TI1 DLP9500 Lvds type a dmd Datasheet

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DLP9500
DLPS025C – AUGUST 2012 – REVISED SEPTEMBER 2015
DLP9500 DLP® 0.95 1080p 2x LVDS Type A DMD
1 Features
3 Description
•
The DLP9500 1080p chipset is part of the DLP®
Discovery™ 4100 platform, which enables high
resolution and high performance spatial light
modulation. The DLP9500 is the digital micromirror
device (DMD) fundamental to the 0.95 1080p chipset.
The DLP Discovery 4100 platform also provides the
highest level of individual micromirror control with the
option for random row addressing. Combined with a
hermetic package, the unique capability and value
offered by DLP9500 makes it well suited to support a
wide variety of industrial, medical, and advanced
display applications.
1
•
•
•
•
•
0.95-Inch Diagonal Micromirror Array
– 1920 × 1080 Array of Aluminum, MicrometerSized Mirrors (1080p Resolution)
– 10.8-µm Micromirror Pitch
– ±12° Micromirror Tilt Angle (Relative to Flat
State)
– Designed for Corner Illumination
Designed for Use With Visible Light
(400 to 700 nm):
– Window Transmission 97% (Single Pass,
Through Two Window Surfaces)
– Micromirror Reflectivity 88%
– Array Diffraction Efficiency 86%
– Array Fill Factor 92%
Four 16-Bit, Low-Voltage Differential Signaling
(LVDS), Double Data Rate (DDR) Input Data
Buses
Up to 400-MHz Input Data Clock Rate
42.2-mm × 42.2-mm × 7-mm Package Footprint
Hermetic Package
2 Applications
•
•
•
Industrial:
– Digital Imaging Lithography
– Laser Marking
– LCD and OLED Repair
– Computer-to-Plate Printers
– SLA 3D Printers
– 3D Scanners for Machine Vision and Factory
Automation
– Flat Panel Lithography
Medical:
– Phototherapy Devices
– Ophthalmology
– Direct Manufacturing
– Hyperspectral Imaging
– 3D Biometrics
– Confocal Microscopes
Display:
– 3D Imaging Microscopes
– Adaptive Illumination
– Augmented Reality and Information Overlay
In addition to the DLP9500 DMD, the 0.95 1080p
chipset includes a dedicated DLPC410 controller
required for high speed pattern rates of >23000 Hz
(1-bit binary) and >1700 Hz (8-bit gray), one unit
DLPR410 (DLP Discovery 4100 Configuration
PROM), and two units DLPA200 (DMD micromirror
drivers).
Reliable function and operation of the DLP9500
requires that it be used in conjunction with the other
components of the chipset. A dedicated chipset
provides developers easier access to the DMD as
well as high speed, independent micromirror control.
DLP9500
is
a
digitally
controlled
microelectromechanical system (MEMS) spatial light
modulator (SLM). When coupled to an appropriate
optical system, the DLP9500 can be used to
modulate the amplitude, direction, and/or phase of
incoming light.
Device Information
PART NUMBER
DLP9500
PACKAGE
LCCC (355)
(1)
BODY SIZE (NOM)
42.16 mm × 42.16 mm
(1) For all available packages, see the orderable addendum at
the end of the data sheet.
Application Schematic
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.
DLP9500
DLPS025C – AUGUST 2012 – REVISED SEPTEMBER 2015
www.ti.com
Table of Contents
1
2
3
4
5
6
7
Features .................................................................. 1
Applications ........................................................... 1
Description ............................................................. 1
Revision History..................................................... 2
Description (continued)......................................... 4
Pin Configuration and Functions ......................... 4
Specifications....................................................... 13
7.1
7.2
7.3
7.4
7.5
7.6
7.7
7.8
7.9
7.10
7.11
7.12
7.13
7.14
8
Absolute Maximum Ratings .................................... 13
Storage Conditions.................................................. 13
ESD Ratings............................................................ 13
Recommended Operating Conditions..................... 14
Thermal Information ................................................ 15
Electrical Characteristics......................................... 15
LVDS Timing Requirements ................................... 16
LVDS Waveform Requirements.............................. 17
Serial Control Bus Timing Requirements................ 18
Systems Mounting Interface Loads....................... 19
Micromirror Array Physical Characteristics ........... 20
Micromirror Array Optical Characteristics ............. 21
Window Characteristics......................................... 22
Chipset Component Usage Specification ............. 23
Detailed Description ............................................ 24
8.1 Overview ................................................................. 24
8.2 Functional Block Diagram ....................................... 24
8.3
8.4
8.5
8.6
8.7
9
Feature Description.................................................
Device Functional Modes........................................
Window Characteristics and Optics .......................
Micromirror Array Temperature Calculation............
Micromirror Landed-On and Landed-Off Duty
Cycle ........................................................................
26
32
34
35
37
Application and Implementation ........................ 39
9.1 Application Information............................................ 39
9.2 Typical Application ................................................. 40
10 Power Supply Recommendations ..................... 42
10.1 Power-Up Sequence (Handled by the DLPC410) 42
10.2 DMD Power-Up and Power-Down Procedures..... 42
11 Layout................................................................... 43
11.1 Layout Guidelines ................................................. 43
11.2 Layout Example .................................................... 45
12 Device and Documentation Support ................. 46
12.1
12.2
12.3
12.4
12.5
12.6
Device Support ....................................................
Documentation Support ........................................
Community Resources..........................................
Trademarks ...........................................................
Electrostatic Discharge Caution ............................
Glossary ................................................................
46
46
46
47
47
47
13 Mechanical, Packaging, and Orderable
Information ........................................................... 47
4 Revision History
NOTE: Page numbers for previous revisions may differ from page numbers in the current version.
Changes from Revision B (July 2013) to Revision C
Page
•
Added ESD Ratings table, Feature Description section, Device Functional Modes, Application and Implementation
section, Power Supply Recommendations section, Layout section, Device and Documentation Support section, and
Mechanical, Packaging, and Orderable Information section ................................................................................................. 1
•
Minor wording changes in Features and Description sections ............................................................................................... 1
•
Changed name of Micromirror clocking pulse reset ............................................................................................................. 11
•
Changed ESD Ratings table to match new standard........................................................................................................... 13
•
Adjusted recommended power density conditions ............................................................................................................... 14
•
Changed thermal test points to match new test point diagram ............................................................................................ 14
•
Replaced Figure 3. ............................................................................................................................................................... 18
•
Changed units from lbs to N................................................................................................................................................. 19
•
Added Max Recommended DMD Temperature – Derating Curve....................................................................................... 22
•
Added explanation for the15 MBRST lines to the DLP9500 from each DLPA200............................................................... 26
•
Changed Thermal Test Point Location graphic .................................................................................................................... 35
•
Added program interface to system interface list ................................................................................................................. 41
•
Corrected number of banks of DMD mirrors to 15 ............................................................................................................... 41
•
Removed link to DLP Discovery 4100 chipset datasheet..................................................................................................... 46
•
Added Community Resources ............................................................................................................................................. 46
2
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Copyright © 2012–2015, Texas Instruments Incorporated
Product Folder Links: DLP9500
DLP9500
www.ti.com
DLPS025C – AUGUST 2012 – REVISED SEPTEMBER 2015
Changes from Revision A (September 2012) to Revision B
Page
•
Added DLPR4101 enhanced PROM to DLPR410 in chipset list ........................................................................................... 1
•
Added DLPR4101 Enhanced PROM to DLPR410 in Related Documentation .................................................................... 46
Changes from Original (August 2012) to Revision A
•
Page
Changed the device From: Product Preview To: Production ................................................................................................. 1
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3
DLP9500
DLPS025C – AUGUST 2012 – REVISED SEPTEMBER 2015
www.ti.com
5 Description (continued)
Electrically, the DLP9500 consists of a two-dimensional array of 1-bit CMOS memory cells, organized in a grid of
1920 memory cell columns by 1080 memory cell rows. The CMOS memory array is addressed on a row-by-row
basis, over four 16-bit LVDS DDR buses. Addressing is handled by a serial control bus. The specific CMOS
memory access protocol is handled by the DLPC410 digital controller.
6 Pin Configuration and Functions
FLN Type A Package
355-Pin LCCC
Bottom View
31
29
30
27
28
25
26
23
24
21
22
19
20
17
18
15
16
13
14
11
12
9
10
7
8
5
6
1
3
4
2
A
B
C
D
E
F
G
H
J
K
L
M
N
P
R
T
U
V
W
Y
AA
AB
AC
AD
AE
AF
AG
AH
AJ
AK
AL
4
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Product Folder Links: DLP9500
DLP9500
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DLPS025C – AUGUST 2012 – REVISED SEPTEMBER 2015
Pin Functions
PIN
(1)
NAME
NO.
TYPE
(I/O/P)
SIGNAL
DATA
RATE (2)
INTERNAL TERM
(3)
CLOCK
DESCRIPTION
TRACE
(MILS)
DATA BUS A
D_AN(0)
F2
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_A
512.01
D_AN(1)
H8
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_A
158.79
D_AN(2)
E5
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_A
471.24
D_AN(3)
G9
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_A
159.33
D_AN(4)
D2
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_A
585.41
D_AN(5)
G3
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_A
551.17
D_AN(6)
E11
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_A
229.41
D_AN(7)
F8
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_A
300.54
D_AN(8)
C9
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_A
346.35
D_AN(9)
H2
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_A
782.27
D_AN(10)
B10
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_A
451.52
D_AN(11)
G15
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_A
74.39
D_AN(12)
D14
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_A
194.26
D_AN(13)
F14
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_A
D_AN(14)
C17
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_A
244.9
D_AN(15)
H16
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_A
73.39
D_AP(0)
F4
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_A
509.63
D_AP(1)
H10
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_A
152.59
D_AP(2)
E3
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_A
464.09
D_AP(3)
G11
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_A
152.39
D_AP(4)
D4
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_A
591.39
D_AP(5)
G5
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_A
532.16
D_AP(6)
E9
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_A
230.78
D_AP(7)
F10
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_A
300.61
D_AP(8)
C11
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_A
338.16
D_AP(9)
H4
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_A
773.17
D_AP(10)
B8
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_A
449.57
(1)
(2)
(3)
Input data bus A
(2x LVDS)
148.29
The following power supplies are required to operate the DMD: VCC, VCC1, VCC2. VSS must also be connected.
DDR = Double Data Rate. SDR = Single Data Rate. Refer to the LVDS Timing Requirements for specifications and relationships.
