DLP9000XUVFLS_技术文档

DLP9000XUV

DLPS158 –DECEMBER 2019

DLP9000XUV 0.9 UV WQXGA Type A DMD

1 Features

–

Laser marking and repair systems

Computer to plate printers

3D printers

1

•

High resolution 2560 × 1600 (WQXGA) Array

–

> 4 Million micromirrors

•

Medical

7.56-µm micromirror pitch

–

Ophthalmology

Photo therapy

0.9-Inch micromirror array diagonal

±12° micromirror tilt angle

Designed for corner illumination

Integrated micromirror driver circuitry

3 Description

Featuring over

4

million micromirrors, the

•

DLP9000XUV with the DLPC910 controller

DLP9000XUV digital micromirror device (DMD)

enables high resolution and high performance spatial

light modulation of UV wavelengths from 355 nm to

420 nm. The DLP9000XUV is designed with a special

UV optimized window to support numerous

applications in the industrial and medical markets.

Reliable operation of the DLP9000XUV chipset

requires the DMD be driven by the DLPC910

Controller. The DLP9000XUV chipset's architecture

enables continuous data streaming for very high

speed lithographic applications. The 4.1 megapixel

resolution of the DMD enables large 3D print build

sizes and results in fine detail for Digital Lithography.

–

480-MHz input data clock rate

Streams up to 61 gigapixels per second

1-Bit binary patterns up to 14,989 Hz

8-Bit gray patterns up to 1,873 Hz (coupled

with Illumination Modulation)

Designed to steer UV wavelengths from 355 to

420 nm

–

Window transmission 98% (per window pass)

Micromirror reflectivity 88% (nominal)

Array diffraction efficiency 85% (nominal)

Array fill factor 92% (nominal)

Device Information⁽¹⁾

PART NUMBER

PACKAGE

BODY SIZE (NOM)

2 Applications

42.20 mm x 42.20 mm x

7.00 mm

DLP9000XUV

FLS (355)

•

Industrial

Direct imaging lithography

–

(1) For all available packages, see the orderable addendum at

the end of the data sheet.

Simplified Application Schematic

Illumination

Driver

Illumination

Sensor

LVDS Interface

DCLKIN (A,B,C,D), DVALID (A,B,C,D), DIN(A,B,C,D)

Row and Block Signals

ROWMD (1:0), ROWAD (10:0), BLKMD (1:0), BLKAD (3:0), RST2BLKZ

USER

Interface

DOUT(A,B,C,D)[15:0]

DCLKOUT (A,B,C,D)

APPS

FPGA

Control Signals

COMP_DATA.NS_FLIP,WDT_ENBLZ,PWR_FLOAT

SCTRL (A,B,C,D)

Status Signals

RST_ACTIVE, INIT_ACTIVE, ECP2_FINISHED

Connectivity

USB

Ethernet

RESET_ADDR (3:0)

RESET_MODE (1:0)

RESET_SEL (1:0)

JTAG(3:0)

DLP9000XUV

DLPC910

RESET_STRB

RESET_OEZ

Volatile

And

PGM(4:0)

DLPR910

Non-Volatile

Storage

RESET_IRQZ

CTRL_RSTZ

I2C

SCP BUS (3:0)

RESETZ

VLED0

VLED1

OSC

50 MHz

Power Management

Power In

1

An IMPORTANT NOTICE at the end of this data sheet addresses availability, warranty, changes, use in safety-critical applications,

intellectual property matters and other important disclaimers. PRODUCTION DATA.

DLP9000XUV

DLPS158 –DECEMBER 2019

www.ti.com

Table of Contents

8.5 Window Characteristics and Optics ....................... 29

8.6 Micromirror Array Temperature Calculation............ 30

8.7 Micromirror Landed-On/Landed-Off Duty Cycle ..... 31

Application and Implementation ........................ 33

9.1 Application Information............................................ 33

9.2 Typical Applications ................................................ 34

1

2

3

4

5

6

Features.................................................................. 1

Applications ........................................................... 1

Description ............................................................. 1

Revision History..................................................... 2

Pin Configuration and Functions......................... 3

Specifications....................................................... 10

6.1 Absolute Maximum Ratings .................................... 10

6.2 Storage Conditions.................................................. 10

6.3 ESD Ratings............................................................ 11

6.4 Recommended Operating Conditions..................... 11

6.5 Thermal Information................................................ 13

6.6 Electrical Characteristics......................................... 13

6.7 Timing Requirements.............................................. 14

9

10 Power Supply Requirements ............................. 36

10.1 DMD Power Supply Requirements ...................... 36

10.2 DMD Power Supply Power-Up Procedure ........... 36

10.3 DMD Mirror Park Sequence (Power_Float)

Requirements........................................................... 37

10.4 DMD Power Supply Power-Down Procedure ...... 37

11 Layout................................................................... 40

11.1 Layout Guidelines ................................................. 40

11.2 Layout Example .................................................... 42

12 Device and Documentation Support ................. 45

12.1 Device Support...................................................... 45

12.2 Documentation Support ........................................ 46

12.3 Support Resources ............................................... 46

12.4 Trademarks........................................................... 46

12.5 Electrostatic Discharge Caution............................ 46

12.6 Glossary................................................................ 46

6.8 Capacitance at Recommended Operating

Conditions ................................................................ 18

6.9 Typical Characteristics............................................ 18

6.10 System Mounting Interface Loads ........................ 19

6.11 Micromirror Array Physical Characteristics........... 20

6.12 Micromirror Array Optical Characteristics ............. 21

6.13 Optical and System Image Quality........................ 22

6.14 Window Characteristics......................................... 22

6.15 Chipset Component Usage Specification ............. 22

Parameter Measurement Information ................ 23

Detailed Description ............................................ 24

8.1 Overview ................................................................. 24

8.2 Functional Block Diagram ....................................... 25

8.3 Feature Description................................................. 26

8.4 Device Functional Modes........................................ 29

13 Mechanical, Packaging, and Orderable

7

8

Information ........................................................... 46

13.1 Thermal Characteristics ........................................ 46

13.2 Package Thermal Resistance ............................... 46

13.3 Case Temperature ................................................ 46

13.4 Package Option Addendum .................................. 47

4 Revision History

DATE

REVISION

NOTES

December 2019

*

Initial Release.

2

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DLPS158 –DECEMBER 2019

5 Pin Configuration and Functions

FLS Package Connector Terminals

355-Pin CLGA

Bottom View

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DLPS158 –DECEMBER 2019

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TRACE

Pin Functions

(1)

TYPE

(I/O/P)

DATA

INTERNAL

SIGNAL

DESCRIPTION

(2)

(3)

(4)

RATE

TERM

(mils)

NAME

NO.

DATA BUS A

D_AN(0)

D_AN(1)

D_AN(2)

D_AN(3)

D_AN(4)

D_AN(5)

D_AN(6)

D_AN(7)

D_AN(8)

D_AN(9)

D_AN(10)

D_AN(11)

D_AN(12)

D_AN(13)

D_AN(14)

D_AN(15)

D_AP(0)

D_AP(1)

D_AP(2)

D_AP(3)

D_AP(4)

D_AP(5)

D_AP(6)

D_AP(7)

D_AP(8)

D_AP(9)

D_AP(10)

D_AP(11)

D_AP(12)

D_AP(13)

D_AP(14)

D_AP(15)

DATA BUS B

D_BN(0)

D_BN(1)

D_BN(2)

D_BN(3)

D_BN(4)

D_BN(5)

D_BN(6)

D_BN(7)

H10

G3

Input

LVDS

DDR

Differential Data, negative

Differential Data, positive

737

738

739

737

739

736

743

737

739

740

737

738

737

736

739

738

737

739

737

741

737

739

737

G9

F4

F10

E3

E9

D2

J5

C9

F14

B8

G15

B14

H16

D16

H8

G5

G11

F2

F8

E5

E11

D4

J3

C11

F16

B10

H14

B16

G17

D14

AD8

AE3

AF8

AF2

AG5

AH8

AG9

AH2

Input

LVDS

DDR

Differential Data, negative

739

737

736

739

737

739

(1) The following power supplies are required to operate the DMD: V_CC, V_CCI, V_OFFSET, V_BIAS, and V_RESET. V_SSmust also be connected.

(2) DDR = Double data rate.

SDR = Single data rate.

Refer to the Timing Requirements regarding specifications and relationships.

(3) Internal term = CMOS level internal termination. Refer to Recommended Operating Conditions regarding differential termination

specification.

(4) Dielectric constant for the DMD type A ceramic package is approximately 9.6.

For the package trace lengths shown:

Propagation speed = 11.8 / sqrt(9.6) = 3.808 in/ns.

Propagation delay = 0.262 ns/in = 262 ps/in = 10.315 ps/mm.

4

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Pin Functions (continued)

(1)

TYPE

(I/O/P)

DATA

RATE

INTERNAL

TERM

TRACE

(mils)

SIGNAL

DESCRIPTION

(2)

(3)

(4)

NAME

NO.

AL9

D_BN(8)

D_BN(9)

D_BN(10)

D_BN(11)

D_BN(12)

D_BN(13)

D_BN(14)

D_BN(15)

D_BP(0)

D_BP(1)

D_BP(2)

D_BP(3)

D_BP(4)

D_BP(5)

D_BP(6)

D_BP(7)

D_BP(8)

D_BP(9)

D_BP(10)

D_BP(11)

D_BP(12)

D_BP(13)

D_BP(14)

D_BP(15)

DATA BUS C

D_CN(0)

D_CN(1)

D_CN(2)

D_CN(3)

D_CN(4)

D_CN(5)

D_CN(6)

D_CN(7)

D_CN(8)

D_CN(9)

D_CN(10)

D_CN(11)

D_CN(12)

D_CN(13)

D_CN(14)

D_CN(15)

D_CP(0)

D_CP(1)

D_CP(2)

D_CP(3)

D_CP(4)

D_CP(5)

D_CP(6)

D_CP(7)

D_CP(8)

Input

LVDS

DDR

Differential Data, negative

Differential Data, positive

737

738

736

737

740

737

738

737

738

737

740

736

739

737

740

739

AJ11

AF14

AE11

AH16

AD14

AG17

AD16

AD10

AE5

AF10

AF4

AG3

AH10

AG11

AH4

AL11

AJ9

AF16

AE9

AH14

AE15

AG15

AE17

C15

E15

A17

F20

B20

G21

D22

E23

B26

F28

C27

J29

Input

LVDS

DDR

Differential Data, negative

Differential Data, positive

737

736

737

738

737

739

737

739

736

737

738

737

735

737

739

D26

H26

E29

G29

C17

E17

A15

F22

B22

H20

D20

E21

B28

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TRACE

Pin Functions (continued)

(1)

TYPE

(I/O/P)

DATA

INTERNAL

SIGNAL

DESCRIPTION

(2)

(3)

(4)

RATE

TERM

(mils)

NAME

NO.

