AMI AMIS-710616-AS

AMIS-710616-AS: CIS PCB
Data Sheet
Product Specification
1.0 General Description
This data sheet covers the AMIS-710616-AS (PI616MC-AS) specification.
CIS stands for contact image sensor. It is a one-dimension array of photosensitive elements, designed to image documents with a oneto-one magnification ratio. The sensors are sequentially cascaded to form a one dimensional variable-length line array in multiple
integral numbers, hence providing the users with desired lengths.
The AMIS-710616-AS is one of these special length line-image arrays. It is configured with a total of eight sub-sections, each section
containing a sequential line of five array sensors, with its individual video output line. These eight video outputs are also referred to as
tapped outputs. They are all read out in parallel (see Figure 1). The eight sub-sections are sequentially cascaded to form the onedimensional array. It is fabricated on two printed circuit boards (PCB) referred to as sensor boards. Each sensor board contains four
sub-sections. The two sensor boards are cascaded in series to form a complete line image sensor of eight sub-sections with a total
read length of ≅ 325mm. Accordingly, each sensor board contains 20 each of AMIS-720639 (PI3039) image sensors, also a product of
AMIS. Hence, for both boards there are a total of eight parallel tapped outputs and 40 each of the AMIS-720639 image array sensors.
Each chip has 192 photo sensing cells, hence on one board there are 3840 cell sites and a total of 7680 cell sites for both boards. Each
cell site is a photo-detector, which possesses its own independent processing circuit. An associated on-chip digital shift register scans
and reads the video signal of each photo detector onto a common output video line. In sections of five sensors, these common output
video lines are individually brought out to the I/O connectors of the sensor boards. There are two connectors, one on each board, each
containing four video outputs. These connectors are connected via a cable to their respective amplifier boards (see Figure 2). The
schematic of the AMIS-710616-AS and its PCB mechanical outline drawing are attached to this data sheet.
2.0 Overview
The AMIS-710616-AS has ≈ 324.2mm read width. Its recommended line rate is 192µs/line at a 5.0MHz clock rate, but its minimum can
be as low as 160µs/line at its maximum clocking speed of 6.0MHz. Its sensor photo-site density is 23.25elements/mm. See AMI
Semiconductor’s AMIS-720639 data sheet, which covers the specifications on the imaging array sensor. Operationally, it requires only
the power supplies, +5V and –5V and two input clocks, one is the clock (CP), to operate the internal shift registers and the second is
the start pulse (SP), to initiate the output scan.
3.0 Scan Outline
Table 3-1: Scanning Outline
Item
Readable width
Sensor photo-site density
Number of total active sensor photo-sites
Number of photo-sites per tap
Total line read time = read time per section
Clock frequency
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Specification
324.2mm
23.25elements/mm
7680 elements
960
192µs/line
160µs/line
5.0MHz
6.0MHz
1
Note
Typical, tested @ 5.0MHz Clock
Minimum, tested @ 6.0MHz Clock
Typical
Maximum
AMIS-710616-AS: CIS PCB
Data Sheet
Product Specification
4.0 Physical Outline
Table 4-1: Physical Outline
Item
Image sensors
PCB stiffner board
Sensor PCB
Data output
Sensor board connectors
Amplifier PCB board
Amplifier board’s four connectors
Specification
AMIS-720639
PCB stiffner board size
≅355.6mm x 41.3mm x 6.35mm
Size ≈165.1mm x 21.4mm x 1.62mm
Eight analog video outputs
Two I/O connectors
MOLEX 52610-1590
Size ≈ 291.3mm x 76.2mm x 1.6mm
Two inputs: MOLEX 52207-1950
Two outputs: ERNI-594083
Note
See referenced image sensor data sheet
Two PCBs mounted on the stiffner
Used to connect to their respective output
amplifiers
Mounted are eight output amplifiers for each
of the video lines from the sensor boards
5.0 Recommended Operating Conditions (25°C)
°
Table 5-1: Recommended Operating Conditions at 25 C
Item
Symbol
Power supply
VDD
IDD
VSS
ISS
(1)
Video output levels
Vpavg
(2)
Video saturation output
VSATA
(2)
Video line saturation output
VSATV
Input voltage at digital high (input clocks, SP and CP)
VIH
Input voltage at digital low (input clocks SP and CP)
VIL
(3)
Clock frequency
Freq
(4)
Clock pulse high duty cycle
Duty
(3)(5)
Clock high duration
TPW
Integration time
Tint
Operating temperature
Notes:
(1)
(2)
(3)
(4)
(5)
(6)
Top
Min.
4.5
135
VDD-1.0
0
Typ.
5.0
150
|-5.0|
45
3.0
5.5
1.2
VDD-.5
5.0
25
83.3
192µs/line
160µs/line
(6)
Max.