Refer to Electrical Characteristics for differential termination specification
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Product Folder Links: DLP9500
5
DLP9500
DLPS025C – AUGUST 2012 – REVISED SEPTEMBER 2015
www.ti.com
Pin Functions (continued)
PIN
(1)
NAME
NO.
TYPE
(I/O/P)
SIGNAL
DATA
RATE (2)
INTERNAL TERM
(3)
CLOCK
TRACE
(MILS)
DESCRIPTION
D_AP(11)
H14
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_A
71.7
D_AP(12)
D16
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_A
198.69
D_AP(13)
F16
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_A
D_AP(14)
C15
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_A
240.14
D_AP(15)
G17
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_A
74.05
D_BN(0)
AH2
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_B
525.25
D_BN(1)
AD8
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_B
190.59
D_BN(2)
AJ5
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_B
525.25
D_BN(3)
AE3
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_B
494.91
D_BN(4)
AG9
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_B
222.67
D_BN(5)
AE11
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_B
205.45
D_BN(6)
AH10
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_B
309.05
D_BN(7)
AF10
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_B
285.62
D_BN(8)
AK8
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_B
483.58
D_BN(9)
AG5
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_B
711.58
D_BN(10)
AL11
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_B
462.21
D_BN(11)
AE15
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_B
74.39
D_BN(12)
AH14
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_B
D_BN(13)
AF14
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_B
156
D_BN(14)
AJ17
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_B
247.9
D_BN(15)
AD16
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_B
111.52
D_BP(0)
AH4
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_B
525.02
D_BP(1)
AD10
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_B
190.61
D_BP(2)
AJ3
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_B
524.22
D_BP(3)
AE5
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_B
476.07
D_BP(4)
AG11
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_B
222.8
D_BP(5)
AE9
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_B
219.48
D_BP(6)
AH8
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_B
306.55
D_BP(7)
AF8
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_B
298.04
D_BP(8)
AK10
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_B
480.31
Input data bus A
(2x LVDS)
143.72
DATA BUS B
6
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Input data bus B
(2x LVDS)
194.26
Copyright © 2012–2015, Texas Instruments Incorporated
Product Folder Links: DLP9500
DLP9500
www.ti.com
DLPS025C – AUGUST 2012 – REVISED SEPTEMBER 2015
Pin Functions (continued)
PIN
(1)
NAME
NO.
TYPE
(I/O/P)
SIGNAL
DATA
RATE (2)
INTERNAL TERM
(3)
CLOCK
DESCRIPTION
TRACE
(MILS)
D_BP(9)
AG3
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_B
727.18
D_BP(10)
AL9
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_B
461.02
D_BP(11)
AD14
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_B
71.35
D_BP(12)
AH16
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_B
D_BP(13)
AF16
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_B
150.38
D_BP(14)
AJ15
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_B
243.14
D_BP(15)
AE17
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_B
113.36
D_CN(0)
B14
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_C
459.04
D_CN(1)
E15
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_C
342.79
D_CN(2)
A17
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_C
456.22
D_CN(3)
G21
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_C
68.24
D_CN(4)
B20
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_C
362.61
D_CN(5)
F20
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_C
163.07
D_CN(6)
D22
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_C
204.16
D_CN(7)
G23
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_C
105.59
D_CN(8)
B26
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_C
450.51
D_CN(9)
F28
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_C
302.04
D_CN(10)
C29
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_C
D_CN(11)
G27
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_C
D_CN(12)
D26
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_C
276.76
D_CN(13)
H28
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_C
186.78
D_CN(14)
E29
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_C
311.3
D_CN(15)
J29
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_C
262.62
D_CP(0)
B16
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_C
463.64
D_CP(1)
E17
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_C
347.65
D_CP(2)
A15
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_C
456.45
D_CP(3)
H20
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_C
67.72
D_CP(4)
B22
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_C
362.76
D_CP(5)
F22
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_C
161.69
Input data bus B
(2x LVDS)
197.69
DATA BUS C
Input data bus C
(2x LVDS)
429.8
317.1
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DLP9500
DLPS025C – AUGUST 2012 – REVISED SEPTEMBER 2015
www.ti.com
Pin Functions (continued)
PIN
(1)
NAME
NO.
TYPE
(I/O/P)
SIGNAL
DATA
RATE (2)
INTERNAL TERM
(3)
CLOCK
DESCRIPTION
TRACE
(MILS)
D_CP(6)
D20
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_C
195.09
D_CP(7)
H22
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_C
104.86
D_CP(8)
B28
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_C
451.41
D_CP(9)
F26
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_C
294.22
D_CP(10)
C27
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_C
D_CP(11)
G29
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_C
D_CP(12)
D28
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_C
276.04
D_CP(13)
H26
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_C
186.25
D_CP(14)
E27
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_C
312.07
D_CP(15)
J27
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_C
262.94
D_DN(0)
AK14
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_D
492.53
D_DN(1)
AG15
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_D
342.78
D_DN(2)
AL17
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_D
491.83
D_DN(3)
AE21
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_D
74.24
D_DN(4)
AK20
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_D
356.23
D_DN(5)
AF20
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_D
D_DN(6)
AH22
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_D
D_DN(7)
AE23
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_D
105.59
D_DN(8)
AK26
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_D
450.51
D_DN(9)
AF28
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_D
302.04
D_DN(10)
AJ29
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_D
429.8
D_DN(11)
AE27
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_D
298.87
Input data bus C
(2x LVDS)
429.68
314.98
DATA BUS D
8
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(2x LVDS)
163.07
204.16
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Pin Functions (continued)
PIN
(1)
NAME
NO.
TYPE
(I/O/P)
SIGNAL
DATA
RATE (2)
INTERNAL TERM
(3)
CLOCK
DESCRIPTION
TRACE
(MILS)
D_DN(12)
AH26
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_D
276.76
D_DN(13)
AD28
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_D
186.78
D_DN(14)
AG29
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_D
311.3
D_DN(15)
AC29
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_D
262.62
D_DP(0)
AK16
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_D
495.13
D_DP(1)
AG17
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_D
342.47
D_DP(2)
AL15
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_D
492.06
D_DP(3)
AD20
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_D
67.72
D_DP(4)
AK22
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_D
356.37
D_DP(5)
AF22
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_D
D_DP(6)
AH20
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_D
D_DP(7)
AD22
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_D
102.86
D_DP(8)
AK28
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_D
451.41
D_DP(9)
AF26
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_D
296.7
D_DP(10)
AJ27
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_D
429.68
D_DP(11)
AE29
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_D
302.74
D_DP(12)
AH28
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_D
276.04
D_DP(13)
AD26
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_D
186.25
D_DP(14)
AG27
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_D
312.07
D_DP(15)
AC27
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_D
262.94
Input data bus D
(2x LVDS)
161.98
195.09
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Pin Functions (continued)
PIN
(1)
NAME
NO.
TYPE
(I/O/P)
SIGNAL
DATA
RATE (2)
INTERNAL TERM
CLOCK
(3)
DESCRIPTION
TRACE
(MILS)
DATA CLOCKS
DCLK_AN
D10
Input
LVCMOS
—
Differentially
terminated – 100 Ω
—
DCLK_AP
D8
Input
LVCMOS
—
Differentially
terminated – 100 Ω
—
DCLK_BN
AJ11
Input
LVCMOS
—
Differentially
terminated – 100 Ω
—
DCLK_BP
AJ9
Input
LVCMOS
—
Differentially
terminated – 100 Ω
—
DCLK_CN
C23
Input
LVCMOS
—
Differentially
terminated – 100 Ω
—
DCLK_CP
C21
Input
LVCMOS
—
Differentially
terminated – 100 Ω
—
DCLK_DN
AJ23
Input
LVCMOS
—
Differentially
terminated – 100 Ω
—
DCLK_DP
AJ21
Input
LVCMOS
—
Differentially
terminated – 100 Ω
—
Input data bus A
Clock (2x LVDS)
Input data bus B
Clock (2x LVDS)
Input data bus C
Clock (2x LVDS)
Input data bus D
Clock (2x LVDS)
325.8
319.9
318.92
318.74
252.01
241.18
252.01
241.18
DATA CONTROL INPUTS
SCTRL_AN
J3
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_A
SCTRL_AP
J5
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_A
SCTRL_BN
AF4
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_B
SCTRL_BP
AF2
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_B
SCTRL_CN
E23
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_C
SCTRL_CP
E21
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_C
SCTRL_DN
AG23
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
DCLK_D
SCTRL_DP
AG21
Input
LVCMOS
DDR
Differentially
terminated – 100 Ω
Serial control for
data bus A (2x
LVDS)
608.14
Serial control for
data bus B (2x
LVDS)
698.12
Serial control for
data bus C (2x
LVDS)
232.46
235.53
DCLK_D
Serial control for
data bus D (2x
LVDS)
607.45
703.8
235.21
235.66
SERIAL COMMUNICATION AND CONFIGURATION
SCPCLK
AE1
Input
LVCMOS
—
pull-down
—
Serial port clock
324.26
SCPDO
AC3
Output
LVCMOS
—
—
SCP_CLK
Serial port output
281.38
SCPDI
AD2
Input
LVCMOS
—
pull-down
SCP_CLK
Serial port input
261.55
SCPEN
AD4
Input
LVCMOS
—
pull-down
SCP_CLK
Serial port enable
184.86
PWRDN
B4
Input
LVCMOS
—
pull-down
—
Device reset
458.78
MODE_A
J1
Input
LVCMOS
—
pull-down
—
G1
Input
LVCMOS
—
pull-down
—
Data bandwidth
mode select
471.57
MODE_B
10
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Pin Functions (continued)
PIN
(1)
NAME
NO.