D_CP(9)

F26

C29

J27

Input

LVDS

DDR

Differential Data, positive

735

737

736

739

736

737

D_CP(10)

D_CP(11)

D_CP(12)

D_CP(13)

D_CP(14)

D_CP(15)

DATA BUS D

D_DN(0)

D28

H28

E27

G27

AJ15

AC27

AK16

AE29

AE21

AF20

AL15

AG29

AD22

AG21

AJ23

AJ29

AF28

AK22

AD28

AK28

AJ17

AC29

AK14

AE27

AD20

AF22

AL17

AG27

AE23

AG23

AJ21

AJ27

AF26

AK20

AD26

AK26

Input

LVDS

DDR

Differential Data, negative

Differential Data, positive

737

738

737

738

737

738

739

738

736

737

741

739

737

738

737

738

737

738

739

738

736

737

740

739

D_DN(1)

D_DN(2)

D_DN(3)

D_DN(4)

D_DN(5)

D_DN(6)

D_DN(7)

D_DN(8)

D_DN(9)

D_DN(10)

D_DN(11)

D_DN(12)

D_DN(13)

D_DN(14)

D_DN(15)

D_DP(0)

D_DP(1)

D_DP(2)

D_DP(3)

D_DP(4)

D_DP(5)

D_DP(6)

D_DP(7)

D_DP(8)

D_DP(9)

D_DP(10)

D_DP(11)

D_DP(12)

D_DP(13)

D_DP(14)

D_DP(15)

SERIAL CONTROL

SCTRL_AN

SCTRL_BN

SCTRL_CN

SCTRL_DN

SCTRL_AP

SCTRL_BP

SCTRL_CP

SCTRL_DP

D8

Input

LVDS

DDR

Differential Serial control, negative

Differential Serial control, positive

736

739

737

739

736

739

AK8

G23

AH28

D10

AK10

H22

AH26

6

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Pin Functions (continued)

(1)

TYPE

(I/O/P)

DATA

RATE

INTERNAL

TERM

TRACE

(mils)

SIGNAL

DESCRIPTION

(2)

(3)

(4)

NAME

NO.

CLOCKS

DCLK_AN

DCLK_BN

DCLK_CN

DCLK_DN

DCLK_AP

DCLK_BP

DCLK_CP

DCLK_DP

H2

AJ5

Input

LVDS

Differential Clock, negative

Differential Clock, positive

740

736

740

736

738

C23

AH22

H4

AJ3

C21

AH20

SERIAL COMMUNICATIONS PORT (SCP)

SCP_DO

SCP_DI

AC3

AD2

AE1

AD4

Output

Input

LVCMOS

SDR

Serial communications port output

Pull-Down Serial communications port data input

Pull-Down Serial communications port clock

SCP_CLK

SCP_ENZ

Pull-Down Active-low serial communications port enable

MICROMIRROR RESET CONTROL

RESET_ADDR(0)

RESET_ADDR(1)

RESET_ADDR(2)

RESET_ADDR(3)

RESET_MODE(0)

RESET_MODE(1)

RESET_SEL(0)

H12

C5

Input

LVCMOS

Pull-Down Reset driver address select

Pull-Down Reset driver mode select

Pull-Down Reset driver level select

B6

A19

J1

G1

AK4

AL13

H6

RESET_SEL(1)

RESET_STROBE

Pull-Down Reset address, mode, and level latched on

rising-edge

ENABLES AND INTERRUPTS

PWRDNZ

B4

Input

LVCMOS

Active-low device reset

RESET_OEZ

AK24

Pull-Down Active-low output enable for DMD reset

driver circuits

RESETZ

AL19

Input

LVCMOS

Pull-Down Active-low sets reset circuits in known

V_OFFSETstate

RESET_IRQZ

C3

Output

Active-low, output interrupt to ASIC

VOLTAGE REGULATOR MONITORING

PG_BIAS

J19

Input

LVCMOS

Pull-Up

Active-low fault from external V_BIASregulator

PG_OFFSET

A13

Active-low fault from external V_OFFSET

regulator

PG_RESET

EN_BIAS

AC19

J15

Input

LVCMOS

Pull-Up

Active-low fault from external V_RESET

regulator

Output

Active-high enable for external V_BIAS

regulator

EN_OFFSET

EN_RESET

H30

J17

Active-high enable for external V_OFFSET

regulator

Active-high enable for external V_RESET

regulator

LEAVE PIN UNCONNECTED

MBRST(0)

MBRST(1)

MBRST(2)

MBRST(3)

MBRST(4)

MBRST(5)

MBRST(6)

MBRST(7)

L5

M28

P4

Output

Analog

Pull-Down For proper DMD operation, do not connect

P30

L3

P28

P2

T28

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TRACE

Pin Functions (continued)

(1)

TYPE

(I/O/P)

DATA

INTERNAL

SIGNAL

DESCRIPTION

(2)

(3)

(4)

RATE

TERM

(mils)

NAME

NO.

MBRST(8)

MBRST(9)

MBRST(10)

MBRST(11)

MBRST(12)

MBRST(13)

MBRST(14)

MBRST(15)

MBRST(16)

MBRST(17)

MBRST(18)

MBRST(19)

MBRST(20)

MBRST(21)

MBRST(22)

MBRST(23)

MBRST(24)

MBRST(25)

MBRST(26)

MBRST(27)

MBRST(28)

MBRST(29)

MBRST(30)

MBRST(31)

M4

L29

T4

Output

Analog

Pull-Down For proper DMD operation, do not connect

N29

N3

L27

R3

V28

V4

R29

Y4

AA27

W3

W27

AA3

W29

U5

U29

Y2

AA29

U3

Y30

AA5

R27

LEAVE PIN UNCONNECTED

RESERVED_PFE

RESERVED_TM

RESERVED_XI0

RESERVED_XI1

RESERVED_XI2

RESERVED_TP0

RESERVED_TP1

RESERVED_TP2

J11

Input

LVCMOS

Analog

Pull-Down For proper DMD operation, do not connect

For proper DMD operation, do not connect

AC7

AC25

AC23

J23

AC9

AC11

AC13

Analog

For proper DMD operation, do not connect

Analog

For proper DMD operation, do not connect

LEAVE PIN UNCONNECTED

RESERVED_BA

RESERVED_BB

RESERVED_BC

RESERVED_BD

RESERVED_TS

AC15

Output

LVCMOS

For proper DMD operation, do not connect

J13

AC21

J21

AC17

LEAVE PIN UNCONNECTED

NO CONNECT

J7

J9

For proper DMD operation, do not connect

J25

8

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Pin Functions

TYPE

(I/O/P)

SIGNAL

DESCRIPTION

(1)

NAME

NO.

Supply voltage for positive bias level of micromirror reset

signal.

V_BIAS

A3, A9, A5, A11, A7, B2

L1, N1, R1

Power

Analog

Supply voltage for HVCMOS logic.

Supply voltage for stepped high voltage at micromirror

address electrodes.

V_OFFSET

U1, W1

AC1, AA1

Supply voltage for offset level of MBRST(31:0).

L31, N31, R31, U31, W31,

AA31

Supply voltage for negative reset level of micromirror reset

signal.

V_RESET

A21, A23, A25, A27, A29,

C1, C31, E31, G31, J31, K2,

AC31, AE31, AG1, AG31,

AJ31, AK2, AK30, AL3, AL5,

AL7, AL21, AL23, AL25,

AL27

Supply voltage for LVCMOS core logic.

Supply voltage for normal high level at micromirror address

electrodes.

V_CC

Power

Analog

H18, H24, M6, M26, P6, P26,

T6, T26, V6, V26, Y6, Y26,

AD6, AD12, AD18, AD24

V_CCI

Supply voltage for LVDS receivers.

A1, B12, B18, B24, B30, C7,

C13, C19, C25, D6, D12,

D18, D24, D30, E1, E7, E13,

E19, E25, F6, F12, F18, F24,

F30, G7, G13, G19, G25, K4,

K6, K26, K28, K30, M2, M30,

N5, N27, R5, T2, T30, U27,

V2, V30, W5, Y28, AB2, AB4,

AB6, AB26, AB28, AB30,

AC5, AD30, AE7, AE13,

V_SS

Power

Analog

Device ground. Common return for all power.

AE19, AE25, AF6, AF12,

AF18, AF24, AF30, AG7,

AG13, AG19, AG25, AH6,

AH12, AH18, AH24, AH30,

AJ1, AJ7, AJ13, AJ19, AJ25,

AK6, AK12, AK18, AL29

(1) The following power supplies are required to operate the DMD: V_CC, V_CCI, V_OFFSET, V_BIAS, and V_RESET. V_SSmust also be connected.

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6 Specifications

6.1 Absolute Maximum Ratings

(1)

See

.

MIN

MAX

UNIT

SUPPLY VOLTAGES

(2)

V_CC

Supply voltage for LVCMOS core logic

–0.5

4

V

(2)

V_CCI

Supply voltage for LVDS receivers

Supply voltage for HVCMOS and micromirror

electrode

V_OFFSET

–0.5

9

V

(2) (3)

(2)

V_BIAS

Supply voltage for micromirror electrode

–0.5

–11

17

0.5

V

(2)

V_RESET

Supply voltage for micromirror electrode

(4)

|V_CC– V_CCI

|V_BIAS– V_OFFSET

INPUT VOLTAGES

|

Supply voltage delta (absolute value)

0.3

(5)

|

Supply voltage delta (absolute value)

8.75

(2)

Input voltage for all other LVCMOS input pins

–0.5

V_CC+ 0.3

V_CCI+ 0.3

700

V

(2) (6)

Input voltage for all other LVDS input pins

(7)

|V_ID

|

Input differential voltage (absolute value)

mV

mA

(7)

I_ID

Input differential current

7

CLOCKS

Clock frequency for LVDS interface, DCLK_A

Clock frequency for LVDS interface, DCLK_B

Clock frequency for LVDS interface, DCLK_C

Clock frequency for LVDS interface, DCLK_D

500

ƒ_clock

MHz

ENVIRONMENTAL

(8)

Array temperature: Operational

20

–40

20

30

90

30

90

T_ARRAY

ºC

(8)

Array temperature: Non–operational

Window temperature: Operational

T_WINDOW

Window temperature: Non–operational

–40

Absolute temperature delta between the window test

points and the ceramic test point TP1⁽⁹⁾

|T_DELTA

|

10

95

ºC

%

R_H

Relative humidity, operating and non–operating

(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 above Recommended Operating Conditions for extended periods may affect device reliability.

(2) All voltages are referenced to common ground V_SS. Supply voltages V_CC, V_CCI, V_OFFSET, V_BIAS, and V_RESETare all required for proper

DMD operation. V_SSmust also be connected.

(3) V_OFFSETsupply transients must fall within specified voltages.

(4) To prevent excess current, the supply voltage delta |V_CCI– V_CC| must be less than specified limit.

(5) To prevent excess current, the supply voltage delta |V_BIAS– V_OFFSET| must be less than specified limit. Refer to Power Supply

Requirements for additional information.

(6) This maximum LVDS input voltage rating applies when each input of a differential pair is at the same voltage potential.