5.5
165
|-5.5|
60
VDD+0.3
0.8
6.0
75
100
25
50
Units
V
ma
V
ma
V
V
V
V
V
MHz
%
Ns, at 50 percent duty
Typical, tested @ 5.0MHz clock
Minimum, tested @ 6.0MHz clock
°
C
Vpavg is a symbol representing the average value of every pixel in the complete line scan. Vp(n) is the pixel amplitude of the nth pixel in a line scan. This
measurement is taken with the image array under a uniform light exposure. The typical output is specified with a uniform input light exposure of 0.5µJ/cm2 from a
blue Led light source.
Two saturated video output levels are specified. One is at the video signal’s output amplifier, VSATA, and the other is at the input of the amplifier. In almost all
applications, because the integration time is usually too short, there is not enough exposure time to saturate the array sensors. Accordingly, each output amplifier
is fixed with a gain of ≅ 4.5.
Freq is generally fixed for any application for the following reasons: One is the exposure time. With a given light power, the exposure time of the sensor can be
related to the clock frequency. The second is the shape of the video output pulse. Because the output video is in pulse charge packets, the signals are processed
on the output video line of the sensors. Hence, the signal shape depends greatly upon the amplifier configurations. Please refer to the referenced AMIS-720639
data sheet. It has some brief outline application notes. Under Note 6 on Page 6, there is a discussion about video pulse shapes. On Page 8, 9 and 10 there are
discussions on the three types of signal output stages.
Duty is the ratio of the clock’s pulse width over its pulse period. Because the video pixel output resets during the clock pulse’s high period and because the reset
requires a finite resetting time, it is recommended to operate the clock duty cycle within the following limits. See the referenced data sheet in Note 3, above.
Noting that the larger the duty, the less the signal amplitude, while too short of a clock pulse will not provide enough video reset time and leaves residual charges,
the recommended duty is 25 percent for frequencies less than 5MHz and 50 percent for frequencies greater than 5MHz.
Tint is determined by the time interval between two start pulses, (SP). Hence, if the SP is generated from a clock count down circuit, it will be directly proportional
to the clock frequency and it will be synchronous with the clock frequency. The longest integration time is determined by the degree of leakage current degradation
that can be tolerated by the system. A 10ms maximum is a typical rule-of-thumb. An experienced CIS user can use his discretion and determine the desired
tolerance level for the given system.
Top is a conservative engineering estimate. It is based on measurements of similar CIS modules and simple bench top tests, using heat guns and freeze sprays.
These will be re-measured during the pilot production under the standard QA practices that are under the control of ISO 9000.
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AMIS-710616-AS: CIS PCB
Data Sheet
Product Specification
6.0 Electro-Optical Characteristics (25°C)
°
Table 6-1: Electro-Optical Characteristics at 25 C
Parameter
Number of active photo detectors
Pixel-to-pixel spacing
Symbol
Parameter
7680
43.25
Units
Elements
µm
192
µs/line
(2)
6.0
MHz
(3)
70
V/µJ/cm2
(3)
55
V/µJ/cm2
(1)
Line scanning rate
Tint
Clock frequency
Freq
Red responsivity
ExpR
Green responsivity
ExpG
Blue responsivity
ExpB
Bright output voltage
(3)
Vpavg
(4)
Bright output non-uniformity
Up (5)
Adjacent pixel non-uniformity
Uadj
(6)
Bright output
Non-uniformity total
Uptotal
Dark non-uniformity
Dark video offset
Ud
(9)
Vd
(7)
(8)
Random noise
RNL
(10)
Modulation transfer function
MTF
(11)
35
V/µJ/cm2
3.0
V
<7
%
<10
%
<10
%
<25
-2.0
<11.8
<3.0
mV
Volts
p-p mV
rms mV
>70
%
Note
@ 5.0MHz clock
frequency
(see Note 1)
Maximum clock
frequency
(see Note 2)
See Note 3 for
definition
See Note 3 for
definition
See Note 3 for
definition
Green light
Depends on
optical system
(see Note 5)
Depends on the
optical system
(see Note 5)
Sensor only
(see Note 11)
Notes:
Since this is a prototype module, the following Notes 4, 5, 6, 7, and 8, are on data based on engineering scope measurements. The data will be re-measured during pilot
production using all the standard QA practices under the control of ISO 9000 regulations. Furthermore, they will be taken on fully computerized test systems. If required,
these prototype data may be revised.
(1)
Tint is the line-scan rate or integration time. It is determined by the time interval between two SPs. If the SP is generated from a clock count down circuit, it will
be directly proportional to clock frequency and it will be synchronous with the clock frequency. The longest integration time is determined by the degree of
leakage current degradation that can be tolerated by the system. A 10ms maximum is a typical rule-of-thumb. An experienced CIS user can use his discretion
to determine the desired tolerance level for the given system.