TYPE
(I/O/P)
SIGNAL
DATA
RATE (2)
INTERNAL TERM
CLOCK
(3)
TRACE
(MILS)
DESCRIPTION
MICROMIRROR CLOCKING PULSE (BIAS RESET)
MBRST(0)
L5
Input
Analog
—
—
—
898.97
MBRST(1)
M28
Input
Analog
—
—
—
621.98
MBRST(2)
P4
Input
Analog
—
—
—
846.88
MBRST(3)
P30
Input
Analog
—
—
—
784.18
MBRST(4)
L3
Input
Analog
—
—
—
763.34
MBRST(5)
P28
Input
Analog
—
—
—
749.61
MBRST(6)
P2
Input
Analog
—
—
—
878.25
MBRST(7)
T28
Input
Analog
—
—
—
783.83
MBRST(8)
M4
Input
Analog
—
—
—
969.36
MBRST(9)
L29
Input
Analog
—
—
—
621.24
MBRST(10)
T4
Input
Analog
—
—
—
918.43
MBRST(11)
N29
Input
Analog
—
—
—
MBRST(12)
N3
Input
Analog
—
—
—
MBRST(13)
L27
Input
Analog
—
—
—
MBRST(14)
R3
Input
Analog
—
—
—
MBRST(15)
V28
Input
Analog
—
—
—
MBRST(16)
V4
Input
Analog
—
—
—
MBRST(17)
R29
Input
Analog
—
—
—
MBRST(18)
Y4
Input
Analog
—
—
—
715
MBRST(19)
AA27
Input
Analog
—
—
—
604.35
MBRST(20)
W3
Input
Analog
—
—
—
832.39
MBRST(21)
W27
Input
Analog
—
—
—
675.21
MBRST(22)
AA3
Input
Analog
—
—
—
861.18
MBRST(23)
W29
Input
Analog
—
—
—
662.66
MBRST(24)
U5
Input
Analog
—
—
—
850.06
MBRST(25)
U29
Input
Analog
—
—
—
726.56
MBRST(26)
Y2
Input
Analog
—
—
—
861.48
MBRST(27)
AA29
Input
Analog
—
—
—
683.83
MBRST(28)
U3
Input
Analog
—
—
—
878.5
MBRST(29)
Y30
Input
Analog
—
—
—
789.2
Power
Analog
—
—
—
Power for LVCMOS
logic
—
Power
Analog
—
—
—
Power supply for
LVDS Interface
—
685.14
Micromirror clocking
pulse reset MBRST
signals clock
micromirrors into
state of LVCMOS
memory cell
associated with each
mirror.
812.31
591.89
878.5
660.15
848.64
796.31
POWER
A3, A5, A7, A9,
A11, A13, A21,
A23, A25, A27,
A29, B2,
VCC
C1, C31, E31,
G31, J31, K2,
L31, N31, R31,
U31, W31,
AA31, AC1,
AC31, AE31,
AG1, AG31,
AJ31, AK2,
AK30, AL3, AL5,
AL7, AL19, AL21,
AL23, AL25,
AL27
VCCI
H6, H12, H18,
H24, M6, M26,
P6, P26, T6, T26,
V6, V26,
Y6, Y26, AD6,
AD12, AD18,
AD24
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Pin Functions (continued)
PIN
(1)
NAME
NO.
L1, N1, R1, U1,
W1, AA1
VCC2
TYPE
(I/O/P)
SIGNAL
DATA
RATE (2)
INTERNAL TERM
CLOCK
(3)
TRACE
(MILS)
DESCRIPTION
Power
Analog
—
—
—
Power for high
voltage CMOS logic
—
Power
Analog
—
—
—
Common return for
all power inputs
—
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,
VSS
AB6, AB26,
AB28, AB30,
AD30, AE7,
AE13, 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
RESERVED SIGNALS (NOT FOR USE IN SYSTEM)
RESERVED_FC
J7
Input
LVCMOS
—
pull-down
—
RESERVED_FD
J9
Input
LVCMOS
—
pull-down
—
RESERVED_PFE
J11
Input
LVCMOS
—
pull-down
—
RESERVED_STM
AC7
Input
LVCMOS
—
pull-down
—
—
RESERVED_AE
C3
Input
LVCMOS
—
pull-down
—
—
A19, B6, C5,
H30, J13, J15,
J17, J19, J21,
J23, J25, R27,
NO_CONNECT
AA5, AC11,
AC13, AC15,
AC17, AC19,
AC21, AC23,
—
—
—
—
—
—
—
Pins should be
connected to VSS
No connection (any
connection to these
terminals may result
in undesirable
effects)
—
—
AC25, AC5, AC9,
AK24, AK4, AL13
12
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7 Specifications
7.1 Absolute Maximum Ratings
over operating free-air temperature (unless otherwise noted).
(1)
MIN
MAX
UNIT
ELECTRICAL
VCC
Voltage applied to VCC
(2) (3)
–0.5
4
V
VCCI
Voltage applied to VCCI
(2) (3)
–0.5
4
V
VCC2
Voltage applied to VVCC2
–0.5
9
V
VMBRST
Clocking pulse waveform voltage applied to MBRST[29:0] input pins (supplied
by DLPA200s)
–28
28
V
0.3
V
|VCC – VCCI|
(2) (3) (4)
Supply voltage delta (absolute value)
(4)
Voltage applied to all other input terminals
|VID|
(2)
VCC + 0.3
V
Maximum differential voltage, damage can occur to internal termination resistor
if exceeded, see Figure 2
–0.5
700
mV
Current required from a high-level output, VOH = 2.4 V
–20
mA
Current required from a low-level output, VOL = 0.4 V
15
mA
20
70
°C
–40
80
°C
ENVIRONMENTAL
Case temperature – operational
TC
Case temperature – non-operational
TGRADIENT
(1)
(2)
(3)
(4)
(5)
(6)
(5)
(5)
(6)
10
°C
Operating relative humidity (non-condensing)
95
%RH
Device temperature gradient – operational
Stresses beyond those listed under Recommended Operating Conditions may cause permanent damage to the device. These are stress
ratings only, which do not imply functional operation of the device at these or any other conditions beyond those indicated under
Recommended Operating Conditions . Exposure to absolute-maximum-rated conditions for extended periods may affect device
reliability.
All voltages referenced to VSS (ground).
Voltages VCC, VCCI, and VCC2 are required for proper DMD operation.
Exceeding the recommended allowable absolute voltage difference between VCC and VCCI may result in excess current draw. The
difference between VCC and VCCI, | VCC – VCCI|, should be less than the specified limit.
DMD Temperature is the worst-case of any test point shown in Case Temperature, or the active array as calculated by the Micromirror
Array Temperature Calculation.
As measured between any two points on the exterior of the package, or as predicted between any two points inside the micromirror
array cavity. Refer to Case Temperature and Micromirror Array Temperature Calculation.
7.2 Storage Conditions
applicable before the DMD is installed in the final product
Tstg
Storage temperature
MIN
MAX
–40
80
°C
95
%RH
Storage humidity (non-condensing)
UNIT
7.3 ESD Ratings
VALUE
VESD
(1)
Electrostatic
discharge
Human body model (HBM), per ANSI/ESDA/JEDEC JS-001
(1)
All pins except
MBRST[29:0]
±2000
MBRST[29:0] pins
±250
UNIT
V
JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process. Manufacturing with
less than 500-V HBM is possible if necessary precautions are taken.
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7.4 Recommended Operating Conditions
over operating free-air temperature range (unless otherwise noted).
SUPPLY VOLTAGES
(1)
MIN
NOM
MAX
UNIT
(2) (3)
VCC
Supply voltage for LVCMOS core logic
3.0
3.3
3.6
V
VCCI
Supply voltage for LVDS receivers
3.0
3.3
3.6
V
VCC2
Mirror electrode and HVCMOS supply voltage
8.25
8.5
8.75
V
VMBRST
Clocking Pulse Waveform Voltage applied to MBRST[29:0] Input Pins (supplied
by DLPA200s)
26.5
V
|VCC – VCCI|
Supply voltage delta (absolute value)
0.3
V
TGRADIENT
Operating Case Temperature
(7)
Operating Case Temperature
(7)
(6)
: Thermal Test Points 2 and 3
(8)
: Thermal Test Point 1 and Array
Device temperature gradient – operational
(8)
20
25-45
70
(8)
°C
20
25-45
65
(8)
°C
10
°C
(9)
Operating relative humidity (non-condensing)
ILLVIS
-27
(5)
ENVIRONMENTAL – For Illumination Source between 420 and 700 nm
TC
(4)
0
Illumination
Thermally limited
ENVIRONMENTAL – For Illumination Source between 400 and 420 nm
TC
TGRADIENT
Operating Case Temperature
(7)
Operating Case Temperature
(7)
(8)
: Thermal Test Point 1 and Array
(8)
20
25-45
70
(8)
°C
20
25-45
65
(8)
°C
(9)
Operating relative humidity (non-condensing)
ILLVIS
TC
TGRADIENT
Operating case temperature
(7)
Operating case temperature
(7)
10
°C
95
%RH
2.5
W/cm2
0
Illumination
ENVIRONMENTAL – For Illumination Source <400 and >700 nm
%RH
W/cm2
(6)
: Thermal Test Points 2 and 3
Device temperature gradient – operational
95
(10)
(6)
: Thermal test points 2 and 3
(8)
: Thermal test point 1 and array
Device temperature gradient – operational
20
(8)
20
(9)
Operating relative humidity (non-condensing)
0
25-45
25-45
70
(8)
°C
65
(8)
°C
10
°C
95
%RH
ILLUV
Illumination, wavelength < 400 nm
0.68
mW/cm2
ILLIR
Illumination, wavelength > 700 nm
10
mW/cm2
(1)
The functional performance of the device specified in this data sheet is achieved when operating the device within the limits defined by
the Recommended Operating Conditions. No level of performance is implied when operating the device above or below the
Recommended Operating Conditions limits.
(2) Supply voltages VCC, VCCI, VOFFSET, VBIAS, and VRESET are all required for proper DMD operation. VSS must also be connected.
(3) All voltages are referenced to common ground VSS.
(4) Voltages VCC, VCCI, and VCC2, are required for proper DMD operation.
(5) Exceeding the recommended allowable absolute voltage difference between VCC and VCCI may result in excess current draw. The
difference between VCC and VCCI, | VCC – VCCI|, should be less than the specified limit.
(6) 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.
(7) In some applications, the total DMD heat load can be dominated by the amount of incident light energy absorbed. See Micromirror Array
Temperature Calculation for further details.
(8) See the Micromirror Array Temperature Calculation for thermal test point locations, package thermal resistance, and device temperature
calculation.
(9) As measured between any two points on the exterior of the package, or as predicted between any two points inside the micromirror
array cavity. Refer to Case Temperature and Micromirror Array Temperature Calculation.
(10) Refer to Case Temperature and Micromirror Array Temperature Calculation.
14
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7.5 Thermal Information
DLP9500
THERMAL METRIC
(1) (2)
LCCC
UNIT
355 PINS
Active micromirror array resistance to TC2
(1)
(2)
0.5
°C/W
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.
