
QUADRANT ASSIGNMENTS FOR PIN 1 ORIENTATION IN TAPE
Sprocket Holes
Q1 Q2
Q3 Q4
Q1 Q2
Q3 Q4
User Direction of Feed
Pocket Quadrants
Package
Type
Package
Drawing
Reel
Diameter (mm)
Reel
Width W1 (mm)
A0
(mm)
B0
(mm)
K0
(mm)
P1
(mm)
W
(mm)
Pin1
Quadrant
Device
Pins
SPQ
TPS99000PZPRQ1
HTQFP
PZP
100
76
版权 © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
TAPE AND REEL BOX DIMENSIONS
Width (mm)
H
W
L
Device
Package Type
HTQFP
Package Drawing Pins
PZP 100
SPQ
Length (mm) Width (mm)
Height (mm)
TPS99000PZPRQ1
版权 © 2015–2019, Texas Instruments Incorporated
77
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
12.1.2 Mechanical Drawings
PACKAGE OUTLINE
PowerPADTMTQFP - 1.2 mm max height
PZP0100K
SCALE 1.000
PLASTIC QUAD FLATPACK
PIN 1 ID
14.2
13.8
B
A
100
76
1
75
14.2
13.8
16.2
15.8
TYP
25
51
50
26
0.27
0.17
100X
96X 0.5
4X 12
0.08
C A B
1.2 MAX
SEE DETAIL A
C
SEATING PLANE
0.08 C
0.09-0.20
TYP
50
26
25
51
0
MIN
4X (0.26)
NOTE 4
0.25
GAGE PLANE
(1)
12X
(0.2)
NOTE 4
6.00
4.68
0.75
0.45
0.15
0.05
0 -7
DETAIL A
TYPICAL
D
E
T
A
I
L
C
A
EXPOSED
THERMAL PAD
12X (0.4)
NOTE 4
75
1
76
100
6.00
4.68
4218999/A 12/2018
PowerPAD is a trademark of Texas Instruments.
NOTES:
1. All linear dimensions are in millimeters. Any dimensions in parenthesis are for reference only. Dimensioning and tolerancing
per ASME Y14.5M.
2. This drawing is subject to change without notice.
3. Reference JEDEC registration MS-026, variation ACD.
4. Strap features may not be present,
www.ti.com
78
版权 © 2015–2019, Texas Instruments Incorporated
TPS99000-Q1
www.ti.com.cn
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
EXAMPLE BOARD LAYOUT
PowerPADTM TQFP - 1.2 mm max height
PZP0100K
PLASTIC QUAD FLATPACK
(
12) NOTE 8
(6)
SYMM
SOLDER MASK
DEFINED PAD
100
76
100X (1.5)
1
75
100X (0.3)
96X (0.5)
(6)
SYMM
(15.4)
(1.35)
TYP
SOLDER MASK
OPENING
25
51
(
0.2) TYP
VIA
METAL COVERED
BY SOLDER MASK
26
50
(1.35) TYP
SEE DETAILS
(15.4)
LAND PATTERN EXAMPLE
EXPOSED METAL SHOWN
SCALE:5X
0.05 MIN
ALL AROUND
0.05 MAX
ALL AROUND
SOLDER MASK
METAL
EXPOSED
METAL
EXPOSED
METAL
METAL UNDER
SOLDER MASK
SOLDER MASK
OPENING
NON SOLDER MASK
DEFINED
SOLDER MASK
DEFINED
SOLDER MASK DETAILS
4218999/A 12/2018
NOTES: (continued)
5. Publication IPC-7351 may have alternate designs.
6. Solder mask tolerances between and around signal pads can vary based on board fabrication site.
7. This package is designed to be soldered to a thermal pad on the board. For more information, see Texas Instruments literature
numbers SLMA002 (www.ti.com/lit/slma002) and SLMA004 (www.ti.com/lit/slma004).
8. Size of metal pad may vary due to creepage requirement.
www.ti.com
版权 © 2015–2019, Texas Instruments Incorporated
79
TPS99000-Q1
ZHCSIF5F –DECEMBER 2015–REVISED APRIL 2019
www.ti.com.cn
EXAMPLE STENCIL DESIGN
PowerPADTM TQFP - 1.2 mm max height
PZP0100K
PLASTIC QUAD FLATPACK
(6)
BASED ON
0.125 THICK STENCIL
SEE TABLE FOR
SYMM
DIFFERENT OPENINGS
FOR OTHER STENCIL
THICKNESSES
76
100
100X (1.5)
100X (0.3)
1
75
96X (0.5)
SYMM
(15.4)
(6)
BASED ON
0.125 THICK
STENCIL
51
25
26
50
METAL COVERED
BY SOLDER MASK
(15.4)
SOLDER PASTE EXAMPLE
EXPOSED PAD
100% PRINTED SOLDER COVERAGE BY AREA
SCALE:5X
STENCIL
THICKNESS
SOLDER STENCIL
OPENING
0.1
6.71 X 6.71
6 X 6 (SHOWN)
5.48 X 5.48
0.125
0.150
0.175
5.07 X 5.07
4218999/A 12/2018
NOTES: (continued)
9. Laser cutting apertures with trapezoidal walls and rounded corners may offer better paste release. IPC-7525 may have alternate
design recommendations.