(7) LVDS differential inputs must not exceed the specified limit or damage may result to the internal termination resistors.

(8) The highest temperature of the active array as calculated by the Micromirror Array Temperature Calculation using ceramic test point 1

(TP1) in Figure 15.

(9) Temperature delta is the highest difference between the ceramic test point TP1 and window test points TP2 and TP3 in Figure 15.

6.2 Storage Conditions

Applicable for the DMD as a component or non-operating in a system.

MIN

MAX

80

UNIT

°C

T_DMD

R_H

DMD storage temperature

–40

Relative humidity, (non-condensing)

95

%

10

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6.3 ESD Ratings

VALUE

UNIT

(1)

V_(ESD)

Electrostatic discharge

Human body model (HBM), per ANSI/ESDA/JEDEC JS-001, all pins

±2000

V

(1) JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process.

6.4 Recommended Operating Conditions

Over operating free-air temperature range (unless otherwise noted)⁽¹⁾

MIN

NOM

MAX

UNIT

(2)

SUPPLY VOLTAGES

V_CC

Supply voltage for LVCMOS core logic

3.3

3.45

8.5

3.6

V

V_CCI

Supply voltage for LVDS receivers

(3)

V_OFFSET

V_BIAS

V_RESET

Supply voltage for HVCMOS and micromirror electrodes

8.25

15.5

–9.5

8.75

16.5

–10.5

0.3

16

Supply voltage for micromirror electrodes

–10

(4)

|V_CCI–V_CC

|

Supply voltage delta (absolute value)

(5)

|V_BIAS–V_OFFSET

|

Supply voltage delta (absolute value)

8.75

LVCMOS PINS

V_IH

(6)

High level Input voltage

1.7

2.5

VCC + 0.3

V

(6)

V_IL

Low level Input voltage

–0.3

0.7

–20

15

I_OH

High level output current at V_OH= 2.4 V

Low level output current at V_OL= 0.4 V

mA

ns

I_OL

(7)

T_PWRDNZ

SCP INTERFACE

ƒ_clock

PWRDNZ pulse width

10

(8)

SCP clock frequency

500

800

700

kHz

ns

(9)

t_{SCP_SKEW}

t_{SCP_DELAY}

t_{SCP_BYTE_INTERVAL}

t_{SCP_NEG_ENZ}

t_{SCP_PW_ENZ}

t_{SCP_OUT_EN}

ƒ_clock

Time between valid SCPDI and rising edge of SCPCLK

Time between valid SCPDO and rising edge of SCPCLK

Time between consecutive bytes

–800

(9)

ns

1

30

1

µs

Time between falling edge of SCPENZ and the first rising edge of SCPCLK

SCPENZ inactive pulse width (high level)

ns

µs

Time required for SCP output buffer to recover after SCPENZ (from tri-state)

1.5

ns

(10)

SCP circuit clock oscillator frequency

9.6

11.1

MHz

(1) The functional performance of the device specified in this data sheet is achieved when operating the device within the limits defined by

this table. No level of performance is implied when operating the device above or below these limits.

(2) Supply voltages V_CC, V_CCI, V_OFFSET, V_BIAS, and V_RESETare all required for proper DMD operation. V_SSmust also be connected. All

voltages are referenced to common ground V_SS

.

(3) V_OFFSETsupply transients must fall within specified max voltages.

(4) To prevent excess current, the supply voltage delta |V_CCI– V_CC| must be less than the specified limit.

(5) To prevent excess current, the supply voltage delta |V_BIAS– V_OFFSET| must be less than the specified limit. Refer to Power Supply

Requirements for additional information.

(6) Tester conditions for V_IHand V_IL:

Frequency = 60 MHz. Maximum rise time = 2.5 ns at (20% to 80%)

Frequency = 60 MHz. Maximum fall time = 2.5 ns at (80% to 20%)

(7) PWRDNZ input pin resets the SCP and disables the LVDS receivers. PWRDNZ input pin overrides SCPENZ input pin and tri-states the

SCPDO output pin.

(8) The SCP clock is a gated clock. Duty cycle shall be 50% ± 10%. SCP parameter is related to the frequency of DCLK.

(9) Refer to Figure 1.

(10) SCP internal oscillator is specified to operate all SCP registers. For all SCP operations, DCLK is required.

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Recommended Operating Conditions (continued)

Over operating free-air temperature range (unless otherwise noted)⁽¹⁾

MIN

NOM

MAX

UNIT

LVDS INTERFACE

(11)

ƒ_clock

|V_ID

Clock frequency DCLK

400

100

400 or 480

400

480

600

MHz

mV

ns

(12)

|

Input differential voltage (absolute value)

(12)

V_CM

Common mode

1200

(12)

V_LVDS

t_{LVDS_RSTZ}

Z_IN

LVDS voltage

0

2000

10

Time required for LVDS receivers to recover from PWRDNZ

Internal differential termination resistance

95

90

105

110

Ω

Z_LINE

Line differential impedance (PWB/trace)

100

Ω

ENVIRONMENTAL⁽¹³⁾

Total combined <353 nm⁽¹⁵⁾

10

2.5

5.8

2.5

5.8

5

mW/cm²

W/cm²

W

Max per single wavelength⁽¹⁶⁾

355 nm to 365 nm

W/cm²

W

Total Combined

355 nm to 365 nm

W/cm²

W

Max per single wavelength⁽¹⁶⁾

365 nm to 400 nm

11.6

10

W/cm²

W

Total Combined

365 nm to 400 nm

Illumination power density and illumination

ILL_PDand ILL_TP

total power on the array⁽¹⁴⁾

23.3

15

W/cm²

W

Max per single wavelength⁽¹⁶⁾

400 nm to 420 nm

34.8

15

W/cm²

W

Total Combined

400 nm to 420 nm

34.8

15

W/cm²

W

Total Combined

355 nm to 420 nm

34.8

Thermally

Limited

Total Combined >420 nm⁽¹⁷⁾

W/cm²

(19)

T_ARRAY

Array temperature⁽¹⁸⁾

20

30

°C

T_WINDOW

Window temperature measured at test points TP2 and TP3

Absolute temperature delta between the window test points (TP2, TP3) and the

ceramic test point TP1.⁽²⁰⁾

|T_DELTA

|

10

95

°C

RH

Relative Humidity (non-condensing)

Operating Landed Duty Cycle⁽²¹⁾

%

50

(11) The DLP9000XUV DMD, coupled with the DLPC910, is designed for operation at 2 specific DCLK frequencies only: 400 MHz or 480

MHz, but not random values in between.

(12) Refer to Figure 2, Figure 3, and Figure 4.

(13) Optimal, long-term performance and optical efficiency of the digital micromirror device (DMD) can be affected by various application

parameters, including illumination spectrum, illumination power density, micromirror landed duty-cycle, ambient temperature (storage

and operating), DMD temperature, ambient humidity (storage and operating), and power on or off duty cycle. TI recommends that

application-specific effects be considered as early as possible in the design cycle.

(14) This is the illumination power density and illumination total power input to the DMD micromirror array and does not include illumination

overfill of the DMD device outside the active array.

(15) Any 355 nm or higher illumination source must use a cutoff filter to be at or below this power level by 353 nm. Illumination power from

355 nm down to 353 nm is expected to be diminishing such that the maximum power limit at 353 nm can be achieved.

(16) Integrated power in any single 3 nm band.

(17) Limited by the resulting micromirror array temperature. Refer to T_ARRAY, |T_DELTA|, and Micromirror Array Temperature Calculation for

information related to verifying the DMD temperature meets its requirements.

(18) The array temperature cannot be measured directly and must be computed analytically from the temperature measured at test point 1

(TP1) shown in Figure 15 and the package thermal resistance in Thermal Information using Micromirror Array Temperature Calculation.

(19) Simultaneous exposure of the DMD to the maximum Recommended Operating Conditions for temperature and UV illumination will

reduce device lifetime.

(20) Temperature delta is the highest difference between the ceramic test point (TP1) and window test points (TP2) and (TP3) in Figure 15.

(21) Landed duty cycle refers to the percentage of time an individual micromirror spends landed in one state (12° or –12°) versus the

opposite state (–12° or 12°). 50% equates to a 50/50 duty cycle where the mirror has been landed 50% in the On-state and 50% in the

Off-state. See Micromirror Landed-On/Landed-Off Duty Cycle for more information on Landed Duty Cycle.

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6.5 Thermal Information

DLP9000XUV

(1)

THERMAL METRIC

FLS (CLGA)

355 PINS

0.5

UNIT

Thermal resistance, active area to test point 1 (TP1)

°C/W

(1) The DMD is designed to conduct absorbed and dissipated heat to the back of the package where it can be removed by an appropriate

heat sink. The heat sink and cooling system must be capable of maintaining the package within the temperature range specified in the

Recommended Operating Conditions. The total heat load on the DMD is largely driven by the incident light absorbed by the active area,

although other contributions include light energy absorbed by the window aperture and electrical power dissipation of the array. Optical

systems should be designed to minimize the light energy falling outside the window clear aperture since any additional thermal load in

this area can significantly degrade the reliability of the device.

6.6 Electrical Characteristics

Over operating free-air temperature range (unless otherwise noted)

(1)

PARAMETER

TEST CONDITIONS

V_CC= 3.0 V, I_OH= –20 mA

MIN TYP

MAX UNIT

V_OH

High-level output voltage

Low level output voltage

2.4

V

V_OL

V_CC= 3.6 V, I_OL= 15 mA

V_CC= 3.6 V, V_I= VCC

V_CC= 3.6 V, V_I= 0

V_CC= 3.6 V

0.4

V

(2) (3)

I_IH

High–level input current

Low level input current

250

µA

IlL

–250

I_OZ

High–impedance output current

10

CURRENT

I_CC

V_CC= 3.6 V, DCLK = 480 MHz

V_CCI= 3.6 V, DCLK = 480 MHz

V_OFFSET= 8.75 V

1850

1100

25

(4)

Supply current

mA

I_CCI

I_OFFSET

I_BIAS

(5)

Supply current

V_BIAS= 16.5 V

14

I_RESET

I_TOTAL

POWER

P_CC

V_RESET= –10.5 V

11

Supply current

DLP9000XUV Total Sum

3000

V_CC= 3.6 V

6660

3960

219

mW

P_CCI

V_CCI= 3.6 V

P_OFFSET

P_BIAS

P_RESET

P_TOTAL

CAPACITANCE

C_I

Supply power dissipation

V_OFFSET= 8.75 V

V_BIAS= 16.5 V

231

V_RESET= –10.5 V

Total sum, DCLK = 480 MHz

115

11185

Input capacitance

Output capacitance

ƒ = 1 MHz

10

pF

C_O

Reset group capacitance

MBRST(31:0)

ƒ = 1 MHz; 2560 × 50 micromirrors

230

290

pF

(1) All voltages are referenced to common ground V_SS. Supply voltages V_CC, V_CCI, V_OFFSET, V_BIAS, and V_RESETare all required for proper

DMD operation. V_SSmust also be connected.