For more information about traditional and new thermal metrics, see the Semiconductor and IC Package Thermal Metrics application
report, SPRA953.
7.6 Electrical Characteristics
over the range of recommended supply voltage and recommended case operating temperature (unless otherwise noted);
under recommended operating conditions
PARAMETER
TEST CONDITIONS
(1)
VOH
High-level output voltage
See Figure 11
Low-level output voltage
See Figure 11
(1)
VOL
VMBRST
Clocking pulse waveform applied to
MBRST[29:0] input pins (supplied by
DLPA200s)
IOZ
High-impedance output current
IOH
IOL
,
VCC = 3 V, IOH = –20 mA
,
High-level output current
(1)
Low-level output current
(1)
MIN
–27
VCC = 3.6 V
V
10
µA
–15
VOL = 0.4 V, VCC ≥ 3 V
15
VOL = 0.4 V, VCC ≥ 2.25 V
14
Low-level input voltage
IIL
Low-level input current
(1)
IIH
High-level input current
ICC
Current into VCC pin
ICCI
Current into VOFFSET pin
ICC2
Current into VCC2 pin
PD
Power dissipation
ZIN
Internal differential impedance
95
ZLINE
Line differential impedance (PWB, trace)
90
CI
Input capacitance
CO
Output capacitance
CIM
Input capacitance for MBRST[29:0] pins
(1)
(2)
26.5
VOH = 1.7 V, VCC ≥ 2.25 V
VIL
(2)
V
–20
(1)
(1)
0.4
VOH = 2.4 V, VCC ≥ 3 V
(1)
1.7
VCC + .3
–0.3
(1)
mA
mA
V
0.7
V
VCC = 3.6 V, VI = 0 V
–60
µA
VCC = 3.6 V, VI = VCC
60
µA
VCC = 3.6 V,
2990
mA
VCCI = 3.6 V
910
mA
25
mA
VCC2 = 8.75 V
4.4
(1)
UNIT
V
VCC = 3.6 V, IOH = 15 mA
(1)
MAX
2.4
High-level input voltage
VIH
TYP
ƒ = 1 MHz
ƒ = 1 MHz
ƒ = 1 MHz
270
W
105
100
Ω
110
Ω
10
pF
10
pF
355
pF
Applies to LVCMOS pins only.
Exceeding the maximum allowable absolute voltage difference between VCC and VCCI may result in excess current draw. (See Absolute
Maximum Ratings for details.)
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7.7 LVDS Timing Requirements
over operating free-air temperature range (unless otherwise noted); see Figure 1
MIN
ƒDCLK_x
DCLK_x clock frequency (where x = [A, B, C, or D])
200
tc
Clock cycle - DLCK_x
2.5
tw
Pulse duration - DLCK_x
ts
Setup time - D_x[15:0] and SCTRL_x before DCLK_x
th
Hold time, D_x[15:0] and SCTRL_x after DCLK_x
tskew
Skew between any two buses (A ,B, C, and D)
NOM
MAX
UNIT
400
MHz
ns
1.25
ns
.35
ns
.35
–1.25
ns
1.25
ns
DCLK_AN
DCLK_AP
th
tw
tw
tc
ts
ts
th
SCTRL_AN
SCTRL_AP
tskew
D_AN(15:0)
D_AP(15:0)
DCLK_BN
DCLK_BP
tw
tw
ts
th
tc
ts
th
SCTRL_BN
SCTRL_BP
D_BN(15:0)
D_BP(15:0)
tw
DCLK_CN
DCLK_CP
ts
th
tw
tc
ts
th
SCTRL_CN
SCTRL_CP
tskew
D_CN(15:0)
D_CP(15:0)
DCLK_DN
DCLK_DP
tw
tw
ts
th
tc
th
ts
SCTRL_DN
SCTRL_DP
D_DN(15:0)
D_DP(15:0)
Figure 1. LVDS Timing Waveforms
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7.8 LVDS Waveform Requirements
over operating free-air temperature range (unless otherwise noted); see Figure 2
MIN
|VID|
Input differential voltage (absolute difference)
VCM
Common mode voltage
VLVDS
LVDS voltage
tr
tr
100
NOM
MAX
UNIT
400
600
mV
1200
mV
0
2000
mV
Rise time (20% to 80%)
100
400
ps
Fall time (80% to 20%)
100
400
ps
V LVDS max = V CM max + | 1/2 × VID max |
tf
VID
V CM
tr
VLVDS min = V CM min ± | 1/2 × VID max |
Figure 2. LVDS Waveform Requirements
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7.9 Serial Control Bus Timing Requirements
over operating free-air temperature range (unless otherwise noted); see Figure 3 and Figure 4
MIN
NOM
MAX
UNIT
50
500
kHz
–300
300
ns
960
ns
ƒSCP_CLK
SCP clock frequency
tSCP_SKEW
Time between valid SCP_DI and rising edge of SCP_CLK
tSCP_DELAY
Time between valid SCP_DO and rising edge of SCP_CLK
t SCP_EN
Time between falling edge of SCP_EN and the first rising edge of SCP_CLK
t_SCP
Rise time for SCP signals
200
ns
tƒ_SCP
Fall time for SCP signals
200
ns
tc
SCPCLK
30
ns
fclock = 1 / tc
50%
50%
tSCP_SKEW
SCPDI
50%
tSCP_DELAY
SCPD0
50%
Figure 3. Serial Communications Bus Timing Parameters
tr_SCP
tf_SCP
Input Controller VCC
SCP_CLK,
SCP_DI,
SCP_EN
VCC/2
0v
Figure 4. Serial Communications Bus Waveform Requirements
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7.10 Systems Mounting Interface Loads
PARAMETER
Maximum system mounting interface
load to be applied to the:
MAX
UNIT
Thermal interface area (see Figure 5)
MIN
NOM
156
N
Electrical interface area (see Figure 5)
1334
N
Datum A Interface area (see Figure 5)
712
N
Thermal
Interface Area
Electrical
Interface Area
Other Area
Datum ‘A’ Areas
Figure 5. System Interface Loads
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7.11 Micromirror Array Physical Characteristics
See Mechanical, Packaging, and Orderable Information for additional details.
M
Number of active micromirror columns
N
Number of active micromirror rows
P
Micromirror (pixel) pitch
1920
micromirrors
1080
micromirrors
(1)
(1)
Micromirror active array height
(1)
(1) (2)
10.8
µm
M×P
20.736
mm
N×P
11.664
mm
10
micromirrors/side
Pond of micromirrors (POM)
M±4
M±3
M±2
M±1
See Figure 6.
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
(1)
(2)
UNIT
(1)
Micromirror active array width
Micromirror array border
VALUE
(1)
0
1
2
3
DMD Active Array
NxP
M x N Micromirrors
N±4
N±3
N±2
N±1
MxP
P
Border micromirrors omitted for clarity.
Details omitted for clarity.
P
Not to scale.
P
P
Refer to the Micromirror Array Physical Characteristics table for M, N, and P specifications.
Figure 6. Micromirror Array Physical Characteristics
20
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7.12 Micromirror Array Optical Characteristics
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. See the related
application reports (listed in Related Documentation) for guidelines.
PARAMETER
a
Micromirror tilt angle
β
Micromirror tilt angle variation
Micromirror crossover time
TEST CONDITIONS
(1) (4) (6) (7) (8)
MIN
(1) (2) (3)
0
DMD landed state
See Figure 12
(1) (4) (5)
12
,
See Figure 12
16
Micromirror array optical efficiency
(3)
(4)
(5)
(6)
(7)
(8)
(9)
(10)
(11)
(12)
(13)
(13) (14)
See Figure 12
400 to 700 nm, with all
micromirrors in the ON state
degrees
1
degrees
22
µs
10
0
44
UNIT
µs
Adjacent micromirrors
(12)
MAX
56
Non-adjacent micromirrors
(11)
Orientation of the micromirror axis-of-rotation
(1)
(2)
–1
(9)
Micromirror switching time at 400 MHz with global
reset (10)
Non-operating micromirrors
TYP
DMD parked state
See Figure 12
45
46
micromirrors
degrees
68%
Measured relative to the plane formed by the overall micromirror array
Parking the micromirror array returns all of the micromirrors to an essentially flat (0˚) state (as measured relative to the plane formed by
the overall micromirror array).
When the micromirror array is parked, the tilt angle of each individual micromirror is uncontrolled.
Additional variation exists between the micromirror array and the package datums, as shown in Mechanical, Packaging, and Orderable
Information.
When the micromirror array is landed, the tilt angle 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 an nominal angular
position of +12°. A binary value of 0 results in a micromirror landing in an nominal angular position of –12°.
Represents the landed tilt angle variation relative to the nominal landed tilt angle.
Represents the variation that can occur between any two individual micromirrors, located on the same device or located on different
devices.
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 and/or system contrast variation.
Micromirror crossover time is primarily a function of the natural response time of the micromirrors.
Micromirror switching is controlled and coordinated by the DLPC410 (DLPS024) and DLPA200 (DLPS015). Nominal switching time
depends on the system implementation and represents the time for the entire micromirror array to be refreshed.
Non-operating micromirror is defined as a micromirror that is unable to transition nominally from the –12° position to +12° or vice versa.
Measured relative to the package datums 'B' and 'C', shown in the Mechanical, Packaging, and Orderable Information.
The minimum or maximum DMD optical efficiency observed in a specific application depends on numerous application-specific design
variables, such as:
(a) Illumination wavelength, bandwidth/line-width, degree of coherence
(b) Illumination angle, plus angle tolerance
(c) Illumination and projection aperture size, and location in the system optical path
(d) Illumination overfill of the DMD micromirror array
(e) Aberrations present in the illumination source and/or path
(f) Aberrations present in the projection path
The specified nominal DMD optical efficiency is based on the following use conditions:
(a) Visible illumination (400 to 700 nm )
(b) Input illumination optical axis oriented at 24° relative to the window normal
(c) Projection optical axis oriented at 0° relative to the window normal
(d) ƒ / 3 illumination aperture
(e) ƒ / 2.4 projection aperture
Based on these use conditions, the nominal DMD optical efficiency results from the following four components:
(a) Micromirror array fill factor: nominally 92%
(b) Micromirror array diffraction efficiency: nominally 86%
(c) Micromirror surface reflectivity: nominally 88%
(d) Window transmission: nominally 97% (single pass, through two surface transitions)
(14) Does not account for the effect of micromirror switching duty cycle, which is application dependent. Micromirror switching duty cycle
represents the percentage of time that the micromirror is actually reflecting light from the optical illumination path to the optical projection
path. This duty cycle depends on the illumination aperture size, the projection aperture size, and the micromirror array update rate.
