CH7308A-TF-TR [CHRONTEL]
Consumer Circuit, CMOS, PQFP64, LEAD FREE, LQFP-64;型号: | CH7308A-TF-TR |
厂家: | CHRONTEL, INC |
描述: | Consumer Circuit, CMOS, PQFP64, LEAD FREE, LQFP-64 商用集成电路 |
文件: | 总22页 (文件大小:409K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
CH7308
Chrontel
CH7308 SDVO1 LVDS Transmitter
Features
General Description
The CH7308 is a display controller device, which accepts
digital graphics input signals, upscales, encodes, and transmits
data through an LVDS transmitter to a LCD panel. This
device accepts one channel of RGB data over three pairs of
serial data ports.
•
•
•
Single/Dual LVDS Transmitter up to 140Mpixels/s
(CH7308A)
Single/Dual LVDS Transmitter up to 165Mpixels/s
(CH7308B)
Support resolutions up to 1600x1200 (1920x1200
with reduced blanking)
The LVDS Transmitter includes a low jitter PLL to generate a
high frequency serialized clock and all circuitry required to
upscale, encode, serialize and transmit data. The CH7308A
supports a maximum single channel pixel rate of 140MP/s
while the CH7308B supports a maximum pixel rate of
165MP/s. The minimum dual channel pixel rate is 100MP/s.
•
•
•
•
•
LVDS low jitter PLL accepts spread spectrum input
LVDS 18-bit and 24-bit outputs
2D dither engine
Panel protection and power sequencing
High-speed SDVO1 serial (1G~2Gbps) AC-coupled
differential RGB inputs
•
•
•
•
•
•
•
Low voltage interface support to graphics device
Programmable power management
Fully programmable through serial port
Configuration through OpCodes1
Complete Windows driver support
Boundary scan support
The LVDS transmitter includes a panel fitting up-scaler and a
programmable dither function to support 18-bit LCD panels.
Data is encoded into commonly used formats, including those
specified in the OpenLDI and SPWG specifications.
Serialized data is outputted on three to eight differential
channels.
Offered in a 64-pin LQFP package
1Intel Proprietary
SC_PROM
SD_PROM
SC_DDC
RESET*
AS
Serial Port/
Power
Control
SPC
SPD
SD_DDC
SDVO_STALL(+/-)
ENAVDD
ENABKL
STALL(+/-) Generator/
Power Sequencing
SDVO_CLK(+/-)
Clock Driver
XTAL
XI/FIN, XO
SDVO_R(+/-)
SDVO_G(+/-)
SDVO_B(+/-)
Data Latch,
Serial To
Parallel
SDVO
Character
Decoder
Up-Scaler
LVDS PLL
LDC[3:0],LDC*[3:0]
LL1C,LL1C*
LDC[7:4],LDC*[7:4]
LL2C,LL2C*
LVDS
Encoder
LVDS
Serializer
LVDS
Driver
Dither
FIFO
VSWING
Figure 1: Functional Block Diagram
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1
CHRONTEL
CH7308
Table of Contents
1.0 Pin Assignment .............................................................................................................................3
1.1
1.2
Package Diagram.......................................................................................................................................3
Pin Description ..........................................................................................................................................4
2.0 Functional Description.................................................................................................................6
2.1
2.2
2.3
2.4
2.5
2.6
2.7
Input Interface............................................................................................................................................6
Automatic Panel-Fitting.............................................................................................................................8
Emission Reduction Clock.........................................................................................................................9
Dithering....................................................................................................................................................9
Power Sequencing .....................................................................................................................................9
Panel Protection.......................................................................................................................................10
Command Interface .................................................................................................................................10
3.0 Register Control .........................................................................................................................13
4.0 Electrical Specifications.............................................................................................................13
4.1
4.2
4.3
4.4
4.5
4.6
4.7
Absolute Maximum Ratings ....................................................................................................................13
Recommended Operating Conditions......................................................................................................13
Electrical Characteristics .........................................................................................................................14
DC Specifications....................................................................................................................................14
AC Specifications....................................................................................................................................16
LVDS Output Specifications ...................................................................................................................17
LVDS Output Timing..............................................................................................................................19
5.0 Package Dimensions...................................................................................................................20
6.0 Revision History .........................................................................................................................21
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CHRONTEL
CH7308
1.0 Pin Assignment
1.1 Package Diagram
64 63 62 61 60 59 58 57 56 55 54 53 52 51 50 49
ENAVBKL
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
SDVO _STALL -
1
SDVO _STALL +
LDC0*
ENAVDD
2
AVDD _PLL
3
4
RESET *
AS
LDC0
LVDD
5
LDC1*
SPC
SPD
6
LDC1
LGND
7
CHRONTEL
CH7308
AGND _PLL
SD_PROM
SC_PROM
8
LDC2*
LDC2
LVDD
LL1C*
LL1C
9
10
11
12
13
14
15
16
SD_DDC
SC_DDC
DGND
XI
LGND
LDC3*
XO
DVDD
LDC3
Figure 2: 64 Pin LQFP Pin Out (Top View)
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CHRONTEL
CH7308
1.2 Pin Description
Table 1: Pin Description
Pin #
Type
Symbol
Description
4
In
RESET*
Reset* Input (Internal pull-up)
When this pin is low, the device is held in the power-on reset
condition. When this pin is high, reset is controlled through the
serial port interface.
5
6
In
AS
Address Select (Internal pull-up)
This pin determines the serial port address of the device
(0,1,1,1,0,0,AS*,0).
Serial Port Clock Input
In/Out
SPC
This pin functions as the clock input of the serial port interface
and operates with from 0 to 2.5V. This pin requires an external
4kΩ - 9kΩ pull up resistor to 2.5V
7
In/Out
In/Out
In/Out
In/Out
In/Out
SPD
Serial Port Data Input/Output
This pin functions as the bi-directional data pin of the serial port
interface and operates with inputs from 0 to 2.5V. Outputs are
driven from 0 to 2.5V. This pin requires an external 4kΩ - 9kΩ
pull up resistor to 2.5V.