(2) Applies to LVCMOS input pins only. Does not apply to LVDS pins and MBRST pins.

(3) LVCMOS input pins utilize an internal 18000 Ω passive resistor for pull-up and pull-down configurations. Refer to Pin Configuration and

Functions to determine pull-up or pull-down configuration used.

(4) To prevent excess current, the supply voltage delta |V_CCI– V_CC| must be less than the specified limit.

(5) To prevent excess current, the supply voltage delta |V_BIAS– V_OFFSET| must be less than the specified limit.

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6.7 Timing Requirements

Over Recommended Operating Conditions (unless otherwise noted)

(1)

MIN

NOM

MAX

UNIT

(2)

SCP INTERFACE

t_r

Rise time

20% to 80%

80% to 20%

200

ns

t_ƒ

Fall time

(2)

LVDS INTERFACE

t_r

Rise time

20% to 80%

80% to 20%

100

400

ps

t_ƒ

Fall time

(3)

LVDS CLOCKS

DCLK_A, 50% to 50%

DCLK_B, 50% to 50%

DCLK_C, 50% to 50%

DCLK_D, 50% to 50%

DCLK_A, 50% to 50%

DCLK_B, 50% to 50%

DCLK_C, 50% to 50%

DCLK_D, 50% to 50%

2.083

1.031

t_c

Cycle time

ns

1.042

t_w

Pulse duration

(3)

LVDS INTERFACE

D_A(15:0) before rising or falling edge of DCLK_A

D_B(15:0) before rising or falling edge of DCLK_B

D_C(15:0) before rising or falling edge of DCLK_C

D_D(15:0) before rising or falling edge of DCLK_D

D_A(15:0) after rising or falling edge of DCLK_A

D_B(15:0) after rising or falling edge of DCLK_B

D_C(15:0) after rising or falling edge of DCLK_C

D_D(15:0) after rising or falling edge of DCLK_D

0.2

0.4

t_su

Setup time

ns

t_h

Hold time

(3)

LVDS INTERFACE

Channel A includes the following LVDS pairs:

DCLK_AP and DCLK_AN

SCTRL_AP and SCTRL_AN

D_AP(15:0) and D_AN(15:0)

–1.04

1.04

ns

Channel B includes the following LVDS pairs:

DCLK_BP and DCLK_BN

SCTRL_BP and SCTRL_BN

D_BP(15:0) and D_BN(15:0)

t_skew

Skew time

Channel C includes the following LVDS pairs:

DCLK_CP and DCLK_CN

SCTRL_CP and SCTRL_CN

D_CP(15:0) and D_CN(15:0)

–1.04

1.04

ns

Channel D includes the following LVDS pairs:

DCLK_DP and DCLK_DN

SCTRL_DP and SCTRL_DN

D_DP(15:0) and D_DN(15:0)

(1) Refer to Pin Configuration and Functions for pin details.

(2) Refer to Figure 5.

(3) Refer to Figure 6.

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t

c

f = 1 / t

clock c

SCPCLK

50%

t_{SCP_SKEW}

SCPDI

50%

t_{SCP_DELAY}

SCPD0

50%

Not to scale.

Refer to SCP Interface section of the Recommended Operating Conditions.

Figure 1. SCP Timing Parameters

(V_IP+ V_IN) / 2

DCLK_P , SCTRL_P , D_P(15:0)

LVDS

Receiver

V_ID

V_IP

DCLK_N , SCTRL_N , D_N(15:0)

V_CM

V_IN

Refer to LVDS Interface section of the Recommended Operating Conditions table.

Refer to Pin Configuration and Functions for a list of LVDS pins.

Figure 2. LVDS Voltage Definitions (References)

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V_{LVDS max}= V_{CM max}+ | 1/2 * V_{ID max}

|

V_CM

V_ID

V_{LVDS min}= V_{CM min}œ | 1/2 * V_{ID max}

|

Not to scale.

Refer to LVDS Interface section of the Recommended Operating Conditions table.

Figure 3. LVDS Voltage Parameters

DCLK_P , SCTRL_P , D_P(15:0)

ESD

Internal

Termination

LVDS

Receiver

DCLK_N , SCTRL_N , D_N(15:0)

ESD

Refer to LVDS Interface section of the Recommended Operating Conditions table.

Refer to Pin Configuration and Functions for list of LVDS pins.

Figure 4. LVDS Equivalent Input Circuit

LVDS Interface

SCP Interface

1.0 * VCC

1.0 * V

ID

V

CM

0.0 * VCC

0.0 * V

ID

t_r

t_f

t_r

t_f

Not to scale.

Refer to the Timing Requirements in Timing Requirements.

Refer to Pin Configuration and Functions for a list of LVDS pins and SCP pins.

Figure 5. Rise Time and Fall Time

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Not to scale.

Refer to LVDS INTERFACE section in the Timing Requirements table.

Figure 6. Timing Requirement Parameter Definitions

Not to scale.

Refer to LVDS INTERFACE section in the Timing Requirements table.

Figure 7. LVDS Interface Channel Skew Definition

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6.8 Capacitance at Recommended Operating Conditions

over operating free-air temperature range (unless otherwise noted)

PARAMETER

Input capacitance

TEST CONDITIONS

ƒ = 1 MHz

MIN

MAX

10

UNIT

pF

C_I

C_O

C_IM

Output capacitance

ƒ = 1 MHz

10

pF

MBRST(31:0) input capacitance

ƒ = 1 MHz. All inputs interconnected.

230

290

pF

6.9 Typical Characteristics

When the DLP9000XUV DMD is controlled by the DLPC910 controller, the digital controller offers streaming 1-bit

binary patterns to the DMD at speeds greater than 61 Gigabits per second (Gbps). The patterns are streamed

from a customer designed applications processor into the DLPC910 input LVDS data interface. Table 1 shows

the pattern rates for the different DMD reset modes.

Table 1. DLPC910 with DLP9000XUV DMD Pattern Rates versus Reset Mode

(3)

RESET MODE⁽¹⁾

Global

MAX PIXEL DATA RATE (Gbps)⁽²⁾

MAX PATTERN RATE (Hz)

53.42

56.46

59.89

61.39

13043

Single

13783⁽⁴⁾

14624⁽⁴⁾

14989⁽⁴⁾

Dual

Quad

(1) Refer to the DLPC910 data sheet in Related Documentation for a description of the reset modes.

(2) Pixel data rates are based on continuous streaming.

(3) Increasing exposure periods may be necessary for a desired application but may decrease pattern rate.

(4) This reset mode typically requires pulsed illumination such as a laser or LED.

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6.10 System Mounting Interface Loads

PARAMETER

MIN

NOM

MAX UNIT

Thermal interface area (See Figure 8)⁽¹⁾⁽²⁾

156

1334

712

N

Maximum system mounting interface

load to be applied to the:

(1)(2)

Electrical interface area

(1)(2)

Datum A interface area

(1) Refer to the DMD Mounting Concepts guide in Related Documentation for more DMD mounting information.

(2) Combined loads of the thermal and electrical interface areas in excess of Datum “A” load shall be evenly distributed outside the Datum

A area (1334 + 156 – Datum A).

Thermal

Interface Area

Electrical

Interface Area

Other Area

Datum ‘A’ Area

Figure 8. System Mounting Interface Loads

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6.11 Micromirror Array Physical Characteristics

VALUE

2560

UNIT

M

N

P

Number of active columns

Number of active rows

micromirrors

1600

micromirrors

Micromirror (pixel) pitch

Micromirror active array width

Micromirror active array height

Micromirror active border

Micromirror total area

See Figure 9

7.56

µm

M × P

19.3536

12.096

14

mm

N × P

(1)

Pond of micromirror (POM)

P²× M × N (converted to cm)

micromirrors/side

cm²

2.341

(1) The structure and qualities of the border around the active array includes a band of partially functional micromirrors called the POM.

These micromirrors are structurally and/or electrically prevented from tilting toward the bright or ON state, but still require an electrical

bias to tilt toward OFF.

0

1

2

3

DMD Active Array

N x P

M x N Micromirrors

N œ 4

N œ 3

N œ 2

N œ 1

M x P

P

Border micromirrors omitted for clarity.

Details omitted for clarity.

P

Not to scale.

P

Refer to section Micromirror Array Physical Characteristics table for M, N, and P specifications.

Figure 9. Micromirror Array Physical Characteristics

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6.12 Micromirror Array Optical Characteristics

Refer to Optical Interface and System Image Quality for important information.

PARAMETER

TEST CONDITIONS

MIN

NOM

MAX

UNIT

Micromirror Landed

(1)

α

β

Micromirror tilt angle

12

degree

(2)

State

(1)(2) (3) (4) (5) (6)

Micromirror tilt angle range tolerance

-1

1

46

0

degree

(7)

Micromirror Hinge Axis Orientation

See Figure 10 and

Figure 13

44

45

Adjacent micromirrors

(8)

Number of out-of-specification micromirrors

micromirrors

Non-adjacent

micromirrors

10

(9) (10)

Micromirror crossover time

Typical performance

2.5

μs

DMD efficiency within the wavelength range 355 nm to 420 nm

68%

(11)

(1) α and β are an average of 5 measured locations on the DMD.

(2) Measured relative to the plane formed by the overall micromirror array.

(3) Additional variation exists between the micromirror array and the package datums.

(4) Represents the landed tilt angle variation relative to the nominal landed tilt angle.

(5) Represents the positive tilt angle variation that can occur between any two individual micromirrors, located on the same device.

(6) For some applications, it is critical to account for the micromirror tilt angle variation in the overall system optical design. With some

system optical designs, the micromirror tilt angle variation within a device may result in perceivable non-uniformities in the light field

reflected from the micromirror array. With some system optical designs, the micromirror tilt angle variation between devices may result in

colorimetry variations, system efficiency variations, or system contrast variations.

(7) When the micromirror array is landed (not parked), the tilt direction of each individual micromirror is dictated by the binary contents of

the CMOS memory cell associated with each individual micromirror. A binary value of 1 results in a micromirror landing in the ON State

direction. A binary value of 0 results in a micromirror landing in the OFF State direction.

(8) An out-of-specification micromirror is defined as a micromirror that is unable to transition between the two landed states within the

specified micromirror switching time.

(9) Micromirror crossover time is primarily a function of the natural response time of the micromirrors.

(10) Performance as measured at the start of life.

(11) Efficiency numbers assume 24-degree illumination angle, F/2.4 illumination and collection cones, uniform source spectrum, and uniform

pupil illumination. Efficiency numbers assume 100% electronic mirror duty cycle and do not include optical overfill loss. Note that this

number is specified under conditions described above and deviations from the specified conditions could result in decreased efficiency.

illumination

Not To Scale

0

1

2

3

On-State

Tilt Direction

Off-State

45°

Tilt Direction

N œ 4

N œ 3

N œ 2

N œ 1

Refer to section Micromirror Array Physical Characteristics table for M, N, and P specifications.