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7.13 Window Characteristics
PARAMETER
(1)
TEST CONDITIONS
Window material designation
Corning 7056
Window refractive index
At wavelength 589 nm
Window flatness
(2)
Window aperture
See
Illumination overfill
Refer to Illumination Overfill
(4)
(5)
MAX
4
Within the Window Aperture
Window transmittance, single–pass
through both surfaces and glass (5)
TYP
UNIT
1.487
Per 25 mm
Window artifact size
(1)
(2)
(3)
MIN
(3)
400
fringes
µm
(4)
At wavelength 405 nm. Applies to 0° and 24° AOI only.
95%
Minimum within the wavelength range 420 nm to 680 nm.
Applies to all angles 0° to 30° AOI.
97%
Average over the wavelength range 420 nm to 680 nm.
Applies to all angles 30° to 45° AOI.
97%
See Window Characteristics and Optics for more information.
At a wavelength of 632.8 nm.
See the Mechanical, Packaging, and Orderable Information section at the end of this document for details regarding the size and
location of the window aperture.
For details regarding the size and location of the window aperture, see the package mechanical characteristics listed in the Mechanical
ICD in the Mechanical, Packaging, and Orderable Information section.
See the TI application report DLPA031, Wavelength Transmittance Considerations for DLP DMD Window.
Figure 7. Max Recommended DMD Temperature – Derating Curve
22
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7.14 Chipset Component Usage Specification
The DLP9500 is a component of one or more DLP chipsets. Reliable function and operation of the DLP9500
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 is the TI
technology and devices for operating or controlling a DLP DMD.
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8 Detailed Description
8.1 Overview
Optically, the DLP9500 consists of 2,073,600 highly reflective, digitally switchable, micrometer-sized mirrors
(micromirrors), organized in a two-dimensional array of 1920 micromirror columns by 1080 micromirror rows ().
Each aluminum micromirror is approximately 10.8 microns in size (see the Micromirror Pitch in ) and is
switchable between two discrete angular positions: –12° and 12°. The angular positions are measured relative to
a 0° flat state, which is parallel to the array plane (see Figure 12). The tilt direction is perpendicular to the hingeaxis, which is positioned diagonally relative to the overall array. The On State landed position is directed toward
row 0, column 0 (upper left) corner of the device package (see the Micromirror Hinge-Axis Orientation in ). In the
field of visual displays, the 1920 × 1080 pixel resolution is referred to as 1080p.
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 (–12° or +12°) of the individual
micromirrors changes synchronously with a micromirror clocking pulse, rather than being synchronous with the
CMOS memory cell data update. Therefore, writing a logic 1 into a memory cell followed by a mirror clocking
pulse will result in the corresponding micromirror switching to a 12° position. Writing a logic 0 into a memory cell
followed by a mirror clocking pulse will result in the corresponding micromirror switching to a –12° position.
Updating the angular position of the micromirror array consists of two steps. First, updating the contents of the
CMOS memory. Second, application of a micromirror clocking pulse to all or a portion of the micromirror array
(depending upon the configuration of the system). Micromirror clocking pulses are generated externally by two
DLPA200s, with application of the pulses being coordinated by the DLPC410 controller.
Around the perimeter of the 1920 by 1080 array of micromirrors is a uniform band of border micromirrors. The
border micromirrors are not user-addressable. The border micromirrors land in the –12° position once power has
been applied to the device. There are 10 border micromirrors on each side of the 1920 by 1080 active array.
Figure 8 shows a DLPC410 and DLP9500 chipset block diagram. The DLPC410 and DLPA200s control and
coordinate the data loading and micromirror switching for reliable DLP9500 operation. The DLPR410 is the
programmed PROM required to properly configure the DLPC410 controller. For more information on the chipset
components, see Application and Implementation. For a typical system application using the DLP Discovery 4100
chipset including a DLP9500, see Figure 18.
8.2 Functional Block Diagram
Figure 8 shows a simplified system block diagram with the use of the DLPC410 with the following chipset
components:
DLPC410
Xilinx [XC5VLX30] FPGA configured to provide high-speed DMD data and control, and DLPA200
timing and control
DLPR410
[XCF16PFSG48C] serial flash PROM contains startup configuration information (EEPROM)
DLPA200
Two DMD micromirror drivers for the DLP9500 DMD
DLP9500
Spatial light modulator (DMD)
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DLPC410
PWR_FLOAT
ROWMD(1:0)
ROWAD(10:0)
RST2BLKZ
BLKMD(1:0)
BLKAD(10:0)
ECP2_FINISHED
DMD_TYPE(3:0)
Bank A Input
Bank B Input
Bank C Input
DDC_DCLKOUT_C
DDC_SCTRL_C
Bank B Input
DDC_DOUT_C(15:0)
DDC_DCLKOUT_D
DDC_SCTRL_D
DDC_DOUT_D(15:0)
DMD SCP
SCPCLK
SCPDO
SCPDI
DMD_A_SCPENZ
DMD_B_SCPENZ
A_SCPENZ
B_SCPENZ
A_STROBE
A_MODE(1:0)
A_SEL(1:0)
A_ADDR(3:0)
DLPA200
A
MBRST1_(15:0)
OEZ
INIT
PROM_CCK_DDC
DONE_DDC
INTB_DDC
RDWR_B_0
TDO_XCF16DDC
TCK_JTAG
TCK_JTAG
TDO_DDC
DDC_M(2:0)
ECP2_M_TP(31:0)
B_SEL(1:0)
B_ADDR(3:0)
B
MBRST2_(15:0)
JTAG Interface
HSWAPEN_0
B_STROBE
B_MODE(1:0)
DLPA200
Resets Side 2
PROM_DO_DDC
Resets
PROGB_DDC
CS_B_0
JTAG Header
DDC_DOUT_B(15:0)
DLPA200 B SCP
TDI_JTAG
JTAG Interface
DLPR410
Program Interface
DDC_VERSION(2:0)
Program Interface
Info Input
INIT_ACTIVE
Info Output
RST_ACTIVE
Serial Data Bus
WDT_ENBLZ
DLPA200 A Output
STEPVCC
DLPA200 B Output
Control Signals Output
NS_FLIP
Control Signals Input
COMP_DATA
DDC_SCTRL_B
Resets Side 1
DDC_DIN_D(15:0)
DDC_DCLKOUT_B
Resets
DVALID_D
DDC_DOUT_A(15:0)
DLPA200 A SCP
DDC_DCLK_D
DDC_SCTRL_A
DLPA200 B Input
Bank D Output
DDC_DIN_C(15:0)
DDC_DCLKOUT_A
DLPA200 A Input
DVALID_C
Bank A Output
DDC_DCLK_C
Bank B Output
Bank C Output
DDC_DIN_B(15:0)
Bank C Output
DVALID_B
Bank B Output
DDC_DCLK_B
Bank A Input
Bank B Output
DDC_DIN_A(15:0)
Bank B Input
DVALID_A
Bank C Input
DDC_DCLK_A
DLP9500
= LVDS Bus
Bank D Input
Bank A Output
USER INTERFACE
VLED0
VLED1
DDCSPARE(1:0)
OSC
50 Mhz
ARSTZ
DMD_A_RESET
CLKIN_R
DMD_B_RESET
Figure 8. DLPC410, DLPA200, DLPR410, and DLP9500 Functional Block Diagram
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8.3 Feature Description
Table 1. DMD Overview
DMD
ARRAY
SINGLE BLOCK
MODE
(PATTERNS/s)
GLOBAL RESET
MODE
(PATTERNS/s)
DATA RATE
(GIGA PIXELS/s)
MIRROR PITCH
DLP9500 - 0.95" 1080p
1920 × 1080
23148
17857
48
10.8 μm
8.3.1 DLPC410 Controller
The DLPC410 chipset includes the DLPC410 controller which provides a high-speed LVDS data and control
interface for DMD control. This interface is also connected to a second FPGA used to drive applications (not
included in the chipset). The DLPC410 generates DMD and DLPA200 initialization and control signals in
response to the inputs on the control interface.
For more information, see the DLPC410 data sheet (DLPS024).
8.3.2 DLPA200 DMD Micromirror Drivers
DLPA200 micromirror drivers provide the micromirror clocking pulse driver functions for the DMD. Two drivers
are required for DLP9500.
The DLPA200 is designed to work with multiple DLP chipsets. Although the DLPA200 contains 16 MBSRT output
pins, only 15 lines are used with the DLP9500 chipset. For more information see and the DLPA200 data sheet
(DLPS015).
8.3.3 Flash Configuration PROM
The DLPC410 is configured at startup from the serial flash PROM. The contents of this PROM can not be
altered. For more information, see the DLPC410 data sheet (DLPS024) and DLPR410 data sheet (DLPS027).
8.3.4 DMD
8.3.4.1 DLP9500 1080p Chipset Interfaces
This section will describe the interface between the different components included in the chipset. For more
information on component interfacing, see Application and Implementation.
8.3.4.1.1 DLPC410 Interface Description
8.3.4.1.1.1 DLPC410 IO
Table 2 describes the inputs and outputs of the DLPC410 to the user. For more details on these signals, see the
DLPC410 data sheet (DLPS024).
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Table 2. Input/Output Description
PIN NAME
DESCRIPTION
I/O
ARST
Asynchronous active low reset
I
CLKIN_R
Reference clock, 50 MHz
I
DIN_[A,B,C,D](15:0)
LVDS DDR input for data bus A,B,C,D (15:0)
I
DCLKIN[A,B,C,D]
LVDS inputs for data clock (200 - 400 MHz) on bus A, B, C, and D
I
DVALID[A,B,C,D]
LVDS input used to start write sequence for bus A, B, C, and D
I
ROWMD(1:0)
DMD row address and row counter control
I
ROWAD(10:0)
DMD row address pointer
I
BLK_AD(3:0)
DMD mirror block address pointer
I
BLK_MD(1:0)
DMD mirror block reset and clear command modes
I
PWR_FLOAT
Used to float DMD mirrors before complete loss of power
I
DMD_TYPE(3:0)
DMD type in use
O
RST_ACTIVE
Indicates DMD mirror reset in progress
O
INIT_ACTIVE
Initialization in progress.