9
SD_PROM
SC_PROM
SD_DDC
SC_DDC
Routed Data Output to PROM
This pin functions as the bi-directional data pin of the serial port
interface for the external 5V serial EEPROM used for ADD2 card
designs. This pin requires an external 5.6K pull-up resistor to the
desired high state voltage. Leave open if unused.
Routed Clock Output to PROM
This pin functions as the clock bus of the serial port interface for
the external 5V serial EEPROM used for ADD2 card designs.
This pin requires an external 5.6K pull-up resistor to the desired
high state voltage. Leave open if unused.
10
11
12
Routed Serial Port Data Output to DDC
This pin functions as the bi-directional data pin of the serial port
to the DDC of the receiver. This pin requires an external 4–9kΩ
pull-up resistor to the desired high state voltage. Leave open if
unused.
Routed Serial Port Clock Output to DDC
This pin functions as the clock bus of the serial port to the DDC of
the receiver. This pin requires an external 4–9kΩ pull-up resistor
to the desired high state voltage. Leave open if unused.
Panel Power Enable
Enable LCD panel VDD (2.5V).
Backlight Enable
Enable backlight of LCD panel (2.5V).
BSCAN (internal pull low)
2
Out
Out
In
ENAVDD
ENABKL
BSCAN
1
63
This pin should be left open or be pulled low with 10kΩ resistor.
50
Out
TEST
TEST
Internal test pin to monitor the state of the ENEXBUF (External
Buffer Enable) signal. See TB49 for details. If the ENEXBUF
signal does not need to be monitored, this pin may be left open.
Reserved
64
In
Reserved
This pin should be left open
4
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CHRONTEL
CH7308
Pin#
Type
Symbol
Description
51, 52, 54,
55, 57, 58
In
SDVO_R+/-
SDVO_G+/-
SDVO_B+/-
SDVO Data Channel Inputs
These pins accept 3 AC-coupled differential pair of inputs from
the digital video port of a graphics controller. These 3 pairs of
inputs can be R, G, B. The differential p-p input voltage has a
maximum value of 1.2V, with a minimum value of 175mV.
Differential Clock Input associated with SDVO Data Channel
(SDVO_R+/-, SDVO_G+/-, SDVO_B+/-)
The range of this clock pair is 100~200MHz. For specific pixel
rates in specific modes, this clock pair will run at an integer
multiple of the pixel rate. Refer to section 2.1.2 for details.
Stall Signal Pair associated with SDVO Data Channel
(SDVO_R+/-, SDVO_G+/-, SDVO_B+/-)
60, 61
47, 48
In
SDVO_CLK+/-
Out
SDVO_STALL+/-
This differential pair is used as a stall indication for a VGA
controller, which is capable of driving out SDVO_R+/-,
SDVO_G+/-, SDVO_B+/- data. When toggling between 100MHz
and 200MHz, the stall indication state is asserted (‘1’ value);
when not toggling at all the state is de-asserted (‘0’ value). The
differential p-p output voltage has a maximum value of 1.2V, with
a minimum value of 175mV.
36, 37
17, 18
33, 39, 42,
45, 34, 40,
43, 46
Out
Out
Out
LL1C, LL1C*
LL2C, LL2C*
LDC[3:0], LDC*[3:0]
LVDS Differential Clock Channel 1
LVDS Differential Clock Channel 2
LVDS Differential Data[3:0]
20, 23, 26,
29, 21, 24,
27, 30
Out
In
LDC[7:4], LDC*[7:4]
VSWING
LVDS Differential Data [7:4]
32
LVDS Swing Control
This pin sets the swing level of the LVDS outputs. A 2.4KOhm
resistor should be connected between this pin and LGND using
short and wide traces.
14
15
In
XI/FIN
XO
Crystal Input/External Reference Input
A parallel resonant 14.31818 MHz crystal (+/-1000 ppm) should
be attached between this pin and XO. Alternatively, an external
CMOS compatible clock may be used to drive the XI/FIN input.
Crystal Output
Out
A parallel resonant 14.31818 MHz crystal (+/-1000 ppm) should
be attached between this pin and XI/FIN. However, if an external
CMOS clock is attached to XI/FIN, XO should be left open.
Digital Supply Voltage (2.5V)
Digital Ground
LVDS Supply Voltage (3.3V)
16, 49
13, 31
19, 25, 38,
44
Power
Power
Power
DVDD
DGND
LVDD
22, 28, 35,
41
Power
LGND
LVDS Ground
56, 62
53, 59
3
Power
Power
Power
Power
AVDD
AGND
AVDD_PLL
AGND_PLL
Analog Supply Voltage (2.5V)
Analog Ground
LVDS PLL Supply Voltage (3.3V)
LVDS PLL Ground
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CHRONTEL
CH7308
2.0 Functional Description
2.1 Input Interface
One pair of differential clock signals and three differential pairs of signals (R/G/B) form one channel data. The input
data is 10-bit serialized data. Input data operates from 1GHz~2GHz and is a 10x multiple of the clock rate
(SDVO_CLK+/-). The CH7308 first de-serializes the input into 10-bit parallel data with synchronization and
alignment then the 10-bit characters are mapped into 8-bit color data or control data (Hsync, Vsync, DE).
2.1.1 Interface Voltage Levels
All differential SDVO pairs are AC coupled differential signals. Therefore, there is not a specified DC signal level
for the signals to operate at. The minimum differential p-p input voltage is 175mVand the maximum differential p-p
input voltage is 1.2V. The minimum differential p-p output voltage is 0.247V and the maximum differential p-p
output voltage is 0.453V.