Figure 10. Micromirror Landed Orientation and Tilt

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6.13 Optical and System Image Quality

Optimizing system optical performance and image quality strongly relate to optical system design parameter

trades. Although it is not possible to anticipate every conceivable application, optical performance is contingent

on compliance to the optical system operating conditions described in a) through c) below:

a. Numerical Aperture and Stray Light Control: The angle defined by the numerical aperture of the

illumination and projection optics at the DMD optical area should be the same. This angle should not exceed

the nominal device mirror tilt angle unless appropriate apertures are added in the illumination and/or

projection pupils to block out flat-state and stray light from the projection lens. The mirror tilt angle defines

DMD capability to separate the "ON" optical path from any other light path, including undesirable flat-state

specular reflections from the DMD window, DMD border structures, or other system surfaces near the DMD

such as prism or lens surfaces. If the numerical aperture exceeds the mirror tilt angle, or if the projection

numerical aperture angle is more than two degrees larger than the illumination numerical aperture angle,

artifacts could occur in the projected image of the DMD border region and/or active area.

b. Pupil Match: TI’s optical and image quality specifications assume that the exit pupil of the illumination optics

is nominally centered within two degrees of the entrance pupil of the projection optics. Misalignment of pupils

can create artifacts in the projection of the DMD border region and/or active area which may require

additional system apertures to control, especially if the numerical aperture of the system exceeds the pixel tilt

angle.

c. Illumination Overfill: Overfill light illuminating the DMD area far enough outside the active array may strike

mechanical features that surround the active array or other surface anomalies resulting in scattered or

reflected light which may impact the projected image performance in certain customer applications. The

illumination optical system should be designed to limit these artifacts by minimizing the amount of light

incident outside the active array to the point where the image performance is in line with the expected

application image performance. The design also needs to take into account the particular system’s optical

architecture and light engine assembly tolerances.

NOTE

TI ASSUMES NO RESPONSIBILITY FOR IMAGE QUALITY ARTIFACTS OR DMD

FAILURES CAUSED BY OPTICAL SYSTEM OPERATING CONDITIONS EXCEEDING

LIMITS DESCRIBED ABOVE.

6.14 Window Characteristics

(1)

PARAMETER

Window material designation

Window refractive index

Window aperture

TEST CONDITIONS

MIN

TYP

MAX

UNIT

Corning 7056

1.487

At wavelength 589 nm

(2)

See

Illumination overfill

Refer to Illumination Overfill

Window Artifact Size

Area within the window aperture only.

400

μm

Window transmittance, single–pass

through both surfaces and glass

Minimum within the wavelength range 355 nm to 420 nm.

Applies to all angles 0° to 30° AOI.

97%

(3)

(1) Refer to Window Characteristics and Optics for more information.

(2) For details regarding the size and location of the window aperture, refer to the package mechanical characteristics listed in the

Mechanical ICD in the Mechanical, Packaging, and Orderable Information section.

(3) Refer to the TI application report DLPA031, Wavelength Transmittance Considerations for DLP DMD Window.

6.15 Chipset Component Usage Specification

The DMD is a component of one or more DLP^®chipsets. Reliable function and operation of the DMD requires

that it be used in conjunction with the other components of the applicable DLP chipset, including those

components that contain or implement TI DMD control technology. TI DMD control technology consists of the TI

technology and devices for operating or controlling a DMD.

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7 Parameter Measurement Information

The data sheet provides timing at the device pin. For output timing analysis, the tester pin electronics and its

transmission line effects must be taken into account. Figure 11 shows an equivalent test load circuit for the

output under test. The load capacitance value stated is only for characterization and measurement of AC timing

signals. This load capacitance value does not indicate the maximum load the device is capable of driving.

Timing reference loads are not intended as a precise representation of any particular system environment or

depiction of the actual load presented by a production test. System designers should use IBIS or other simulation

tools to correlate the timing reference load to a system environment. Refer to the Application and Implementation

section.

Device Pin

Tester Channel

Output Under Test

C_LOAD

Figure 11. Test Load Circuit

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8 Detailed Description

8.1 Overview

The DMD is a 0.9 inch diagonal spatial light modulator which consists of an array of highly reflective aluminum

micromirrors. Pixel array size and square grid pixel arrangement are shown in Figure 9.

The DMD is an electrical input, optical output micro-electrical-mechanical system (MEMS). The electrical

interface is Low Voltage Differential Signaling (LVDS), Double Data Rate (DDR).

The DMD consists of a two-dimensional array of 1-bit CMOS memory cells. The array is organized in a grid of M

memory cell columns by N memory cell rows. Refer to the Functional Block Diagram.

The positive or negative deflection angle of the micromirrors can be individually controlled by changing the

address voltage of underlying CMOS addressing circuitry and micromirror reset signals (MBRST).

Each cell of the M × N memory array drives its true and complement (‘Q’ and ‘QB’) data to two electrodes

underlying one micromirror, one electrode on each side of the diagonal axis of rotation. Refer to Micromirror

Array Optical Characteristics. The micromirrors are electrically tied to the micromirror reset signals (MBRST) and

the micromirror array is divided into reset groups.

Electrostatic potentials between a micromirror and its memory data electrodes cause the micromirror to tilt

toward the illumination source in a DLP projection system or away from it, thus reflecting its incident light into or

out of an optical collection aperture. The positive (+) tilt angle state corresponds to an 'on' pixel, and the negative

(–) tilt angle state corresponds to an 'off' pixel.

Refer to Micromirror Array Optical Characteristics for the ± tilt angle specifications. Refer to Pin Configuration

and Functions for more information on micromirror reset control.

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8.2 Functional Block Diagram

Not to Scale. Details Omitted for Clarity. See Accompanying Notes in this Section.

Channel A

Interface

Channel C

Interface

Control

Column Read & Write

Control

(0,0)

Word Lines

Voltages

Row

Micromirror Array

Voltage

Generators

Voltage

Generators

Voltages

(M-1, N-1)

Control

Column Read & Write

Control

Channel B

Interface

Channel D

Interface

For pin details on Channels A, B, C, and D, refer to Pin Configuration and Functions and LVDS Interface section of

Timing Requirements.

Figure 12. Functional Block Diagram

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8.3 Feature Description

The DMD consists of 4096000 highly reflective, digitally switchable, micrometer-sized mirrors (micromirrors)

organized in a two-dimensional orthogonal pixel array. Refer to Figure 9 and Figure 13.

Each aluminum micromirror is switchable between two discrete angular positions, –α and +α. The angular

positions are measured relative to the micromirror array plane, which is parallel to the silicon substrate. Refer to

Micromirror Array Optical Characteristics and Figure 14.

The parked position of the DMD micromirrors is not an operational mode which is electrostatically driven.

Therefore, the DMD micromirrors are not driven to a known landed position and the individual micromirror flat-

state angular positions may vary from the DMD array plane. Tilt direction of the micromirror is perpendicular to

the hinge-axis. The on-state landed position is directed toward the left-top edge of the package, as shown in

Figure 13.

Each individual micromirror is positioned over a corresponding CMOS memory cell. The angular position of a

specific micromirror is determined by the binary state (logic 0 or 1) of the corresponding CMOS memory cell

contents, after the mirror clocking pulse is applied. The angular position (–α and +α) of the individual micromirrors

changes synchronously with a micromirror clocking pulse, rather than being coincident with the CMOS memory

cell data update.

Writing logic 1 into a memory cell followed by a mirror clocking pulse results in the corresponding micromirror

switching to a +α position. Writing logic 0 into a memory cell followed by a mirror clocking pulse results in the

corresponding micromirror switching to a – α position.

Updating the angular position of the micromirror array consists of two steps. First, update the contents of the

CMOS memory. Second, apply a micromirror reset (also referred as Mirror Clocking Pulse) to all or a portion of

the micromirror array (depending upon the configuration of the system). Micromirror reset pulses are generated

internally by the DMD, with application of the pulses being coordinated by the DLPC910 digital controller.

For more information, refer to the TI application report DLPA008, DMD101: Introduction to Digital Micromirror

Device (DMD) Technology.

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Feature Description (continued)

Incident

Illumination

Package Pin

A1 Corner

Details Omitted For Clarity.

Not To Scale.

DMD

Micromirror

Array

Active Micromirror Array

(Border micromirrors eliminated for clarity)

0

Nœ1

Micromirror Pitch

Micromirror Hinge-Axis Orientation

P (um)

—On-State“

Tilt Direction

45°

—Off-State“

Tilt Direction

P (um)

Refer to Micromirror Array Physical Characteristics, Figure 9, and Figure 10.

Figure 13. Micromirror Array, Pitch, Hinge Axis Orientation

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Feature Description (continued)

Details Omitted For Clarity.

Not To Scale.

Package Pin

A1 Corner

DMD

Incident

Illumination

Two

—On-State“ —Off-State“

Micromirrors Micromirrors

For Reference

Flat-State

( —parked“ )

Micromirror Position

a

b

-a

b

Silicon Substrate

—On-State“

Micromirror

—Off-State“

Micromirror

Micromirror States: On, Off, Flat

Figure 14. Micromirror States: On, Off, Flat

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8.4 Device Functional Modes

The DLP9000XUV DMD is controlled by one DLPC910 digital controller. The digital controller offers high speed

streaming mode where 1-bit binary patterns are accepted at the LVDS interface input, and then streamed to the

DMD. To ensure reliable operation, the DLP9000XUV DMD must always be used with the DLPC910 controller.

For more information, refer to the DLPC910 data sheet listed under Related Documentation.

8.5 Window Characteristics and Optics

NOTE

TI assumes no responsibility for image quality artifacts or DMD failures caused by optical

system operating conditions exceeding limits described previously.

8.5.1 Optical Interface and System Image Quality

TI assumes no responsibility for end-equipment optical performance. Achieving the desired end-equipment

optical performance involves making trade-offs between numerous component and system design parameters.

Optimizing system optical performance and image quality strongly relate to optical system design parameter

trades. Although it is not possible to anticipate every conceivable application, projector image quality and optical

performance is contingent on compliance to the optical system operating conditions described in the following

sections.

8.5.2 Numerical Aperture and Stray Light Control

The angle defined by the numerical aperture of the illumination and projection optics at the DMD optical area

should be the same. This angle should not exceed the nominal device mirror tilt angle unless appropriate

apertures are added in the illumination and/or projection pupils to block out flat-state and stray light from the

projection lens. The mirror tilt angle defines DMD capability to separate the "ON" optical path from any other light

path, including undesirable flat-state specular reflections from the DMD window, DMD border structures, or other

system surfaces near the DMD such as prism or lens surfaces. If the numerical aperture exceeds the mirror tilt

angle, or if the projection numerical aperture angle is more than two degrees larger than the illumination

numerical aperture angle, objectionable artifacts in the display’s border and/or active area could occur.

8.5.3 Pupil Match

TI’s optical specifications assume that the exit pupil of the illumination optics is nominally centered within 2° (two

degrees) of the entrance pupil of the projection optics. Misalignment of pupils can create objectionable artifacts in

the display’s border and/or active area, which may require additional system apertures to control, especially if the

numerical aperture of the system exceeds the pixel tilt angle.