10. Board assembly site may have different recommendations for stencil design.
www.ti.com
80
版权 © 2015–2019, Texas Instruments Incorporated
PACKAGE OPTION ADDENDUM
www.ti.com
10-Dec-2020
PACKAGING INFORMATION
Orderable Device
Status Package Type Package Pins Package
Eco Plan
Lead finish/
Ball material
MSL Peak Temp
Op Temp (°C)
Device Marking
Samples
Drawing
Qty
(1)
(2)
(3)
(4/5)
(6)
TPS9900TPZPQ1
TPS9900TPZPRQ1
ACTIVE
ACTIVE
HTQFP
HTQFP
PZP
PZP
100
100
90
RoHS & Green
NIPDAU
Level-3-260C-168 HR
Level-3-260C-168 HR
-40 to 105
-40 to 105
TPS9900TPZP
TPS9900TPZP
1000 RoHS & Green
NIPDAU
(1) The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2) RoHS: TI defines "RoHS" to mean semiconductor products that are compliant with the current EU RoHS requirements for all 10 RoHS substances, including the requirement that RoHS substance
do not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, "RoHS" products are suitable for use in specified lead-free processes. TI may
reference these types of products as "Pb-Free".
RoHS Exempt: TI defines "RoHS Exempt" to mean products that contain lead but are compliant with EU RoHS pursuant to a specific EU RoHS exemption.
Green: TI defines "Green" to mean the content of Chlorine (Cl) and Bromine (Br) based flame retardants meet JS709B low halogen requirements of <=1000ppm threshold. Antimony trioxide based
flame retardants must also meet the <=1000ppm threshold requirement.
(3) MSL, Peak Temp. - The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.
(4) There may be additional marking, which relates to the logo, the lot trace code information, or the environmental category on the device.
(5) Multiple Device Markings will be inside parentheses. Only one Device Marking contained in parentheses and separated by a "~" will appear on a device. If a line is indented then it is a continuation
of the previous line and the two combined represent the entire Device Marking for that device.
(6)
Lead finish/Ball material - Orderable Devices may have multiple material finish options. Finish options are separated by a vertical ruled line. Lead finish/Ball material values may wrap to two
lines if the finish value exceeds the maximum column width.
Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information
provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and
continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.
TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.
Addendum-Page 1
PACKAGE OPTION ADDENDUM
www.ti.com
10-Dec-2020
Addendum-Page 2
PACKAGE MATERIALS INFORMATION
www.ti.com
5-Jan-2022
TRAY
Chamfer on Tray corner indicates Pin 1 orientation of packed units.
*All dimensions are nominal
Device
Package Package Pins SPQ Unit array
Max
matrix temperature
(°C)
L (mm)
W
K0
P1
CL
CW
Name
Type
(mm) (µm) (mm) (mm) (mm)
TPS9900TPZPQ1
PZP
HTQFP
100
90
6 X 15
150
315 135.9 7620 15.4
20.3
21
Pack Materials-Page 1
GENERIC PACKAGE VIEW
PZP 100
14 x 14, 0.5 mm pitch
PowerPAD TM TQFP - 1.2 mm max height
PLASTIC QUAD FLATPACK
Images above are just a representation of the package family, actual package may vary.
Refer to the product data sheet for package details.
4224739/A
www.ti.com
PACKAGE OUTLINE
PZP0100K
PowerPADTM TQFP - 1.2 mm max height
SCALE 1.000
PLASTIC QUAD FLATPACK
PIN 1 ID
14.2
13.8
B
A
100
76
1
75
14.2
13.8
16.2
15.8
TYP
25
51
50
26
0.27
0.17
100X
96X 0.5
4X 12
0.08
C A B
1.2 MAX
SEE DETAIL A
C
SEATING PLANE
0.08 C
0.09-0.20
TYP
50
26
25
51
0
MIN
4X (0.26)
NOTE 4
0.25
GAGE PLANE
(1)
12X
(0.2)
NOTE 4
6.00
4.68
0.75
0.45
0.15
0.05
0 -7
DETAIL A
DETAIL
SCALE: 12
A
EXPOSED
THERMAL PAD
TYPICAL
12X (0.4)
NOTE 4
75
1
76
100
6.00
4.68
4218999/A 12/2018
PowerPAD is a trademark of Texas Instruments.