2.1.2 Input Clock and Data Timing
A data character is transmitted least significant bit first. The beginning of a character is noted by the falling edge of
the SDVO_CLK+ edge. The skew among input lanes is required to be no larger than 2ns.
The clock rate must be between 100MHz~200MHz. The pixel rate can be 25MP/s~140MP/s for the CH7308A and
25MP/s~165MP/s for the CH7308B. The pixel rate and the clock rate do not have to be equal. The clock rate is a
multiple of the pixel rate (1x, 2x or 4x depending on the pixel rate) such that the clock rate remains within the
100MHz~200MHz range. In the condition that the clock rate is running at a multiple of the pixel rate, there isn’t
enough pixel data to fill the data channels. Dummy fill characters (‘0001111010’) are used to stuff the data stream.
The CH7308 supports the following clock rate multipliers and fill patterns shown in Table 2.
Table 2: CH7308 supported Pixel Rates, Clock Rates, Data Transfer Rates and Fill Patterns
Pixel Rate
Clock Rate – Multiplier
Stuffing Format
Data Transfer Rate - Multiplier
CH7308A/B
25~50 MP/s
50~100 MP/s
100~140 MP/s
(CH7308A)
100~200 MHz – 4xPixel Rate
100~200 MHz – 2xPixel Rate
100~140 MHz – 1xPixel Rate
Data, Fill, Fill, Fill
Data, Fill
Data
1.00~2.00 GHz – 10xClock Rate
1.00~2.00 GHz – 10xClock Rate
1.00~1.40 GHz – 10xClock Rate
100~165 MP/s
(CH7308B)
100~200 MHz – 1xPixel Rate
Data
1.00~2.00 GHz – 10xClock Rate
2.1.3 Synchronization
Synchronization and channel-to-channel deskewing is facilitated by the transmission of special characters during the
blank period. The CH7308 synchronizes during the initialization period and subsequently uses the blank periods to
re-synch to the data stream.
2.1.4 LVDS-Output
Table 3: Signal Mapping for Single LVDS Channel
18-bit SPWG / 18-bit OpenLDI
24-bit SPWG / 24-bit OpenLDI
LDC[0](1)
LDC[0](2)
LDC[0](3)
LDC[0](4)
LDC[0](5)
LDC[0](6)
LDC[0](7)
LDC[1](1)
R0 / R0
R1 / R1
R2 / R2
R3 / R3
R4 / R4
R5 / R5
G0 / G0
G1 / G1
R0 / R2
R1 / R3
R2 / R4
R3 / R5
R4 / R6
R5 / R7
G0 / G2
G1 / G3
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CHRONTEL
CH7308
LDC[1](2)
LDC[1](3)
LDC[1](4)
LDC[1](5)
LDC[1](6)
LDC[1](7)
LDC[2](1)
LDC[2](2)
LDC[2](3)
LDC[2](4)
LDC[2](5)
LDC[2](6)
LDC[2](7)
LDC[3](1)
LDC[3](2)
LDC[3](3)
LDC[3](4)
LDC[3](5)
LDC[3](6)
LDC[3](7)
G2 / G2
G3 / G3
G4 / G4
G5 / G5
B0 / B0
B1 / B1
B2 / B2
B3 / B3
B4 / B4
G2 / G4
G3 / G5
G4 / G6
G5 / G7
B0 / B2
B1 / B3
B2 / B4
B3 / B5
B4 / B6
B5 / B7
B5 / B5
HSYNC / HSYNC
VSYNC / VSYNC
DE / DE
HSYNC / HSYNC
VSYNC / VSYNC
DE / DE
R6 / R0
R7 / R1
G6 / G0
G7 / G1
B6 / B0
B7 / B1
RES / RES
Table 4: Signal Mapping for Dual LVDS Channel
18-bit SPWG / 18-bit OpenLDI
24-bit SPWG / 24-bit OpenLDI
Ro0 / Ro2
LDC[0](1)
LDC[0](2)
LDC[0](3)
LDC[0](4)
LDC[0](5)
LDC[0](6)
LDC[0](7)
LDC[1](1)
LDC[1](2)
LDC[1](3)
LDC[1](4)
LDC[1](5)
LDC[1](6)
LDC[1](7)
LDC[2](1)
LDC[2](2)
LDC[2](3)
LDC[2](4)
LDC[2](5)
LDC[2](6)
LDC[2](7)
LDC[3](1)
LDC[3](2)
LDC[3](3)
LDC[3](4)
LDC[3](5)
LDC[3](6)
LDC[3](7)
LDC[4](1)
LDC[4](2)
LDC[4](3)
LDC[4](4)
Ro0 / Ro0
Ro1 / Ro1
Ro2 / Ro2
Ro3 / Ro3
Ro4 / Ro4
Ro5 / Ro5
Go0 / Go0
Go1 / Go1
Go2 / Go2
Go3 / Go3
Go4 / Go4
Go5 / Go5
Bo0 / Bo0
Bo1 / Bo1
Bo2 / Bo2
Bo3 / Bo3
Bo4 / Bo4
Bo5 / Bo5
HSYNC / HSYNC
VSYNC / VSYNC
DE / DE
Ro1 / Ro3
Ro2 / Ro4
Ro3 / Ro5
Ro4 / Ro6
Ro5 / Ro7
Go0 / Ro2
Go1 / Ro3
Go2 / Go4
Go3 / Go5
Go4 / Go6
Go5 / Go7
Bo0 / Bo2
Bo1 / Bo3
Bo2 / Bo4
Bo3 / Bo5
Bo4 / Bo6
Bo5 / Bo7
HSYNC / HSYNC
VSYNC / VSYNC
DE / DE
Ro6 / Ro0
Ro7 / Ro1
Go6 / Ro0
Go7 / Go1
Bo6 / Bo0
Bo7 / Bo1
RES / RES
Re0 / Re2
Re1 / Re3
Re2 / Re4
Re0 / Re0
Re1 / Re1
Re2 / Re2
Re3 / Re3
Re3 / Re5
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CHRONTEL
CH7308
LDC[4](5)
LDC[4](6)
LDC[4](7)
LDC[5](1)
LDC[5](2)
LDC[5](3)
LDC[5](4)
LDC[5](5)
LDC[5](6)
LDC[5](7)
LDC[6](1)
LDC[6](2)
LDC[6](3)
LDC[6](4)
LDC[6](5)
LDC[6](6)
LDC[6](7)
LDC[7](1)
LDC[7](2)
LDC[7](3)
LDC[7](4)
LDC[7](5)
LDC[7](6)
LDC[7](7)
Re4 / Re4
Re5 / Re5
Ge0 / Ge0
Ge1 / Ge1
Ge2 / Ge2
Ge3 / Ge3
Ge4 / Ge4
Ge5 / Ge5
Be0 / Be0
Be1 / Be1
Be2 / Be2
Be3 / Be3
Be4 / Be4
Re4 / Re6