8.5.4 Illumination Overfill

The active area of the device is surrounded by an aperture on the inside DMD window surface that masks

structures of the DMD device assembly from normal view. The aperture is sized to anticipate several optical

operating conditions. Overfill light illuminating the window aperture can create artifacts from the edge of the

window aperture opening and other surface anomalies that may be visible on the screen. The illumination optical

system should be designed to limit light flux incident anywhere on the window aperture from exceeding

approximately 10% of the average flux level in the active area. Depending on the particular system’s optical

architecture, overfill light may have to be further reduced below the suggested 10% level in order to be

acceptable.

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8.6 Micromirror Array Temperature Calculation

Figure 15. DMD Thermal Test Points

Micromirror array temperature can be computed analytically from measurement points on the outside of the

package, the package thermal resistance, the electrical power, and the illumination heat load. The relationship

between micromirror array temperature and the reference ceramic temperature is provided by the following

equations:

T_ARRAY= T _CERAMIC+ (Q_ARRAY× R_{ARRAY-TO-CERAMIC}

Q_ARRAY= Q_ELECTRICAL+ Q_ILLUMINATION

)

where:

•

T_ARRAY= Computed array temperature (°C)

T_CERAMIC= Measured ceramic temperature (°C) (TP1 location)

R_{ARRAY-TO-CERAMIC}= Thermal resistance of DMD package from array to ceramic TP1 (°C/W)

Q_ARRAY= Total DMD power (electrical and absorbed) on the array (Watts)

Q_ELECTRICAL= Nominal electrical power (Watts)

Q_INCIDENT= Incident Illumination optical power (W)

Q_ILLUMINATION= (DMD average thermal absorptivity x Q_INCIDENT) (W)

DMD average thermal absorptivity = 0.39

The electrical power dissipation of the DMD is variable and depends on the voltages, data rates, and pattern

rates of the DMD within the intended application. For the example array temperature calculation shown below,

the maximum value of 11.2 W is used for the electrical power dissipation. Since the electrical power dissipation

of the DMD is application dependent, customers will want to test and use their own application dependent power

values in their array temperature calculation. The absorbed power from the illumination source is variable and

depends on the operating state of the micromirrors and the intensity of the light source. The equations shown

above are valid for each DMD chip in a system. The absorption factor of 0.39 assumes the array is fully

illuminated with an illumination distribution of 90% on the active array and 10% overfill on the array border. It is

strongly recommended to minimize illumination overfill as much as possible which will, in turn, maximize the

active array illumination, increase overall system efficiency, and reduce DMD thermal heating.

The following is a sample Calculation for each DMD in a system with a measured illumination power density:

•

T_Ceramic= 15°C (measured)

ILL_DENSITY= 15 Watts per cm²(optical power on DMD per unit area) (measured)

Overfill = 10% (optical design)

Q_ELECTRICAL= 11.2 Watts

R_{ARRAY-TO-CERAMIC}= 0.5 °C/W

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Micromirror Array Temperature Calculation (continued)

•

Area of array = ( 1.9354 cm x 1.2096 cm ) = 2.34 cm²

ILL_AREA= 2.34 cm²/ (90%) = 2.6 cm²

Q_INCIDENT=15 W/cm²x 2.6 cm²= 39.0 W

Q_ARRAY= 11.2 W + (0.39 x 39.0 W) = 26.4 W

T_ARRAY=15°C + (26.4 W x 0.5 °C) = 28.2 °C

8.7 Micromirror Landed-On/Landed-Off Duty Cycle

8.7.1 Definition of Micromirror Landed-On/Landed-Off Duty Cycle

The micromirror landed-on/landed-off duty cycle (landed duty cycle) denotes the amount of time (as a

percentage) that an individual micromirror is landed in the On–state versus the amount of time the same

micromirror is landed in the Off–state.

As an example, a landed duty cycle of 100/0 indicates that the referenced pixel is in the On-state 100% of the

time (and in the Off-state 0% of the time); whereas 0/100 would indicate that the pixel is in the Off-state 100% of

the time. Likewise, 50/50 indicates that the pixel is On 50% of the time and Off 50% of the time.

Note that when assessing landed duty cycle, the time spent switching from one state (ON or OFF) to the other

state (OFF or ON) is considered negligible and is thus ignored.

Since a micromirror can only be landed in one state or the other (On or Off), the two numbers (percentages)

always add to 100.

8.7.2 Landed Duty Cycle and Useful Life of the DMD

Knowing the long-term average landed duty cycle (of the end product or application) is important because

subjecting all (or a portion) of the DMD’s micromirror array (also called the active array) to an asymmetric landed

duty cycle for a prolonged period of time can reduce the DMD’s usable life.

Note that it is the symmetry/asymmetry of the landed duty cycle that is of relevance. The symmetry of the landed

duty cycle is determined by how close the two numbers (percentages) are to being equal. For example, a landed

duty cycle of 50/50 is perfectly symmetrical whereas a landed duty cycle of 100/0 or 0/100 is perfectly

asymmetrical.

Individual DMD mirror duty cycles vary by application as well as the mirror location on the DMD within any

specific application. DMD mirror useful life are maximized when every individual mirror within a DMD approaches

50/50 (or 1/1) duty cycle. For the DLPC910 and DLP9000XUV chipset, it is recommended the controlling

applications processor provide a 50/50 pattern sequence to the DLPC910 for display on the DLP9000XUV DMD

as often as possible. The pattern provides a 50/50 duty cycle across the entire DMD mirror array, where the

mirrors are continuously flipped between the on and off states.

8.7.3 Landed Duty Cycle and Operational DMD Temperature

Operational DMD Temperature and Landed Duty Cycle interact to affect the DMD’s usable life.

8.7.4 Estimating the Long-Term Average Landed Duty Cycle of a Product or Application

During a given period of time, the Landed Duty Cycle of a given pixel follows from the image content being

displayed by that pixel.

For example, in the simplest case, when displaying pure-white on a given pixel for a given time period, that pixel

will experience a 100/0 Landed Duty Cycle during that time period. Likewise, when displaying pure-black, the

pixel will experience a 0/100 Landed Duty Cycle.

Between the two extremes (ignoring for the moment color and any image processing that may be applied to an

incoming image), the Landed Duty Cycle tracks one-to-one with the gray scale value, as shown in Table 2.

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Micromirror Landed-On/Landed-Off Duty Cycle (continued)

Table 2. Grayscale Value and Landed Duty Cycle

GRAYSCALE VALUE

LANDED DUTY CYCLE

0%

10%

20%

30%

40%

50%

60%

70%

80%

90%

100%

0/100

10/90

20/80

30/70

40/60

50/50

60/40

70/30

80/20

90/10

100/0

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9 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.

9.1 Application Information

The DLP9000XUV DMD is controlled by the DLPC910 controller, where the DLPC910 is configured by the

program content in the DLPR910. This chipset offers streaming 1-bit binary patterns to the DMD at speeds

greater than 61 Gigabits per second (Gbps). The patterns are streamed from a customer designed processor into

the LVDS input data interface of the DLPC910 Controller.

The DLP9000XUV chipset provides solutions for many varied applications including structured light,

3D printing, video projection, and high speed lithography. The DMD is a spatial light modulator, which reflects

incoming light from an illumination source to one of two directions, with the primary direction being into a

projection or collection optic. Each application is derived primarily from the optical architecture of the system and

the format of the data being used.

9.1.1 DMD Reflectivity Characteristics

Under long term UVA illumination, many elements of optical systems can experience degradation, including

illuminators, lenses, etc. TI assumes no responsibility for DMD reflectivity performance which affects end-

equipment performance over time. Achieving the desired end-equipment reflectivity performance involves making

trade-offs between numerous component and system design parameters and validating the performance for the

end equipment prior to production. DMD reflectivity includes both micromirror surface reflectivity and DMD

window transmission. DMD reflectivity was characterized over time using 365 nm, 385 nm, and 405 nm high

power LEDs directly illuminating the DMD at various DMD array temperatures. Nominal DMD Reflectivity

characteristics over Total UV Exposure Times at maximum power densities for given wavelengths are

represented in the following figures. (Contact your local Texas Instruments representative for additional

information about power density measurements.)

Figure 16. Relative Reflectivity @ 355nm

Figure 17. Relative Reflectivity @ 365nm

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Application Information (continued)

Figure 18. Relative Reflectivity @ 385nm

Figure 19. Relative Reflectivity @ 405nm

9.1.1.1 Design Considerations Influencing DMD Reflectivity

Optimal, long-term performance of the digital micromirror device (DMD) can be affected by various customer

selected application and design parameters. The following list identifies some of these parameters and includes

high level design recommendations that may help extend relative DMD reflectivity from time zero:

•

Illumination spectrum – use longer wavelengths for the application whenever possible while filtering or

preventing shorter wavelengths from striking the DMD

•

Illumination power density – use the lowest illumination power density possible for the application

DMD temperature – always operate the DMD within its array temperature specification and toward the lower

end when at all possible

•

Cumulative incident illumination – minimize the total hours of UV illumination exposure. In the application,

when the DMD is not actively required to steer UV light, disable the solid-state illumination or shutter the

illumination.

Micromirror landed duty cycles – during periods of system inactivity, turn off the illuminators and rapidly apply

repeating 50/50 duty cycle patterns to the DMD.

9.2 Typical Applications

High-end lithography is benefitting from the conversion from mask-based imaging to digital mask-less imaging.

Instead of stopping the lithography process to change out expensive masks, mask-less lithography offers a

continuous run of printing by changing the imaged patterns digitally without stopping the imaging process. The

programmable nature of the DMD supports real-time correction of optical and imaged surface distortions.

Figure 20 shows a system where a DLPC910 digital controller is coupled with the DLP9000XUV DMD. These

components enable a high speed digital imaging system that takes in digital images at 2560 × 1600 in resolution

at speeds of more than 61 Gbps and projects them at pattern rates nearing 15 kHz. For more information, refer

to the DLPC910 digital controller data sheet listed under Related Documentation.

9.2.1 Design Requirements

Detailed design requirements are located in the DLPC910 digital controller data sheets. Refer to the data sheets

listed under Related Documentation.

9.2.2 Detailed Design Procedure

TIDA-00570 is a TI reference design which provides detailed information to assist customers in implementing a

DLPC910 based system using the DLP9000X DMD. The reference design is also applicable to using the

DLPC910 with the DLP9000XUV DMD instead of the DLP9000X DMD. This reference material includes

reference board schematics, PCB layouts, and Bills of Materials. Layout guidelines for boards utilizing these

controllers and DMDs can also be found in the DLPC910 Controller and DLP9000X(UV) data sheets. For more

information, please refer to the individual data sheets listed under Related Documentation.