O
VLED0
System “heartbeat” signal
O
VLED1
Denotes initialization complete
O
8.3.4.1.1.2 Initialization
The INIT_ACTIVE (Table 2) signal indicates that the DLP9500, DLPA200s, and DLPC410 are in an initialization
state after power is applied. During this initialization period, the DLPC410 is initializing the DLP9500 and
DLPA200s by setting all internal registers to their correct states. When this signal goes low, the system has
completed initialization. System initialization takes approximately 220 ms to complete. Data and command write
cycles should not be asserted during the initialization.
During initialization the user must send a training pattern to the DLPC410 on all data and DVALID lines to
correctly align the data inputs to the data clock. For more information, see the interface training pattern
information in the DLPC410 data sheet.
8.3.4.1.1.3 DMD Device Detection
The DLPC410 automatically detects the DMD type and device ID. DMD_TYPE (Table 2) is an output from the
DLPC410 that contains the DMD information.
8.3.4.1.1.4 Power Down
To ensure long term reliability of the DLP9500, a shutdown procedure must be executed. Prior to power removal,
assert the PWR_FLOAT (Table 2) signal and allow approximately 300 µs for the procedure to complete. This
procedure assures the mirrors are in a flat state.
8.3.4.1.2 DLPC410 to DMD Interface
8.3.4.1.2.1 DLPC410 to DMD IO Description
Table 3 lists the available controls and status pin names and their corresponding signal type, along with a brief
functional description.
Table 3. DLPC410 to DMD I/O Pin Descriptions
PIN NAME
DESCRIPTION
I/O
DDC_DOUT_[A,B,C,D](15:0)
LVDS DDR output to DMD data bus A,B,C,D (15:0)
O
DDC_DCLKOUT_[A,B,C,D]
LVDS output to DMD data clock A,B,C,D
O
DDC_SCTRL_[A,B,C,D]
LVDS DDR output to DMD data control A,B,C,D
O
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8.3.4.1.2.2 Data Flow
Figure 9 shows the data traffic through the DLPC410. Special considerations are necessary when laying out the
DLPC410 to allow best signal flow.
LVDS BUS A
sDIN_A(15:0)
sDCLK_A
sDVALID_A
LVDS BUS B
sDIN_B(15:0)
sDCLK_B
sDVALID_B
LVDS BUS D
LVDS BUS C
sDIN_D(15:0)
sDCLK_D
sDVALID_D
sDIN_C(15:0)
sDCLK_C
sDVALID_C
DLPC410
LVDS BUS D
LVDS BUS A
sDOUT_D(15:0)
sDCLKOUT_D
sSCTRL_D
sDOUT_A(15:0)
sDCLKOUT_A
sSCTRL_A
LVDS BUS C
sDOUT_C(15:0)
sDCLKOUT_C
sSCTRL_C
LVDS BUS B
sDIN_B(15:0)
sDCLK_B
sDVALID_B
Figure 9. DLPC410 Data Flow
Four LVDS buses transfer the data from the user to the DLPC410. Each bus has its data clock that is input edge
aligned with the data (DCLK). Each bus also has its own validation signal that qualifies the data input to the
DLPC410 (DVALID).
Output LVDS buses transfer data from the DLPC410 to the DMD. Output buses LVDS C and LVDS D are used
in addition to LVDS A and LVDS B with the DLP9500.
8.3.4.1.3 DLPC410 to DLPA200 Interface
8.3.4.1.3.1 DLPA200 Operation
The DLPA200 DMD micromirror driver is a mixed-signal application-specific integrated circuit (ASIC) that
combines the necessary high-voltage power supply generation and micromirror clocking pulse functions for a
family of DMDs. The DLPA200 is programmable and controllable to meet all current and anticipated DMD
requirements.
The DLPA200 operates from a 12-V power supply input. For more detailed information on the DLPA200, see the
DLPA200 data sheet.
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8.3.4.1.3.2 DLPC410 to DLPA200 IO Description
The serial communications port (SCP) is a full duplex, synchronous, character-oriented (byte) port that allows
exchange of commands from the DLPC410 to the DLPA200s.
DLPA200
SCP bus
DLPC410
SCP bus
DLPA200
Figure 10. Serial Port System Configuration
Five signal lines are associated with the SCP bus: SCPEN, SCPCK, SCPDI, SCPDO, and IRQ.
Table 4 lists the available controls and status pin names and their corresponding signal type, along with a brief
functional description.
Table 4. DLPC410 to DLPA200 I/O Pin Descriptions
PIN NAME
DESCRIPTION
I/O
A_SCPEN
Active-low chip select for DLPA200 serial bus
O
A_STROBE
DLPA200 control signal strobe
O
A_MODE(1:0)
DLPA200 mode control
O
A_SEL(1:0)
DLPA200 select control
O
A_ADDR(3:0)
DLPA200 address control
O
B_SCPEN
Active-low chip select for DLPA200 serial bus (2)
O
B_STROBE
DLPA200 control signal strobe (2)
O
B_MODE(1:0)
DLPA200 mode control
O
B_SEL(1:0)
DLPA200 select control
O
B_ADDR(3:0)
DLPA200 address control
O
The DLPA200 provides a variety of output options to the DMD by selecting logic control inputs: MODE[1:0],
SEL[1:0] and reset group address A[3:0] (Table 4). The MODE[1:0] input determines whether a single output, two
outputs, four outputs, or all outputs, will be selected. Output levels (VBIAS, VOFFSET, or VRESET) are selected
by SEL[1:0] pins. Selected outputs are tri-stated on the rising edge of the STROBE signal and latched to the
selected voltage level after a break-before-make delay. Outputs will remain latched at the last micromirror
clocking pulse waveform level until the next micromirror clocking pulse waveform cycle.
8.3.4.1.4 DLPA200 to DLP9500 Interface
8.3.4.1.4.1 DLPA200 to DLP9500 Interface Overview
The DLPA200 generates three voltages: VBIAS, VRESET, and VOFFSET that are supplied to the DMD MBRST
lines in various sequences through the micromirror clocking pulse driver function. VOFFSET is also supplied
directly to the DMD as DMDVCC2. A fourth DMD power supply, DMDVCC, is supplied directly to the DMD by
regulators.
The function of the micromirror clocking pulse driver is to switch selected outputs in patterns between the three
voltage levels (VBIAS, VRESET and VOFFSET) to generate one of several micromirror clocking pulse
waveforms. The order of these micromirror clocking pulse waveform events is controlled externally by the logic
control inputs and timed by the STROBE signal. DLPC410 automatically detects the DMD type and then uses the
DMD type to determine the appropriate micromirror clocking pulse waveform.
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A direct micromirror clocking pulse operation causes a mirror to transition directly from one latched state to the
next. The address must already be set up on the mirror electrodes when the micromirror clocking pulse is
initiated. Where the desired mirror display period does not allow for time to set up the address, a micromirror
clocking pulse with release can be performed. This operation allows the mirror to go to a relaxed state regardless
of the address while a new address is set up, after which the mirror can be driven to a new latched state.
A mirror in the relaxed state typically reflects light into a system collection aperture and can be thought of as off
although the light is likely to be more than a mirror latched in the off state. System designers should carefully
evaluate the impact of relaxed mirror conditions on optical performance.
8.3.5 Measurement Conditions
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. All rise
and fall transition timing parameters are referenced to VIL MAX and VIH MIN for input clocks, VOL MAX and VOH
MIN for output clocks.
LOAD CIRCUIT
RL
From Output
Under Test
Tester
Channel
CL = 50 pF
CL = 5 pF for Disable Time
Figure 11. Test Load Circuit for AC Timing Measurements
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Ill Inc
um id
in en
at t
io
n
www.ti.com
Package Pin
A1 Corner
Ill Inc
um id
in en
at t
io
n
DLP9500
Two
“On-State”
Micromirrors
For Reference
t
nt t Pa
ide gh
Inc on-Li
ati
min
Illu
t
h
h
at
nt
ide ht P
Inc n-Lig
atio
min
Illu
Projected-Light
Path
Two
“Off-State”
Micromirrors
O
gh
Li
eat th
t
S a
ff- P
a±b
Flat-State
( “parked” )
Micromirror Position
-a ± b
Silicon Substrate
“On-State”
Micromirror
Silicon Substrate
“Off-State”
Micromirror
Figure 12. Micromirror Landed Positions and Light Paths
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8.4 Device Functional Modes
The DLP9500 has only one functional mode; it is set to be highly optimized for low latency and high speed in
generating mirror clocking pulses and timings.
When operated with the DLPC410 controller in conjunction with the DLPA200 drivers, the DLP9500 can be
operated in several display modes. The DLP9500 is loaded as 15 blocks of 72 rows each. The first 64 bits of
pixel data and last 64 bits of pixel data for all rows are not visible. Below is a representation of how the image is
loaded by the different micromirror clocking pulse modes. Figure 13, Figure 14, Figure 15, and Figure 16 show
how the image is loaded by the different micromirror clocking pulse modes.
There are four micromirror clocking pulse modes that determine which blocks are reset when a micromirror
clocking pulse command is issued:
• Single block mode
• Dual block mode
• Quad block mode
• Global mode
8.4.1 Single Block Mode
In single block mode, a single block can be loaded and reset in any order. After a block is loaded, it can be reset
to transfer the information to the mechanical state of the mirrors.
Figure 13. Single Block Mode
8.4.2 Dual Block Mode
In dual block mode, reset blocks are paired together as follows (0-1), (2-3), (4-5), (6-7), (8-9), (10-11), (12-13),
and (14). These pairs can be reset in any order. After data is loaded a pair can be reset to transfer the
information to the mechanical state of the mirrors.
Figure 14. Dual Block Mode
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Device Functional Modes (continued)
8.4.3 Quad Block Mode
In quad block mode, reset blocks are grouped together in fours as follows (0-3), (4-7), (8-11) and (12-14). Each
quad group can be randomly addressed and reset. After a quad group is loaded, it can be reset to transfer the
information to the mechanical state of the mirrors.
Figure 15. Quad Block Mode
8.4.4 Global Block Mode
In global mode, all reset blocks are grouped into a single group and reset together. The entire DMD must be
loaded with the desired data before issuing a Global Reset to transfer the information to the mechanical state of
the mirrors.
Figure 16. Global Mode
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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, projection pupils, or both 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 recommends the exit pupil of the illumination 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 optical architecture of a
particular system, overfill light may have to be further reduced below the suggested 10% level to be acceptable.