Re5 / Re7
Ge0 / Ge2
Ge1 / Ge3
Ge2 / Ge4
Ge3 / Ge5
Ge4 / Ge6
Ge5 / Ge7
Be0 / Be2
Be1 / Be3
Be2 / Be4
Be3 / Be5
Be4 / Be6
Be5 / Be7
Be5 / Be5
HSYNC / LCTLE
VSYNC / LCTLF
DE / LA6RL
HSYNC / LCTLE
VSYNC / LCTLF
DE / LA6RL
Re6 / Re0
Re7 / Re1
Ge6 / Re0
Ge7 / Re1
Be6 / Be0
Be7 / Be1
RES
2.2 Automatic Panel-Fitting
Serialized input data, sync and clock signals are input to the CH7308 from the graphics controller’s serial digital
video output port. Input is through three differential data pairs and one differential clock pair. The data rate is in the
range of 1.0~2.0GHz. The clock rate, independent from the pixel rate, is 1/10 of the data rate, resulting in the range
of 100M~200MHz. Horizontal sync and vertical sync information are embedded in the data stream.
Given the panel information (output timing information), the CH7308 can automatically fit the output timing to the
panel. The up-scaler in the CH7308 supports but is not limited to the following LVDS panel sizes:
Table 5: Popular Panel Sizes
WUXGA
UXGA
Wide SXGA+ (CH7308B)
SXGA+
(CH7308B)
(CH7308B)
1920x1200 ( Reduced Blanking)
1600x1200
1680x1050
1400x1050
1360x1024
1440x900
WSXGA
SXGA
1280x1024
1280x960
WXGA
XGA
1366x768
1024x768
1024x600
SVGA
800x600
The CH7308 is capable of up-scaling images containing 1400 active horizontal pixels or less to the native resolution
of the supported LVDS panel. For resolutions containing more than 1400 horizontal pixels, no up-scaling will be
done. The up-scaler periodically sends a pair of SDVO_STALL(+/-) signals to the graphics controller to halt the
transmission of one line of active video data. When the SDVO_STALL(+/-) signals toggle between 100MHz and
200MHz, this is interpreted as asking for next line of video data to be “stalled”; not toggling at all is considered as
asking for the next line of video data to be sent. The Up-scaler performs 2D interpolation of the graphics input data
and does not change the pixel rate between the input and the output. The 2D interpolation consists of programmable
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CHRONTEL
CH7308
non-linear functions. The maximum pixel rate supported by the Up-scaler is 140MP/s for the CH7308A and
200MP/s for the CH7308B.
2.3 Emission Reduction Clock
LVDS output can support a ±2.5% spreading in the output clock to reduce EMI emissions. The frequency and the
amplitude of the spreading triangle waveform can be programmed via opcode commands.
2.4 Dithering
The dither engine in the CH7308 converts 24-bit per pixel RGB data to 18-bit per pixel RGB data before sending the
data to the LVDS encoder. The maximum pixel rate supported is 140MP/s for the CH7308A and 165MP/s for the
CH7308B. This feature supports 18-bit LVDS panels only.
2.5 Power Sequencing
The CH7308 conforms to the SPWG requirements on power sequencing. The timing specification shown in figure
4 is a superset of the requirements dictated by the SPWG specification. The timing parameters can be programmed
to different values via opcode commands to suit the timing requirements defined by the particular panel
specifications to be used.
T1 T2
T3 T4
T5
ENAVDD
ENEXBUF
ENABKL
LVDS Clocks
LVDS Data
Valid Clock
Valid Data
Tristate or GND
Tristate or GND
Figure 3: Power Sequencing
Table 6: Power Sequencing
Range
Increment
1 ms
T1
T2
T3
T4
T5
1-1023 ms
1-1023 ms
1-1023 ms
1-1023 ms
1-1023 ms
1ms
1ms
1 ms
1ms
The power-on sequence begins when the LVDS software registers are set properly via opcode commands and the
internal PLL lock detection circuit, the internal Sync detection circuit, and the XCLK detection circuit (see section
2.6) indicate that HSYNC, VSYNC and XCLK are stable. The power-off sequence begins when any of the
detection circuits indicates instability in the timing signals (see section 2.6), or through opcode programming. Once
the power-off sequence starts, the internal state machine will complete the power-off sequence and power-on
sequence is allowed only after T5 is passed.
To verify the T1 – T5 LVDS Panel Power Sequencing, please see TB49 for more details.