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Typical Applications (continued)

Illumination

Driver

Illumination

Sensor

LVDS Interface

DCLKIN (A,B,C,D), DVALID (A,B,C,D), DIN(A,B,C,D)

Row and Block Signals

ROWMD (1:0), ROWAD (10:0), BLKMD (1:0), BLKAD (3:0), RST2BLKZ

USER

Interface

DOUT(A,B,C,D)[15:0]

DCLKOUT (A,B,C,D)

APPS

FPGA

Control Signals

COMP_DATA.NS_FLIP,WDT_ENBLZ,PWR_FLOAT

SCTRL (A,B,C,D)

Status Signals

RST_ACTIVE, INIT_ACTIVE, ECP2_FINISHED

Connectivity

USB

Ethernet

RESET_ADDR (3:0)

RESET_MODE (1:0)

RESET_SEL (1:0)

JTAG(3:0)

DLP9000XUV

DLPC910

RESET_STRB

RESET_OEZ

Volatile

And

PGM(4:0)

DLPR910

Non-Volatile

Storage

RESET_IRQZ

CTRL_RSTZ

I2C

SCP BUS (3:0)

RESETZ

VLED0

VLED1

OSC

50 MHz

Power Management

Power In

Figure 20. DLP9000XUV DMD - Typical Application Schematic

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10 Power Supply Requirements

10.1 DMD Power Supply Requirements

The following power supplies are all required to operate the DMD: V_CC, V_CCI, V_OFFSET, V_BIAS, and V_RESET. V_SS

must also be connected. DMD power-up and power-down sequencing is strictly controlled by the DLPC910

Controllers within their associated reference designs.

CAUTION

For reliable operation of the DMD, the following power supply sequencing

requirements must be followed. Failure to adhere to the prescribed power-up and

power-down procedures may affect device reliability. V_CC, V_CCI, V_OFFSET, V_BIAS, and

V_RESETpower supplies have to be coordinated during power-up and power-down

operations. V_SSmust also be connected. Failure to meet any of the below

requirements will result in a significant reduction in the DMD’s reliability and lifetime.

Refer to Figure 21.

10.2 DMD Power Supply Power-Up Procedure

•

During power-up, V_CCand V_CCImust always start and settle before V_OFFSET, V_BIAS, and V_RESETvoltages are

applied to the DMD.

•

During power-up, it is a strict requirement that the delta between V_BIASand V_OFFSETmust be within the

specified limit shown in Recommended Operating Conditions. During power-up, V_BIASdoes not have to start

after V_OFFSET

.

•

During power-up, there is no requirement for the relative timing of V_RESETwith respect to V_OFFSETand V_BIAS

.

Power supply slew rates requirements during power-up are flexible, provided that the transient voltage levels

follow the requirements listed in Absolute Maximum Ratings, in Recommended Operating Conditions, and in

Figure 21.

•

During power-up, LVCMOS input pins shall not be driven high until after V_CCand V_CCIhave settled at

operating voltages listed in Recommended Operating Conditions.

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10.3 DMD Mirror Park Sequence (Power_Float) Requirements

For correct power down operation of the DLP9000XUV DMD, the following power down procedure must be

executed.

Prior to an anticipated power removal, assert the PWR_FLOAT signal to the DLPC910 for a minimum of 500 μs

to allow the DLPC910 to complete the power down procedure. This procedure will assure the DMD mirrors are in

the unbiased parked state. Following this procedure, the power can be safely removed.

In the event of an unanticipated power loss, the power management system must detect the input power loss,

immediately assert PWR_FLOAT to the DLPC910, and maintain all operating power levels of the DLPC910 and

the DLP9000XUV DMD for a minimum of 500 μs to allow the DLPC910 to complete the power down procedure.

Refer to the DLPC910 datasheet for more details on power down requirements.

To restart the DLPC910 and DLP9000XUV after assertion of PWR_FLOAT, the DLPC910 must be reset by

setting CTRL_RSTZ low (logic 0) for 50 ms and then back to high (logic 1), or the power to the DLPC910 must

be cycled.

10.4 DMD Power Supply Power-Down Procedure

•

During power-down, V_CCand V_CCImust be supplied until after V_BIAS, V_RESET, and V_OFFSETare discharged to

within the specified limit of ground. Refer to Table 3.

•

During power-down, it is a strict requirement that the delta between V_BIASand V_OFFSETmust be within the

specified limit shown in Recommended Operating Conditions. During power-down, it is not mandatory to stop

driving V_BIASprior to V_OFFSET

During power-down, there is no requirement for the relative timing of V_RESETwith respect to V_OFFSETand

V_BIAS

Power supply slew rates during power-down are flexible, provided that the transient voltage levels follow the

requirements listed in Absolute Maximum Ratings, in Recommended Operating Conditions, and in Figure 21.

.

•

.

During power-down, LVCMOS input pins must be less than specified in Recommended Operating Conditions.

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DMD Power Supply Power-Down Procedure (continued)

EN_BIAS, EN_OFFSET, and EN_RESET are disabled by DLP controller software or PWRDNZ signal control

VBIAS, VOFFSET, and VRESET are disabled by DLP controller software

Note 3

Power Off

VCC / VCCI

Mirror Park Sequence

RESET_OEZ

Note 6

VSS

¸ ¸

VCC / VCCI

PWRDNZ

¸ ¸

VSS

VCC / VCCI

VCC

VCCI

VSS

¸ ¸

VSS

EN_BIAS

VCC / VCCI

EN_OFFSET

¸ ¸

Note 3

EN_RESET

VSS

VBIAS

¸ ¸

VBIAS

VBIAS < Specification

Note 1

∆V < Specification

Note 4

∆V < Specification

VSS

VOFFSET

¸ ¸

VOFFSET < Specification

VOFFSET

Note 4

VSS

Note 5

Refer to specifications listed in Recommended Operating Conditions.

Waveforms are not to scale. Details are omitted for clarity.

VRESET < Specification

Note 4

VSS

VRESET

VRESET > Specification

VRESET

VCC

VRESET

¸ ¸

LVCMOS

Inputs

VSS

Note 2

LVDS

Inputs

¸ ¸

Figure 21. DMD Power Supply Sequencing Requirements

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DMD Power Supply Power-Down Procedure (continued)

1. To prevent excess current, the supply voltage delta |V_BIAS– V_OFFSET| must be less than specified in

Recommended Operating Conditions. OEMs may find that the most reliable way to ensure this is to power

V_OFFSETprior to V_BIASduring power-up and to remove V_BIASprior to V_OFFSETduring power-down.

2. During power-up, the LVDS signals are less than the input differential voltage (V_ID) maximum specified in

Recommended Operating Conditions. During power-down, LVDS signals are less than the high level input

voltage (V_IH) maximum specified in Recommended Operating Conditions.

3. When system power is interrupted, the DLPC910 controllers initiate a hardware power-down that activates

PWRDNZ and disables V_BIAS, V_RESETand V_OFFSETafter the micromirror park sequence. Software power-

down disables V_BIAS, V_RESET, and V_OFFSETafter the micromirror park sequence through software control. For

either case, enable signals EN_BIAS, EN_OFFSET, and EN_RESET are used to disable V_BIAS, V_OFFSET, and

V_RESET, respectively.

4. Refer to Table 3.

5. Figure not to scale. Details have been omitted for clarity. Refer to Recommended Operating Conditions.

6. Refer to DMD Mirror Park Sequence (Power_Float) Requirements for details on powering down the DMD.

Table 3. DMD Power-Down Sequence Requirements

PARAMETER

MIN

MAX

4.0

UNIT

V_BIAS

V

V_OFFSET

V_RESET

Supply voltage level during power–down sequence

4.0

–4.0

0.5

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11 Layout

11.1 Layout Guidelines

Each chipset provides a solution for many applications including digital lithography and 3D printing. This section

provides layout guidelines for the DMD.

11.1.1 General PCB Recommendations

The PCB shall be designed to IPC2221 and IPC2222, Class 2, Type Z, at level B producibility and built to

IPC6011 and IPC6012, class 2. The PCB board thickness to be 0.062 inches ±10%, using a dielectric material

with a low loss-tangent, for example: Hitachi 679gs or equivalent.

Two-ounce copper planes are recommended in the PCB design in order to achieve needed thermal connectivity.

Refer to the digital controller data sheets listed under Related Documentation regarding DMD Interface

Considerations.

High-speed interface waveform quality and timing on the digital controllers (that is, the LVDS DMD interface) is

dependent on the following factors:

•

Total length of the interconnect system

Spacing between traces

Characteristic impedance

Etch losses

How well matched the lengths are across the interface

Thus, ensuring positive timing margin requires attention to many factors.

As an example, DMD interface system timing margin can be calculated as follows:

•

Setup Margin = (controller output setup) – (DMD input setup) – (PCB routing mismatch) – (PCB SI

degradation)

•

Hold-time Margin = (controller output hold) – (DMD input hold) – (PCB routing mismatch) – (PCB SI

degradation)

The PCB SI degradation is the signal integrity degradation due to PCB effects which includes simultaneously

switching output (SSO) noise, crosstalk, and inter-symbol-interference (ISI) noise.

DLPC910 I/O timing parameters can be found in their respective data sheets. Similarly, PCB routing mismatch

can be easily budgeted and met via controlled PCB routing. However, PCB SI degradation is not as easy to

determine.

In an attempt to minimize the signal integrity analysis that would otherwise be required, the following PCB design

guidelines provide a reference of an interconnect system that satisfies both waveform quality and timing

requirements (accounting for both PCB routing mismatch and PCB SI degradation). Deviation from these

recommendations should be confirmed with PCB signal integrity analysis or lab measurements.

11.1.2 Power Planes

Signal routing is NOT allowed on the power and ground planes. All device pin and via connections to this plane

shall use a thermal relief with a minimum of four spokes. The power plane shall clear the edge of the PCB by

0.2".

Prior to routing, vias connecting all digital ground layers (GND) should be placed around the edge of the rigid

PWB regions 0.025” from the board edges with a 0.100” spacing. It is also desirable to have all internal digital

ground (GND) planes connected together in as many places as possible. If possible, all internal ground planes

should be connected together with a minimum distance between connections of 0.5". Extra vias are not required

if there are sufficient ground vias due to normal ground connections of devices. NOTE: All signal routing and

signal vias should be inside the perimeter ring of ground vias.

Power and Ground pins of each component shall be connected to the power and ground planes with one via for

each pin. Trace lengths for component power and ground pins should be minimized (ideally, less than 0.100”).

Unused or spare device pins that are connected to power or ground may be connected together with a single via

to power or ground. Ground plane slots are NOT allowed.

Route V_OFFSET, V_BIAS, and V_RESETas a wide trace >20 mils (wider if space allows) with 20 mils spacing.

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Layout Guidelines (continued)

11.1.3 LVDS Signals

The LVDS signals shall be first. Each pair of differential signals must be routed together at a constant separation

such that constant differential impedance (as in section Board Stack and Impedance Requirements) is

maintained throughout the length. Avoid sharp turns and layer switching while keeping lengths to a minimum.

The distance from one pair of differential signals to another shall be at least 2 times the distance within the pair.