NOTES:
1. All linear dimensions are in millimeters. Any dimensions in parenthesis are for reference only. Dimensioning and tolerancing
per ASME Y14.5M.
2. This drawing is subject to change without notice.
3. Reference JEDEC registration MS-026, variation ACD.
4. Strap features may not be present,
www.ti.com
EXAMPLE BOARD LAYOUT
PZP0100K
PowerPADTM TQFP - 1.2 mm max height
PLASTIC QUAD FLATPACK
(
12) NOTE 8
(6)
SYMM
SOLDER MASK
DEFINED PAD
100
76
100X (1.5)
1
75
100X (0.3)
96X (0.5)
(6)
SYMM
(15.4)
(1.35)
TYP
SOLDER MASK
OPENING
25
51
(
0.2) TYP
VIA
METAL COVERED
BY SOLDER MASK
26
50
(1.35) TYP
SEE DETAILS
(15.4)
LAND PATTERN EXAMPLE
EXPOSED METAL SHOWN
SCALE:5X
0.05 MIN
ALL AROUND
0.05 MAX
ALL AROUND
SOLDER MASK
METAL
EXPOSED
METAL
EXPOSED
METAL
METAL UNDER
SOLDER MASK
SOLDER MASK
OPENING
NON SOLDER MASK
DEFINED
SOLDER MASK
DEFINED
SOLDER MASK DETAILS
4218999/A 12/2018
NOTES: (continued)
5. Publication IPC-7351 may have alternate designs.
6. Solder mask tolerances between and around signal pads can vary based on board fabrication site.
7. This package is designed to be soldered to a thermal pad on the board. For more information, see Texas Instruments literature
numbers SLMA002 (www.ti.com/lit/slma002) and SLMA004 (www.ti.com/lit/slma004).
8. Size of metal pad may vary due to creepage requirement.
www.ti.com
EXAMPLE STENCIL DESIGN
PZP0100K
PowerPADTM TQFP - 1.2 mm max height
PLASTIC QUAD FLATPACK
(6)
BASED ON
0.125 THICK STENCIL
SEE TABLE FOR
SYMM
DIFFERENT OPENINGS
FOR OTHER STENCIL
THICKNESSES
76
100
100X (1.5)
100X (0.3)
1
75
96X (0.5)
SYMM
(15.4)
(6)
BASED ON
0.125 THICK
STENCIL
51
25
26
50
METAL COVERED
BY SOLDER MASK
(15.4)
SOLDER PASTE EXAMPLE
EXPOSED PAD
100% PRINTED SOLDER COVERAGE BY AREA
SCALE:5X
STENCIL
THICKNESS
SOLDER STENCIL
OPENING
0.1
6.71 X 6.71
6 X 6 (SHOWN)
5.48 X 5.48
0.125
0.150
0.175
5.07 X 5.07
4218999/A 12/2018
NOTES: (continued)
9. Laser cutting apertures with trapezoidal walls and rounded corners may offer better paste release. IPC-7525 may have alternate
design recommendations.
10. Board assembly site may have different recommendations for stencil design.
www.ti.com
重要声明和免责声明
TI“按原样”提供技术和可靠性数据(包括数据表)、设计资源(包括参考设计)、应用或其他设计建议、网络工具、安全信息和其他资源,
不保证没有瑕疵且不做出任何明示或暗示的担保,包括但不限于对适销性、某特定用途方面的适用性或不侵犯任何第三方知识产权的暗示担
保。
这些资源可供使用 TI 产品进行设计的熟练开发人员使用。您将自行承担以下全部责任:(1) 针对您的应用选择合适的 TI 产品,(2) 设计、验
证并测试您的应用,(3) 确保您的应用满足相应标准以及任何其他功能安全、信息安全、监管或其他要求。
这些资源如有变更,恕不另行通知。TI 授权您仅可将这些资源用于研发本资源所述的 TI 产品的应用。严禁对这些资源进行其他复制或展示。
您无权使用任何其他 TI 知识产权或任何第三方知识产权。您应全额赔偿因在这些资源的使用中对 TI 及其代表造成的任何索赔、损害、成
本、损失和债务,TI 对此概不负责。
TI 提供的产品受 TI 的销售条款或 ti.com 上其他适用条款/TI 产品随附的其他适用条款的约束。TI 提供这些资源并不会扩展或以其他方式更改
TI 针对 TI 产品发布的适用的担保或担保免责声明。
TI 反对并拒绝您可能提出的任何其他或不同的条款。IMPORTANT NOTICE
邮寄地址:Texas Instruments, Post Office Box 655303, Dallas, Texas 75265
Copyright © 2023,德州仪器 (TI) 公司
相关型号:
©2020 ICPDF网 联系我们和版权申明