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CHRONTEL
CH7308
2.6 Panel Protection
Damage to the LCD panel may occur if either HSYNC or VSYNC signals are absent from the LVDS link. This
situation can happen when there is a catastrophic failure in the PC or the graphics system. The CH7308 is designed
to prevent damage to the panel under such a failure. If the system fails, the CH7308 does not expect any software
instruction from the graphics controller to power down the panel. Detection circuits are used to monitor the three
timing signals – HSYNC, VSYNC and XCLK. If any one, combination of, or all of these signals becomes unstable
or missing, the CH7308 will commence Power Down Sequencing.
The power up sequence can occur only if there are no missing HSYNC and VSYNC, the input clock is available, the
PLL clock is stable and the SetActiveOutput opcode is called. The power down sequence is initiated if one of those
conditions fails. The panel protection circuitry is comprised of the PLL Lock Detection block, which detects an
unstable clock from the LVDS PLL, the SYNC Detection block, which detects missing inputs HSYNC and
VSYNC, and the Clock Detection block, which detects missing input CLOCK.
The SYNC Detection block consists of counters to count HSYNC and VSYNC pulses. One counter is used to count
the number of HSYNC pulses per frame over 3 frames. The end counts for all 3 frames must be equal to enable the
power up sequence. In addition, the SYNC Detection block checks for the presence of VSYNC and HSYNC. If
VSYNC is missing for 2 frames or if HSYNC is missing for 32us, the power up sequence is disabled. Conversely, if
the panel has been enabled and the number of HSYNC pulses per frame is different over 3 frames, VSYNC is
missing for 2 frames, or HSYNC is missing for 32us, the CH7308 will go into a power down sequence.
The PLL Lock Detection, SYNC Detection and Clock Detection blocks can be defeated independently. Opcode
commands are supported for these features. The power up sequence can also occur if the panel protection circuitry is
defeated.
2.7 Command Interface
Communication is through a two-wire path, control clock (SPC) and data (SPD). The CH7308 accepts incoming
control clock and data from a graphics controller, and is capable of redirecting that data stream to the ADD2 card
PROM, DDC, or CH7308 internal registers. The control bus is able to run up to 1MHz.
Internal
Device
Registers
control
the
observer
switch
on/off
Control Bus
from VGA
DDC
default
position
PROM
Figure 4: Control Bus Switch
Upon reset, the default state of the control bus direction switch is to redirect the control bus interface to the ADD2
PROM. At this stage, the CH7308 observes the Control bus traffic. If the observing logic sees a control bus
transaction destined for the internal registers (device address 70h or 72h), it disables the PROM output pairs, and
switches to internal registers. In the condition that traffic is to the internal registers, an opcode command is used to
set the redirection circuitry to the appropriate destination (ADD2 PROM or DDC). Redirecting the traffic to internal
registers while at the stage of traffic to DDC occurs on observing a STOP after a START on the control bus.
10
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CHRONTEL
CH7308
2.7.1 NAND Tree Test
CH7308 provides “NAND TREE Testing” to verify IO cell functions at the PC board level. This test will check the
interconnect between the chip’s I/O and the printed circuit board for faults (soldering, bent leads, open printed
circuit board traces, etc.). The NAND tree test is a simple serial logic which turns all IO cell signals to input mode,
connects all inputs with NAND gates as shown in Figure 6 and switches each signal to high or low according to the
sequence in Table 7. The test results are then passed out of pin 48 (SDVO_STALL-). This test is enabled when the
BSCAN pin (pin 63) is set to “1”.
Figure 5: NAND Tree Connection
Testing Sequence
Set BSCAN = 1; (internal weak pull low)
Set all signals listed in Table 7 to 1.
Set all signals listed in Table 7 to 0, toggle one by one with a suggested time period of 200 ns.
Pin 48 will change its value each time an input value changed.
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CHRONTEL
CH7308
Table 7: Signal Order in the NAND Tree Testing
Order
Pin Name
LQFP Pin
1
2
3
4
ENABKL
ENAVDD
RESET*
AS
1
2
4
5
5
SPC
6
6
SPD
7
7
8
9
SD_PROM
SC_PROM
SD_DDC
SC_DDC
XI
XO
LL2C
LL2C*
LDC7
LDC7*
LDC6
LDC6*
LDC5
LDC5*
LDC4
LDC4*
LDC3
LDC3*
LL1C
LL1C*
LDC2
LDC2*
LDC1
LDC1*
LDC0
9
10
11
12
14
15
17
18
20
21
23
24
26
27
29
30
33
34
36
37
39
40
42
43
45
46
47
48
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
LDC0*
SDVOB_STALL+
SDVOB_STALL-
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CHRONTEL
CH7308
3.0 Register Control
The CH7308 is controlled by using Intel opcodes through the serial port. The serial bus uses only the SPC clock to
latch data into registers, and does not use any internally generated clocks so that the device can be written to in all
power down modes. The device will retain all register values during power down modes.
For details regarding Intel® SDVO opcodes, please contact Intel®.
4.0 Electrical Specifications
4.1 Absolute Maximum Ratings
Symbol
Description
Min
Typ
Max
Units
All 2.5V power supplies relative to GND
All 3.3V power supplies relative to GND
-0.5
-0.5
3.0
5.0
V
T
Analog output short circuit duration
Ambient operating temperature
Storage temperature
Indefinite
Sec
°C
°C
°C
°C
°C
°C
SC
T
AMB
-20
-65
85
T
STOR
150
150
260
245
225
T
J
Junction temperature
T
VPS1
Vapor phase soldering (5 seconds)
Vapor phase soldering (11 seconds)
Vapor phase soldering (60 seconds)
T
VPS2
T
VPS3
Note:
1) Stresses greater than those listed under absolute maximum ratings may cause permanent damage to the device.
These are stress ratings only. Functional operation of the device at these or any other conditions above those
indicated under the normal operating condition of this specification is not recommended. Exposure to absolute
maximum rating conditions for extended periods may affect reliability. The temperature requirements of vapor
phase soldering apply to all standard and lead free parts.