11.1.4 Critical Signals

The critical signals on the board must be hand routed in the order specified below. In case of length matching

requirements, the longer signals should be routed in a serpentine fashion, keeping the number of turns to a

minimum and the turn angles no sharper than 45 degrees. Avoid routing long trace all around the PCB.

Table 4. Timing Critical Signals

GROUP

SIGNAL

CONSTRAINTS

ROUTING LAYERS

D_AP(0:15), D_AN(0:15), DCLK_AP,

DCLK_AN, SCTRL_AN, SCTRL_AP,

D_BP(0:15), D_BN(0:15), DCLK_BP,

DCLK_BN, SCTRL_BN, SCTRL_BP,

D_CP(0:15), D_CN(0:15), DCLK_CP,

DCLK_CN, SCTRL_CN, SCTRL_CP,

D_DP(0:15), D_DN(0:15), DCLK_DP,

DCLK_DN, SCTRL_DN, SCTRL_DP.

Internal signal layers. Avoid layer switching

when routing these signals.

1

Refer to Table 5 and Table 6

RESET_ADDR_(0:3),

RESET_MODE_(0:1),

RESET_OEZ,

Internal signal layers. Top and bottom as

required.

2

RESET_SEL_(0:1)

RESET_STROBE,

RESET_IRQZ.

SCP_CLK, SCP_DO,

SCP_DI, SCP_DMD_CSZ.

3

4

Any

Others

No matching/length requirement

11.1.5 Flex Connector Plating

Plate all the of pad area on the top layer of the flex connection with a minimum of 35 and of maximum 50 micro-

inches of electrolytic hard gold over a minimum of 150 micro-inches of electrolytic nickel.

11.1.6 Device Placement

Unless otherwise specified, all major components should be placed on the top layer. Small components such as

ceramic, non-polarized capacitors, resistors, and resistor networks can be placed on the bottom layer. All high

frequency de-coupling capacitors for the ICs shall be placed near the parts. Distribute the capacitors evenly

around the IC and place them as close to the device’s power pins as possible (preferably with no vias). In the

case where an IC has multiple de-coupling capacitors with different values, alternate the values of those that are

side by side as much as possible and place the smaller value capacitor closer to the device.

11.1.7 Device Orientation

It is desirable to have all polarized capacitors oriented with their positive terminals in the same direction. If

polarized capacitors are oriented both horizontally and vertically, then all horizontal capacitors should be oriented

with the “+” terminal facing the same direction and likewise for the vertically oriented ones.

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11.2 Layout Example

11.2.1 Board Stack and Impedance Requirements

Refer to Figure 22 regarding guidance on the parameters.

PCB design:

Configuration:

Asymmetric dual stripline

Etch thickness (T):

1.0-oz copper (1.2 mil)

0.5-oz copper (0.6 mil)

50 Ω (±10%)

Flex etch thickness (T):

Single-ended signal impedance:

Differential signal impedance:

100 Ω (±10%)

PCB stack-up:

Reference plane 1 is assumed to be a ground plane for the proper return path.

Reference plane 2 is assumed to be the I/O power plane or ground.

Dielectric material with a low loss-tangent, for

example: Hitachi 679gs or equivalent.

(Er): 3.8 (nominal)

Signal trace distance to reference plane 1 (H1): 5.0 mil (nominal)

Signal trace distance to reference plane 2 (H2): 34.2 mil (nominal)

Figure 22. PCB Stack Geometries

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Layout Example (continued)

Table 5. General PCB Routing (Applies to All Corresponding PCB Signals)

PARAMETER

APPLICATION

SINGLE-ENDED SIGNALS

DIFFERENTIAL PAIRS

UNIT

4 .4

(0.1)

4 .3

(0.1)

mil

(mm)

Escape routing in ball field

7

4.25

(0.11)

mil

(mm)

Line width (W)

PCB etch data or control

PCB etch clocks

(0.18)

7

4.25

(0.11)

mil

(mm)

(0.18)

5.75⁽¹⁾

–0.15

5.75⁽¹⁾

–0.15

mil

(mm)

PCB etch data or control

PCB etch clocks

N/A

Differential signal pair spacing (S)

mil

(mm)

20

(0.51)

mil

(mm)

PCB etch data or control

PCB etch clocks

Minimum differential pair-to-pair

spacing (S)

20

(0.51)

mil

(mm)

4

(0.1)

4

(0.1)

mil

(mm)

Escape routing in ball field

PCB etch data or control

PCB etch clocks

10

(0.25)

20

(0.51)

mil

(mm)

Minimum line spacing to other

signals (S)

20

(0.51)

20

(0.51)

mil

(mm)

10

–0.25

mil

(mm)

Maximum differential pair P-to-N

length mismatch

Total data

N/A

10

–0.25

mil

(mm)

Total data

(1) Spacing may vary to maintain differential impedance requirements.

Table 6. DMD Interface Specific Routing

SIGNAL GROUP LENGTH MATCHING

INTERFACE

SIGNAL GROUP

REFERENCE SIGNAL

MAX MISMATCH

UNIT

± 50

(± 1.3)

mil

(mm)

SCTRL_AN / SCTRL_AP

D_AP(15:0)/ D_AN(15:0)

DMD (LVDS)

DCLK_AP/ DCLK_AN

± 50

(± 1.3)

mil

(mm)

SCTRL_BN/ SCTRL_BP

D_BP(15:0)/ D_BN(15:0)

DMD (LVDS)

DCLK_BP/ DCLK_BN

DCLK_CP/ DCLK_CN

DCLK_DP/ DCLK_DN

± 50

(± 1.3)

mil

(mm)

SCTRL_CN/ SCTRL_CP

D_CP(15:0)/ D_CN(15:0)

± 50

(± 1.3)

mil

(mm)

SCTRL_DN/ SCTRL_DP

D_DP(15:0)/ D_DN(15:0)

Number of layer changes:

•

Single-ended signals: Minimize.

Differential signals: Individual differential pairs can be routed on different layers but the signals of a given pair

should not change layers.

(1)

Table 7. DMD Signal Routing Length

BUS

MIN

MAX

UNIT

DMD (LVDS)

50

375

mm

(1) Max signal routing length includes escape routing.

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Stubs: Stubs should be avoided.

Termination Requirements (DMD interface): None – The DMD receiver is differentially terminated to 100 Ω

internally.

Connector (DMD-LVDS interface bus only):

High-speed connectors that meet the following requirements should be used:

•

Differential crosstalk: <5%

Differential impedance: 75 to 125 Ω

Routing requirements for right-angle connectors: When using right-angle connectors, P-N pairs should be routed

in the same row to minimize delay mismatch. When using right-angle connectors, propagation delay difference

for each row should be accounted for on associated PCB etch lengths. Voltage or low frequency signals should

be routed on the outer layers. Signal trace corners shall be no sharper than 45 degrees. Adjacent signal layers

shall have the predominant traces routed orthogonal to each other.

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12 Device and Documentation Support

12.1 Device Support

12.1.1 Device Nomenclature

Figure 23 provides a legend for reading the complete device name for any DLP device.

xDLP9000XUV_FLS

Package Type

Revision

Wavelength

Device Descriptor

Device Status

x œ prototype device

blank œ production device

Figure 23. Device Nomenclature

12.1.2 Device Markings

The device marking will include both human-readable information and a 2-dimensional matrix code. The human-

readable information is described in Figure 24. The 2-dimensional matrix code is an alpha-numeric character

string that contains the DMD part number, Part 1 of Serial Number, and Part 2 of Serial Number. The first

character of the DMD Serial Number (part 1) is the manufacturing year. The second character of the DMD Serial

Number (part 1) is the manufacturing month.

TI Internal Numbering

2 Dimensional Matrix Code

(DMD Part Number and

DMD Part Number

Serial Number)

YYYYYYY

DLP9000XUVFLS

GHXXXXX LLLLLLM

LLLLLL

Part 2 of Serial Number

(7 characters)

Part 1 of Serial Number

(7 characters)

TI Internal Numbering

Figure 24. DMD Markings

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12.2 Documentation Support

12.2.1 Related Documentation

The following documents contain additional information related to the use of the DLP9000XUV:

•

DLPC910 Digital Controller Data Sheet (DLPS064)

DLPR910 Configuration PROM Data Sheet (DLPS065)

DLP9000 DLP9500 Type A Mounting Concept (DLPR014)

12.3 Support Resources

TI E2E™ support forums are an engineer's go-to source for fast, verified answers and design help — straight

from the experts. Search existing answers or ask your own question to get the quick design help you need.

Linked content is provided "AS IS" by the respective contributors. They do not constitute TI specifications and do

not necessarily reflect TI's views; see TI's Terms of Use.

12.4 Trademarks

E2E is a trademark of Texas Instruments.

DLP is a registered trademark of Texas Instruments.

12.5 Electrostatic Discharge Caution

These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam

during storage or handling to prevent electrostatic damage to the MOS gates.

12.6 Glossary

SLYZ022 — TI Glossary.

This glossary lists and explains terms, acronyms, and definitions.

13 Mechanical, Packaging, and Orderable Information

The following pages include mechanical, packaging, and orderable information. This information is the most

current data available for the designated devices. This data is subject to change without notice and revision of

this document. For browser-based versions of this data sheet, refer to the left-hand navigation.

13.1 Thermal Characteristics

Achieving optimal DMD performance requires proper management of the maximum DMD case temperature, the

maximum temperature of any individual micromirror in the active array and the temperature gradient between

any two points on or within the package.

Refer to Absolute Maximum Ratings and Recommended Operating Conditions regarding applicable temperature

limits.

13.2 Package Thermal Resistance

The DMD is designed to conduct the absorbed and dissipated heat back to the series FLS package where it can

be removed by an appropriate thermal management system. The thermal management system must be capable

of maintaining the package within the specified operational temperatures at the thermal test point locations (refer

to Figure 15 or Micromirror Array Temperature Calculation). The total heat load on the DMD is typically driven by

the incident light absorbed by the active area; although other contributions can include light energy absorbed by

the window aperture, electrical power dissipation of the array, and parasitic heating. For the thermal resistance,

refer to Thermal Information.

13.3 Case Temperature

The temperature of the DMD case can be measured directly. For consistency, a thermal test point location is

defined as shown in Figure 15 and Micromirror Array Temperature Calculation.

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IMPLIED WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE OR NON-INFRINGEMENT OF THIRD

PARTY INTELLECTUAL PROPERTY RIGHTS.

These resources are intended for skilled developers designing with TI products. You are solely responsible for (1) selecting the appropriate

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These resources are subject to change without notice. TI grants you permission to use these resources only for development of an

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TI objects to and rejects any additional or different terms you may have proposed. IMPORTANT NOTICE

Mailing Address: Texas Instruments, Post Office Box 655303, Dallas, Texas 75265


型号：	DLP9000XUVFLS
厂家：	TEXAS INSTRUMENTS
描述：	DLP® 0.90 高速 WQXGA UV A 型 DMD \| FLS \| 355 \| 20 to 30 商用集成电路
文件：	总54页 (文件大小：2533K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

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