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8.6 Micromirror Array Temperature Calculation
Achieving optimal DMD performance requires proper management of the maximum DMD case temperature, the
maximum temperature of any individual micromirror in the active array, the maximum temperature of the window
aperture, and the temperature gradient between case temperature and the predicted micromirror array
temperature (see Figure 17).
See the Recommended Operating Conditions for applicable temperature limits.
8.6.1 Package Thermal Resistance
The DMD is designed to conduct absorbed and dissipated heat to the back of the type A 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 specified operational temperatures, refer to Figure 17. The total heat load on the DMD is
typically 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.
8.6.2 Case Temperature
The temperature of the DMD case can be measured directly. For consistency, thermal test point locations 1, 2,
and 3 are defined, as shown in Figure 17.
21.08
Figure 17. Thermal Test Point Location
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Micromirror Array Temperature Calculation (continued)
8.6.3 Micromirror Array Temperature Calculation
Micromirror array temperature cannot be measured directly; therefore, it must be computed analytically from
measurement points (Figure 17), the package thermal resistance, the electrical power, and the illumination heat
load. The relationship between micromirror array temperature and the case temperature are provided by
Equation 1 and Equation 2:
TArray = T Ceramic + (QArray × RArray-To-Ceramic)
(1)
QArray = QELE + QILL
where
•
•
•
•
•
•
TArray = Computed micromirror array temperature (°C)
TCeramic = Ceramic temperature (°C) (TP1 location Figure 17)
QArray = Total DMD array power (electrical + absorbed) (measured in Watts)
RArray-To-Ceramic = Thermal resistance of DMD package from array to TP1 (°C/W) (see Package Thermal
Resistance)
QELE = Nominal electrical power (W)
QILL = Absorbed illumination energy (W)
(2)
An example calculation is provided based on a traditional DLP video projection system. The electrical power
dissipation of the DMD is variable and depends on the voltages, data rates, and operating frequencies. The
nominal electrical power dissipation used in the calculation is 4.4 W. Thus, QELE = 4.4 W. The absorbed power
from the illumination source is variable and depends on the operating state of the mirrors and the intensity of the
light source. Based on modeling and measured data from DLP projection system:
QILL = CL2W × SL
where
•
•
•
•
CL2W is a lumens to watts constant and can be estimated at 0.00274 W/lm
SL = Screen lumens nominally measured to be 2000 lm
QArray = 4.4 + (0.00274 × 2000) = 9.88 W, estimated total power on micromirror array
TCeramic = 55°C, assumed system measurement
(3)
Finally, TArray (micromirror active array temperature) is:
TArray= 55°C + (9.88 W × 0.5°C/W) = 59.9°C
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8.7 Micromirror Landed-On and 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.
Because 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 usable life of the DMD.
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.
8.7.3 Landed Duty Cycle and Operational DMD Temperature
Operational DMD temperature and landed duty cycle interact to affect the usable life of the DMD, and this
interaction can be exploited to reduce the impact that an asymmetrical landed duty cycle has on the DMD’s
usable life. This is quantified in the derating curve shown in Figure 7. The importance of this curve is that:
• All points along this curve represent the same usable life.
• All points above this curve represent lower usable life (and the further away from the curve, the lower the
usable life).
• All points below this curve represent higher usable life (and the further away from the curve, the higher the
usable life).
In practice, this curve specifies the maximum operating DMD temperature that the DMD should be operated at
for a give long-term average landed duty.
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 5.
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Table 5. Grayscale Value and Landed Duty Cycle
GRAYSCALE VALUE
LANDED DUTY CYCLE
0%
0/100
10%
10/90
20%
20/80
30%
30/70
40%
40/60
50%
50/50
60%
60/40
70%
70/30
80%
80/20
90%
90/10
100%
100/0
Accounting for color rendition (but still ignoring image processing) requires knowing both the color intensity (from
0% to 100%) for each constituent primary color (red, green, and/or blue) for the given pixel as well as the color
cycle time for each primary color, where “color cycle time” is the total percentage of the frame time that a given
primary must be displayed to achieve the desired white point.
During a given period of time, the landed duty cycle of a given pixel can be calculated as follows:
Landed Duty Cycle = (Red_Cycle_% × Red_Scale_Value) + (Green_Cycle_% × Green_Scale_Value) +
(Blue_Cycle_% × Blue_Scale_Value)
where:
Red_Cycle_%, Green_Cycle_%, and Blue_Cycle_%, represent the percentage of the frame time that Red,
Green, and Blue are displayed (respectively) to achieve the desired white point.
For example, assume that the red, green and blue color cycle times are 50%, 20%, and 30% respectively (to
achieve the desired white point), then the landed duty for various combinations of red, green, blue color
intensities would be as shown in Table 6.
Table 6. Example Landed Duty Cycle for Full-Color
38
RED CYCLE PERCENTAGE
50%
GREEN CYCLE PERCENTAGE
20%
BLUE CYCLE PERCENTAGE
30%
RED SCALE VALUE
GREEN SCALE VALUE
BLUE SCALE VALUE
0%
0%
0%
0/100
100%
0%
0%
50/50
0%
100%
0%
20/80
0%
0%
100%
30/70
12%
0%
0%
6/94
0%
35%
0%
7/93
0%
0%
60%
18/82
100%
100%
0%
70/30
LANDED DUTY CYCLE
0%
100%
100%
50/50
100%
0%
100%
80/20
12%
35%
0%
13/87
0%
35%
60%
25/75
12%
0%
60%
24/76
100%
100%
100%
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 DLP9500 devices must be coupled with the DLPC410 controller to provide a reliable solution for many
different applications. The DMDs are spatial light modulators which reflect incoming light from an illumination
source to one of two directions, with the primary direction being into a projection collection optic. Each application
is derived primarily from the optical architecture of the system and the format of the data coming into the
DLPC410. Applications of interest include 3D printing, lithography, medical systems, and compressive sensing.
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9.2 Typical Application
A typical embedded system application using the DLPC410 controller and DLP9500 is shown in Figure 18. In this configuration, the DLPC410 controller
supports input from an FPGA. The FPGA sends low-level data to the controller, enabling the system to be highly optimized for low latency and high
speed.
OPTICAL
SENSOR
LED
DRIVERS
(CAMERA)
LEDS
OPTICS
LED
SENSORS
USER
INTERFACE
LVDS BUS (A,B,[C,D])
LVDS BUS (A,B,[C,D])
DDC_DCLK, DVALID, DDC_DIN(15:0)
DDC_DCLKOUT, DDCSCTRL, DDC_DOUT(15:0)
SCP BUS
ROW and BLOCK SIGNALS
SCPCLK, SCPDO, SCPDI, DMD_SCPENZ, A_SCPENZ, B_SCPENZ
ROWMD(1:0), ROWAD(10:0), BLKMD(1:0), BLKAD(3:0), RST2BLKZ
CONNECTIVITY
(USB, ETHERNET, ETC.)
CONTROL SIGNALS
COMP_DATA, NS_FLIP, WDT_ENBLZ, PWR_FLOAT
USER - MAIN
PROCESSOR / FPGA
DLPA200 CONTROL
A_MODE(1:0), A_SEL(1:0),
A_ADDR(3:0), OEZ, INIT
DLPC410 INFO SIGNALS
RST_ACTIVE, INIT_ACTIVE, ECP2_FINISHED,
DMD_TYPE(3:0), DDC_VERSION(2:0)
MBRST1_(15:0)
DLP9500
DLPA200
A
DLPC410
PGM SIGNALS
VOLATILE
and
NON-VOLATILE
STORAGE
DLPR410
PROM_CCK_DDC, PROGB_DDC,
PROM_DO_DDC, DONE_DDC, INTB_DDC
DLPA200 CONTROL
B_MODE(1:0), B_SEL(1:0),
B_ADDR(3:0), OEZ, INIT
JTAG
ARSTZ
CLKIN_R
OSC
50 Mhz
~
MBRST2_(15:0)
DLPA200
B
VLED0
VLED1
DMD_RESET
POWER MANAGMENT
Figure 18. DLPC410 and DLP9500 Embedded Example Block Diagram
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9.2.1 Design Requirements
All applications using the DLP9500 1080p chipset require both the controller and the DMD components for
operation. The system also requires an external parallel flash memory device loaded with the DLPC410
configuration and support firmware. The chipset has several system interfaces and requires some support
circuitry. The following interfaces and support circuitry are required:
• DLPC410 system interfaces:
– Control interface
– Trigger interface
– Input data interface
– Illumination interface
– Reference clock
– Program interface
• DLP9500 interfaces:
– DLPC410 to DLP9500 digital data
– DLPC410 to DLP9500 control interface
– DLPC410 to DLP9500 micromirror reset control interface
– DLPC410 to DLPA200 micromirror driver
– DLPA200 to DLP9500 micromirror reset
9.2.1.1 Device Description
The DLP9500 1080p chipset offers developers a convenient way to design a wide variety of industrial, medical,
telecom and advanced display applications by delivering maximum flexibility in formatting data, sequencing data,
and light patterns.
The DLP9500 1080p chipset includes the following four components: DMD digital controller (DLPC410),
EEPROM (DLPR410), DMD micromirror driver (DLPA200), and a DMD (DLP9500).
DLPC410 DMD digital controller
• Provides high speed 2XLVDS data and control interface to the user.
• Drives mirror clocking pulse and timing information to the DLPA200.
• Supports random row addressing.
• Controls illumination
DLPR410 EEPROM
• Contains startup configuration information for the DLPC410
DLPA200 DMD micromirror driver
• Generates micromirror clocking pulse control (sometimes referred to as a reset) of 15 banks of DMD
mirrors. (Two are required for the DLP9500.)
DLP9500 DMD
• Steers light in two digital positions (+12° and –12°) using 1920 × 1080 micromirror array of aluminum
mirrors.
Table 7. DLP DLP9500 Chipset Configurations
QUANTITY
TI PART
1
DLP9500
0.95 1080p Type A digital micromirror device (DMD)
DESCRIPTION
1
DLPC410
DLP Discovery 4100 DMD controller
1
DLPR410
DLP Discovery 4100 configuration PROM
2
DLPA200
DMD micromirror driver
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Reliable function and operation of DLP9500 1080p chipsets require the components be used in conjunction with
each other. This document describes the proper integration and use of the DLP9500 1080p chipset components.
The DLP9500 1080p chipset can be combined with a user programmable application FPGA (not included) to
create high performance systems.