2) The device is fabricated using high-performance CMOS technology. It should be handled as an ESD sensitive
device. Voltage on any signal pin that exceeds the power supply voltages by more than ± 0.5V can induce a
destructive latchup.
4.2 Recommended Operating Conditions
Symbol
Description
Min
2.375
3.100
2.375
3.100
3.100
2.375
-20
Typ
2.5
3.3
2.5
3.3
3.3
2.5
Max
2.625
3.500
2.625
3.500
3.500
2.625
70
Units
AVDD
Analog Power Supply Voltage
Analog PLL Power Supply Voltage
Digital Power Supply Voltage
LVDS Power Supply
V
AVDD_PLL
DVDD
V
V
LVDD
V
VDD33
VDD25
Generic for all 3.3V supplies
Generic for all 2.5V supplies
Ambient operating temperature
V
V
°C
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CHRONTEL
CH7308
4.3 Electrical Characteristics
(Operating Conditions: TA = -20°C – 70°C, VDD25 =2.5V ± 5%, VDD33=3.3V± 5%)
Symbol
Description
Min
Typ
Max
Units
Total VDD25 supply current (2.5V supplies)
(no upscaler)
Total VDD33 supply current (3.3V supply)
(no upscaler)
Total VDD25 supply current (2.5V supplies)
(with upscaler enabled)
Total VDD33 supply current (3.3V supply)
(with upscaler enabled)
I
I
I
I
I
VDD25
VDD33
VDD25UP
VDD33UP
PD
170
200
mA
70
270
70
85
mA
mA
mA
uA
340
85
Total Power Down Current (all supplies)
30
4.4 DC Specifications
Symbol
Description
Test Condition
Min
Typ
Max
Unit
SDVO Receiver Differential
Input Peak to Peak Voltage
0.175
1.200
V
VRX-DIFFp-p
VRX-DIFFp-p = 2 *
⏐VRX-D+ - VRX-D-
⏐
SDVO Receiver DC
Differential Input Impedance
80
100
50
120
60
Ω
Ω
Ω
ZRX-DIFF-DC
ZRX-COM-DC
SDVO Receiver DC Common
Mode Input Impedance
40
SDVO Receiver Initial DC
Common Mode Input
Impedance
Impedance allowed
when receiver
terminations are first
turned on
5
50
60
ZRX-COM-
INITIAL-DC
SDVO Stall Differential Output VSTALL-DIFFp-p = 2 *
0.8
1.200
0.4
V
V
V
V
VSTALL-DIFFp-p
Peak to Peak Voltage
⏐VSTALL-D+ - VSTALL-D-
⏐
1
SPD (serial port data) Output
Low Voltage
VSDOL
I
OL
= 2.0 mA
2
Serial Port (SPC, SPD) Input
High Voltage
2.0
GND-0.5
0.25
VDD25+
0.5
VSPIH
2
Serial Port (SPC, SPD) Input
Low Voltage
0.4
VSPIL
Hysteresis of Serial Port
Inputs
V
V
VHYS
VDDCIH
DDC Serial Port
VDD5 +
0.5
Input High Voltage
4.0
VDDCIL
DDC Serial Port
V
V
Input Low Voltage
GND-0.5
4.0
0.4
VPROMIH
PROM Serial Port
Input High Voltage
VDD5 +
0.5
VPROMIL
PROM Serial Port
Input Low Voltage
V
V
GND-0.5
0.4
3
SPD (serial port data) Output
Low Voltage from SD_DDC
(or SD_EPROM)
Input is VINL at
SD_DDC or
SD_EPROM.
0.9*VINL
0.25
+
VSD_DDCOL
4.0KΩ pullup to 2.5V.
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CHRONTEL
CH7308
Symbol
Description
Test Condition
Min
Typ
Max
Unit
4
SC_DDC and SD_DDC
Output Low Voltage
Input is VINL at SPC
and SPD.
0.933*VINL
+ 0.35
V
VDDCOL
5.6KΩ pullup to 5.0V.
5
SC_EPROM and
SD_EPROM Output Low
Voltage
Input is VINL at SPC
and SPD.
0.933*VINL
+ 0.35
V
VEPROMOL
5.6KΩ pullup to 5.0V.
AS
2.0
VDD25 +
0.5
V
V
VASIH
VASIL
Input High Voltage
AS
GND-0.5
0.5
Input Low Voltage
AS Pull Up Current
VIN = 0V
10
40
uA
V
IASPU
RESET*
Input High Voltage
2.7
VDD33 +
0.5
VRESETIH
RESET*
Input Low Voltage
GND-0.5
0.5
V
VRESETIL
RESET* Pull Up Current
VIN = 0V
10
40
uA
V
IRESETPU
VTESTIH
BSCAN
Input High Voltage
2.0
VDD25 +
0.5
BSCAN
Input Low Voltage
GND-0.5
0.5
V
VTESTIL
BSCAN
Pull Down Current
VIN = 2.5V
10
40
uA
V
ITESTPD
VXIIH
XI (for clock input)
Input High Voltage
2.6
VDD33 +
0.5
XI (for clock input)
Input Low Voltage
GND-0.5
VDD-0.2
0.6
V
V
V
VXIIL
ENAVDD, ENABKL
Output High Voltage
IOH = -6.5mA
IOL = 9.0mA
VMISCAOH
VMISCAOL
ENAVDD, ENABKL
Output Low Voltage
0.2
Notes:
1. VSDOL is the SPD output low voltage when transmitting from internal registers, not from DDC or EEPROM.
2. VSPIH and VSPIL are the serial port (SPC and SPD) input low voltage when transmitting to internal registers. Separate
requirements may exist for transmission to the DDC and EEPROM.
3. VSD_DDCOL is the output low voltage at the SPD pin when the voltage at SD_DDC or SD_EPROM is VINL. Maximum output
voltage has been calculated with a worst case pullup of 4.0kΩ to 2.5V on SPD.
4. VDDCOL is the output low voltage at the SC_DDC and SD_DDC pins when the voltage at SPC and SPD is VINL. Maximum output
voltage has been calculated with 5.6k pullup to 3.3V on SC_DDC and SD_DDC.
5. VEPROMOL is the output low voltage at the SC_EPROM and SD_EPROM pins when the voltage at SPC and SPD is VINL
.
Maximum output voltage has been calculated with 5.6kΩ pullup to 5V on SC_EPROM and SD_EPROM.
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CHRONTEL
CH7308
4.5 AC Specifications
Symbol
Description
Test Condition
Min
Typ.
Typ
Max
Unit
UIDATA
SDVO Receiver Unit Interval
for Data Channels
1/[Data
Transfer
Rate]
Typ.
ps
– 300ppm
+ 300ppm
fSDVOB_CLK
fPIXEL
SDVO CLK Input Frequency
100
25
200
200
MHz
MHz
SDVO Receiver Pixel
frequency
fSYMBOL
tRX-EYE
SDVO Receiver Symbol
frequency
1
2
GHz
UI
SDVO Receiver Minimum Eye
Width
0.4
tRX-EYE-JITTER
SDVO Receiver Max. time
between jitter median and
max. deviation from median
0.3
UI
VRX-CM-ACp
SDVO Receiver AC Peak
150
mV
Common Mode Input Voltage
RLRX-DIFF
RLRX-CM
tSKEW
Differential Return Loss
50MHz – 1.25GHz
50MHz – 1.25GHz
Across all lanes
10
6
dB
dB
ns
Common Mode Return Loss
SDVO Receiver Total Lane to
Lane Skew of Inputs
2
XI
CXI
15
pF
Input Capacitance
XI
fTOL XI
-1000
45
+1000
ppm
Input Clock Frequency
Tolerance (when crystal not
used)
XI
DCXI
TSPR
55
%
Input Clock Duty Cycle (when
crystal not used)
SPC, SPD Rise Time
(20% - 80%)
Standard mode 100k
Fast mode 400k
1000
300
150
300
300
150
300
ns
ns
ns
ns
ns
ns
ns
1M running speed
Standard mode 100k
Fast mode 400k
TSPF
SPC, SPD Fall Time
(20% - 80%)
1M running speed
Fast mode 400K
TPROMR
TPROMF
TDDCR
TDDCF
SC_PROM, SD_PROM Rise
Time (20% - 80%)
SC_PROM, SD_PROM Rise
Time (20% - 80%)
Fast mode 400K
300
1000
300
ns
ns
ns
SC_DDC, SD_DDC Rise
Time (20% - 80%)
Standard mode 100k
Standard mode 100k
SC_DDC, SD_DDC Fall
Time (20% - 80%)
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CHRONTEL
CH7308
Symbol
Description
Test Condition
Min
Typ
Max
Unit
1
TDDCR-DELAY
SC_DDC, SD_DDC Rise
Time Delay (50%)
Standard mode 100k
0
ns
1
TDDCF-DELAY
SC_DDC, SD_DDC Fall
Time Delay (50%)
Standard mode 100k
3
ns
Notes:
1.
Refers to the figure below, the delay refers to the time pass through the internal switches.
3.3V typ.
2.5V typ.
R=5K
To SPC/SPD pin
To DDC pin
Figure 6: DDC – SPC/SPD Circuit
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CHRONTEL
CH7308
4.6 LVDS Output Specifications
The LVDS specifications meet the requirements of ANSI/EIA/TIA-644. Refer to Figure 7 for definitions of parameters.
Symbol
Description
Test Condition
Min
Typ
Max
Unit
|Vt|
Steady State Differential
100Ω differential load
247
453
mV
Output Magnitude for logic 1
| Vt *|
Steady State Differential
100Ω differential load
100Ω differential load
247
453
50
mV
mV
Output Magnitude for logic 0
| Vt | - | Vt *|
Steady State Magnitude of
Differential between Logic 1
and 0 Outputs
|VOS
|
Steady State Magnitude of
Offset Voltage for Logic 1
Measured at
1.125
1.125
1.375
1.375
50
V
V
centertap of two 50Ω
resistors connected
between outputs
|VOS*|
Steady State Magnitude of
Offset Voltage for Logic 0
Measured at
centertap of two 50Ω
resistors connected
between outputs
|Vos|-|Vos*|
Steady State Magnitude of
Offset Difference between
Logic States
Measured at
mV
centertap of two 50Ω
resistors connected
between outputs
1
fLLC
LVDS Output Clock
Frequency
25
108
MHz
ns
1
tUI
LVDS data unit time interval
25MHz <
1.3
5.7
f
LLC<108MHz
tr
LVDS data rise time
100Ω and 5pF
differential load
0.3*tUI
1.5
ns
ns
t
UI > 5ns
20%->80% Vswing
1.3ns<tUI<5ns
tf
LVDS data fall time
100Ω and 5pF
differential load
0.3*tUI
1.5
ns
ns
TUI > 5ns
80%->20% Vswing
1.3ns<tUI<5ns
Vring
Voltage ringing after transition 100Ω and 5pF
20%
differential load
Vswing
Note 1: Corresponds to maximum pixel rate fXCLK for single channel operation. Dual channel operation is required for pixel rates
greater than 108MHz.