9.2.2 Detailed Design Procedure
The DLP9500 DMD is well suited for visible light applications requiring fast, spatially programmable light patterns
using the micromirror array. See the block diagram in Figure 8 to see the connections between the DLP9500
DMD, the DLPC410 digital controller, the DLPR410 EEPROM, and the DLPA200 DMD micromirror drivers. An
example application block diagram can be found in Figure 18. Layout guidelines should be followed for reliability.
10 Power Supply Recommendations
10.1 Power-Up Sequence (Handled by the DLPC410)
The sequence of events for DMD system power-up is:
1. Apply logic supply voltages to the DLPA200 and to the DMD according to DMD specifications.
2. Place DLPA200 drivers into high impedance states.
3. Turn on DLPA200 bias, offset, or reset supplies according to driver specifications.
4. After all supply voltages are assured to be within the limits specified and with all micromirror clocking pulse
operations logically suspended, enable all drivers to either VOFFSET or VBIAS level.
5. Begin micromirror clocking pulse operations.
10.2 DMD Power-Up and Power-Down Procedures
Failure to adhere to the prescribed power-up and power-down procedures may affect device reliability. The
DLP9500 power-up and power-down procedures are defined by the DLPC410 data sheet (DLPS024). These
procedures must be followed to ensure reliable operation of the device.
42
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11 Layout
11.1 Layout Guidelines
The DLP9500 is part of a chipset that is controlled by the DLPC410 in conjunction with the DLPA200. These
guidelines are targeted at designing a PCB board with these components.
11.1.1 Impedance Requirements
Signals should be routed to have a matched impedance of 50 Ω ±10% except for LVDS differential pairs
(DMD_DAT_Xnn, DMD_DCKL_Xn, and DMD_SCTRL_Xn) which should be matched to 100 Ω ±10% across
each pair.
11.1.2 PCB Signal Routing
When designing a PCB board for the DLP9500 controlled by the DLPC410 in conjunction with the DLPA200s,
the following are recommended:
Signal trace corners should be no sharper than 45°. Adjacent signal layers should have the predominate traces
routed orthogonal to each other. TI recommends that critical signals be hand routed in the following order: DDR2
Memory, DMD (LVDS signals), then DLPA200 signals.
TI does not recommend signal routing on power or ground planes.
TI does not recommend ground plane slots.
High speed signal traces should not cross over slots in adjacent power and/or ground planes.
Table 8. Important Signal Trace Constraints
SIGNAL
CONSTRAINTS
LVDS (DMD_DAT_xnn,
DMD_DCKL_xn, and
DMD_SCTRL_xn)
P-to-N data, clock, and SCTRL: <10 mils (0.25 mm); Pair-to-pair <10 mils (0.25 mm); Bundle-to-bundle
<2000 mils (50 mm, for example DMD_DAT_Ann to DMD_DAT_Bnn)
Trace width: 4 mil (0.1 mm)
Trace spacing: In ball field – 4 mil (0.11 mm); PCB etch – 14 mil (0.36 mm)
Maximum recommended trace length <6 inches (150 mm)
Table 9. Power Trace Widths and Spacing
SIGNAL NAME
MINIMUM TRACE
WIDTH
MINIMUM TRACE
SPACING
GND
Maximize
5 mil (0.13 mm)
VCC, VCC2
20 mil (0.51 mm)
10 mil (0.25 mm)
MBRST[14:0]
11 mil (0.28 mm)
15 mil (0.38 mm)
LAYOUT REQUIREMENTS
Maximize trace width to connecting pin as a minimum
11.1.3 Fiducials
Fiducials for automatic component insertion should be 0.05-inch copper with a 0.1-inch cutout (antipad). Fiducials
for optical auto insertion are placed on three corners of both sides of the PCB.
11.1.4 PCB Layout Guidelines
A target impedance of 50 Ω for single ended signals and 100 Ω between LVDS signals is specified for all signal
layers.
11.1.4.1 DMD Interface
The digital interface from the DLPC410 to the DMD are LVDS signals that run at clock rates up to 400 MHz. Data
is clocked into the DMD on both the rising and falling edge of the clock, so the data rate is 800 MHz. The LVDS
signals should have 100 Ω differential impedance. The differential signals should be matched but kept as short
as possible. Parallel termination at the LVDS receiver is in the DMD; therefore, on board termination is not
necessary.
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11.1.4.1.1 Trace Length Matching
The DLPC410 DMD data signals require precise length matching. Differential signals should have impedance of
100Ω (with 5% tolerance). It is important that the propagation delays are matched. The maximum differential pair
uncoupled length is 100 mils with a relative propagation delay of ±25 mil between the p and n. Matching all
signals exactly will maximize the channel margin. The signal path through all boards, flex cables and internal
DMD routing must be considered in this calculation.
11.1.4.2 DLP9500 Decoupling
General decoupling capacitors for the DLP9500 should be distributed around the PCB and placed to minimize
the distance from IC voltage and ground pads. Each decoupling capacitor (0.1 µF recommended) should have
vias directly to the ground and power planes. Via sharing between components (discreet or integrated) is
discouraged. The power and ground pads of the DLP9500 should be tied to the voltage and ground planes with
their own vias.
11.1.4.2.1 Decoupling Capacitors
Decoupling capacitors should be placed to minimize the distance from the decoupling capacitor to the supply and
ground pin of the component. TI recommends that the placement of and routing for the decoupling capacitors
meet the following guidelines:
• The supply voltage pin of the capacitor should be located close to the device supply voltage pin or pins. The
decoupling capacitor should have vias to ground and voltage planes. The device can be connected directly to
the decoupling capacitor (no via) if the trace length is less than 0.1 inch. Otherwise, the component should be
tied to the voltage or ground plane through separate vias.
• The trace lengths of the voltage and ground connections for decoupling capacitors and components should
be less than 0.1 inch to minimize inductance.
• The trace width of the power and ground connection to decoupling capacitors and components should be as
wide as possible to minimize inductance.
• Connecting decoupling capacitors to ground and power planes through multiple vias can reduce inductance
and improve noise performance.
• Decoupling performance can be improved by using low ESR and low ESL capacitors.
11.1.4.3 VCC and VCC2
The VCC pins of the DMD should be connected directly to the DMD VCC plane. Decoupling for the VCC should
be distributed around the DMD and placed to minimize the distance from the voltage and ground pads. Each
decoupling capacitor should have vias directly connected to the ground and power planes. The VCC and GND
pads of the DMD should be tied to the VCC and ground planes with their own vias.
The VCC2 voltage can be routed to the DMD as a trace. Decoupling capacitors should be placed to minimize the
distance from the DMD’s VCC2 and ground pads. Using wide etch from the decoupling capacitors to the DMD
connection will reduce inductance and improve decoupling performance.
11.1.4.4 DMD Layout
See the respective sections in this data sheet for package dimensions, timing and pin out information.
11.1.4.5 DLPA200
The DLPA200 generates the micromirror clocking pulses for the DMD. The DMD-drive outputs from the
DLPA200 (MBRST[29:0] should be routed with minimum trace width of 11 mil and a minimum spacing of 15 mil.
The VCC and VCC2 traces from the output capacitors to the DLPA200 should also be routed with a minimum
trace width and spacing of 11 mil and 15 mil, respectively. See the DLPA200 customer data sheet DLPS015 for
mechanical package and layout information.
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11.2 Layout Example
For LVDS (and other differential signal) pairs and groups, it is important to match trace lengths. In the area of the
dashed lines, Figure 19 shows correct matching of signal pair lengths with serpentine sections to maintain the
correct impedance.
Figure 19. Mitering LVDS Traces to Match Lengths
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12 Device and Documentation Support
12.1 Device Support
12.1.1 Device Nomenclature
Figure 20 provides a legend of reading the complete device name for any DLP device.
DLP9500 FLN
Package Type
Device Descriptor
Figure 20. Device Nomenclature
12.1.2 Device Marking
Figure 21 shows the device marking fields.
TI Internal Numbering
2-Dimensional Matrix Code
DMD Part Number
(DMD Part Number and
Serial Number)
Part 2 of Serial Number
Part 1 of Serial Number
(7 characters)
(7 characters)
TI Internal Numbering
Figure 21. DLP9500 Device Marking
12.2 Documentation Support
12.2.1 Related Documentation
The following documents contain additional information related to the use of the DLP9500 device.
• DLPC410 digital controller data sheet
• DLPA200 DMD micromirror driver data sheet
• DLPR410 EEPROM data sheet
12.3 Community Resources
The following links connect to TI community resources. Linked contents are 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.
TI E2E™ Online Community TI's Engineer-to-Engineer (E2E) Community. Created to foster collaboration
among engineers. At e2e.ti.com, you can ask questions, share knowledge, explore ideas and help
solve problems with fellow engineers.
Design Support TI's Design Support Quickly find helpful E2E forums along with design support tools and
contact information for technical support.
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12.4 Trademarks
Discovery, E2E are trademarks of Texas Instruments.
DLP is a registered trademark of Texas Instruments.
All other trademarks are the property of their respective owners.
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.
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PACKAGE OPTION ADDENDUM
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23-Dec-2015
PACKAGING INFORMATION
Orderable Device
Status
(1)
Package Type Package Pins Package
Drawing
Qty
Eco Plan
Lead/Ball Finish
MSL Peak Temp
(2)
(6)
(3)
DLP9500BFLN
ACTIVE
LCCC
FLN
355
3
TBD
Call TI
Call TI
DLP9500FLN
NRND
LCCC
FLN
355
3
TBD
Call TI
Call TI
Op Temp (°C)
Device Marking
(4/5)
(1)
The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2)
Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability
information and additional product content details.
TBD: The Pb-Free/Green conversion plan has not been defined.
Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that
lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.
Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between
the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above.
Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight
in homogeneous material)
(3)
MSL, Peak Temp. - The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.
(4)
There may be additional marking, which relates to the logo, the lot trace code information, or the environmental category on the device.
(5)
Multiple Device Markings will be inside parentheses. Only one Device Marking contained in parentheses and separated by a "~" will appear on a device. If a line is indented then it is a continuation
of the previous line and the two combined represent the entire Device Marking for that device.
(6)
Lead/Ball Finish - Orderable Devices may have multiple material finish options. Finish options are separated by a vertical ruled line. Lead/Ball Finish values may wrap to two lines if the finish
value exceeds the maximum column width.
Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information
provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and
continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.
TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.
Addendum-Page 1
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PACKAGE OPTION ADDENDUM
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23-Dec-2015
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.
Addendum-Page 2
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