18
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Rev. 2.41, 3/30/2009
CHRONTEL
CH7308
4.7 LVDS Output Timing
Vring
+/-20% Vswing
0.8 Vswing
+Vt
Vswing
0V Differential
-Vt
0.2 Vswing
tr
tf
tui
Figure 7: AC Timing for LVDS Outputs
Table 8: AC Timing for LVDS Outputs
Symbol
Parameter
Min
Typ
Max
Steady State Differential Output Magnitude
| Vt |
see section 4.6
| Vt | + | Vt *|
Voltage Difference between the two Steady State Values of Output
VSWING
Unit time interval
Rise time
tUi
tr
see section 4.6
see section 4.6
see section 4.6
tf
Fall time
201-0000-064
Rev. 2.41, 3/30/2009
19
CHRONTEL
CH7308
5.0 Package Dimensions
A
B
I
1
A B
H
C
D
J
LEAD
CO-PLANARITY
F
E
.004 “
G
Table of Dimensions
No. of Leads
SYMBOL
64 (10 X 10 mm)
A
B
C
D
E
F
G
H
I
J
Milli-
meters
MIN
MAX
0.17
0.27
1.35
1.45
0.05
0.15
0.45
0.75
0.09
0.20
0°
7°
12
10
0.50
1.00
Figure 8: 64 Pin LQFP Package
20
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CHRONTEL
CH7308
6.0 Revision History
Table 9: Revisions
Rev. #
1.0
1.1
Date
11/23/04
12/20/04
Section
All
2.2
Description
Version 1.0
Updated panel-fitting scaler information.
4.1
Updated T
– Vapor phase soldering information.
VPS
1.2
1/05/05
Ordering
Lead Free tape and reel part number added.
Information
4.1
Note 1 updated.
1.3
1.4
1/27/05
2/2/05
4.4
1.1, 1.2
2.5
Table 8
2.2
1.2
2.6
4.4, 4.5, 4.6, 4.7
4.4
4.5
4.6
Added VMISCAOH and VMISCAOL DC Specification data.
Added TEST pin (pin50) and description.
Updated Figure 4 and added reference to TB49.
Corrected note to which section to refer to
Added Wide SXGA+, 1680 x 1050, to Table 5
Change descriptions for pin 11, 12, 14, 15, 60, 61
Replace “PANEN set to 1” with “SetActiveOutput is called”.
Change spec. values.
Changed conditions and value for VDDCOL
Changed definition of fPIXEL and value for RLRX-DIFF
Changed parameters fLLC, tUI , tR, tF.
1.5
2/7/05
8/8/05
1.61
All
Changed the maximum pixel rate to 140MP/s
Changed the maximum upscale resolution to 1600x900
Updated the table to reflect the new maximum pixel rate of
140MP/s
Features, 2.2
Table 2
2.2
Ordering
Information
Removed panel sizes no longer supported.
Added a footnote stating the current revision of the CH7308A is
revision D and marked as XUD
General Description The last sentence of the 2nd paragraph was edited to avoid
confusion in what is the maximum pixel rate per channel.
1.7
1.8
10/12/05
12/20/05
Ordering
information
4.4, 4.5
Added Green parts into the ordering information.
Added serial interface AC and DC Electrical Specification
information.
General Description Sentence mentioning supported pixel rates for dual panel LVDS
panels (100MP/s to 140MP/s).
3.0 Register Control Changed the first sentence to clarify that the CH7308A is
controlled by use of Intel Opcodes instead of register
reads/writes.
2.0
2.1
1/11/2006 All text and figures
Modified the datasheet to include the CH7308B.
Added CH7308B related information in the features section and
Features and
General Description the second paragraph of the General Description section.
Ordering
Information
Added CH7308B ordering information.
3/13/2008 Features
Added 1600x1200 and 1920x1200 reduced blanking resolution
support.
Pin Description
Table 5
Figure 3
Pin 63 and Pin 64 are changed to “open”
Added 1920x1200 resolution reduced blanking to Table 5.
Added LVDS Clock and LVDS Data to Figure 3.
Updated DC Specifications.
2.2
2.3
8/5/2008
9/22/2008 4.4
2.4
2.41
12/2/2008 4.2, 4.3.
3/30/2009 1.2 Table 1
Updated operating temperature.
Updated description for Pin 63.
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21
CHRONTEL
CH7308
Disclaimer
This document provides technical information for the user. Chrontel reserves the right to make changes at any time
without notice to improve and supply the best possible product and is not responsible and does not assume any
liability for misapplication or use outside the limits specified in this document. We provide no warranty for the use
of our products and assume no liability for errors contained in this document. The customer should make sure that
they have the most recent data sheet version. Customers should take appropriate action to ensure their use of the
products does not infringe upon any patents. Chrontel, Inc. respects valid patent rights of third parties and does not
infringe upon or assist others to infringe upon such rights.
Chrontel PRODUCTS ARE NOT AUTHORIZED FOR AND SHOULD NOT BE USED WITHIN LIFE SUPPORT
SYSTEMS OR NUCLEAR FACILITY APPLICATIONS WITHOUT THE SPECIFIC WRITTEN CONSENT OF
Chrontel. Life support systems are those intended to support or sustain life and whose failure to perform when used
as directed can reasonably expect to result in personal injury or death.
ORDERING INFORMATION
Part Number
CH7308A-TF
Package Type
Number of Pins
64
Voltage Supply
2.5V, 3.3V
Lead Free - LQFP
Lead Free - Tape
and Reel LQFP
CH7308A-TF-TR
CH7308B-TF
64
64
64
2.5V, 3.3V
2.5V, 3.3V
2.5V, 3.3V
Lead Free - LQFP
Lead Free - Tape
and Reel LQFP
CH7308B-TF-TR
Chrontel
2210 O’Toole Avenue, Suite 100,
San Jose, CA 95131-1326
Tel: (408) 383-9328
Fax: (408) 383-9338
www.chrontel.com
E-mail: sales@chrontel.com
©2009 Chrontel, Inc. All Rights Reserved.
Printed in the U.S.A.
22
201-0000-064
Rev. 2.41, 3/30/2009
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