(2) Freq is the clock frequency, which is also equal to the signal data rate. It is generally fixed for many applications for following reasons: One is the exposure
time. With a given light power, the exposure time of the sensor depends on the integration time and in most applications it uses clock count down circuits to
generate the SP, shift register start pulse. The second is the shape of the video output pulse. Because the output is in pulse packets of video charges, the
signals are processed on the output video line of the sensors. The signal shape depends greatly upon the amplifier configurations. Please refer to the
referenced AMIS-720639 data sheet. It has some brief outline application notes. Under Note 6 on Page 6, there is a discussion on video pulse shapes. On
Page 8, 9 and 10 there are discussions on the three types of signal output stages.
(3) The responsivity is the ratio of video signal in volts, divided by the unit exposure (V/micro-Joules/cm 2). This exposure was measured with the output level
adjusted to 1.27V. The spread of the measured exposure R-RSP, G-RSP and B-RSP can be used to compute the user’s desired signal voltage level.
(4) Vpmax = maximum pixel value of Vp(n); Vpmin = minimum pixel value of Vp(n); Vpavg = ∑ Vp(n)/7680; where Vp(n) is the nth pixel in a line scan with the
module scanning a uniform white target. Vp values are measured with a uniform exposure.
(5) Bright output Non-uniformity: Up(+) = [(Vpmax - Vpavg) / Vpavg] x 100% or Up(-)= [(Vpavg - Vpmin) / Vpavg] x 100%, whichever polarity with the highest value
is selected. Two further notes: One is that the AMIS-710616-AS has no requirement for an optical system, or a light system. The second is that the nonuniformity is dominated by the LED light bar’s non-uniformity so only the sensor non-uniformity is specified. The normal standard CIS modules are enclosed in a
self-contained module with a complete optical and LED lighting system. So the light system, usually the LED bar, is included in making the measurement of the
optical characteristics. This fixes the optical geometry for the module and the light source. The module’s optical characteristics are simply measured with the
module placed on a uniform reflecting target with a known reflection density. However, the AMIS-710616-AS is not enclosed with its optical and light source
system. Therefore, Up is measured with uniform light source, which directly illuminates the image sensors’ photosite.
(6) Adjacent Pixel Non-uniformity: Upadj = MAX[ | (Vp(n) - Vp(n+l) | / Vp(n)] x 100%. Upadj is non-uniformity in percentage of Vpavg. It is the maximum difference
amplitude between two neighboring pixels.
(7) Bright output total non-uniformity: Uptotal = [Vpmax -Vpmin]/Vpavg
(8) Dark non-uniformity: Ud = Vdmax – Vdmin: It is measured over the full length of the array with the light source off and the sensors placed in the dark. Vdmax is
the maximum pixel value of the video pixel with the exposure off. Vdmin is the minimum pixel value of the video pixel with the exposure off. The references for
these levels are the dark level, VDL.
(9) Dark output voltage, VDL is the level between the out video pixel dark level and the ground.
(10) Random noise, RNL, is measured using two methods; one is to take the measurement tangentially on the scope. This measures an approximate peak-to-peak,
p-p, random thermal noise. The other method is in terms of rms. It is estimated by using Gaussian statistical methods. One pixel is selected out of a line scan
and its peak values are recorded for multiple line scans. These random peak values are used to estimate the rms values.
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AMIS-710616-AS: CIS PCB
Data Sheet
Product Specification
(11) Modulation transfer function depends on the optical system. Since this system relies on the users optical system, it was not measured. Referring back to Note
5, measurements on Up, all notes that reference the optical measurements apply to MTF measurements as well. Using a conservative engineering estimate,
the sensor’s MTF is in excess of 70 percent at the optical Nyquest frequency.
7.0 Electrical Timing Characteristics
7.1 Clock Amplitude and Duty Characteristics
Table 7-1: Clock Amplitude and Duty Characteristics
Item
Symbol
Condition
(1)
Clock input voltage
Clock input current
Clock frequency
Line read time
Clock pulse duty cycle
VIH
(1)
VIL
(1)
IIH
(1)
IIL
(2)
Freq
Tint
°
(Ta =25 C)
Min.
For values see
the notes
Specification
Typ.
Max.
See Note (1) for values
See Note (1) for values
0.100
5.0
6.0
MHz
160
192
1000
µs
25
50
75
%
(3)
Ratio = tw/ to
Units
(4)
Notes:
(1)
(2)
(3)
(4)
These CP and SP values are compatible with CMOS 74HCXX series logic devices.
Freq is not only the clock frequency, but is also equal to the pixel sample rate. See not 2 under Table 6.1.
Tint is the line scan read time, which depends on the interval between the SP entries. See Note 1 under Table 6.1. The longest integration time is determined
by the degree of leakage current degradation that can be tolerated by the system. A 10ms maximum is a typical rule-of-thumb. An experienced CIS user can
use his discretion to determine the desired tolerance level for the given system.
The definition for the symbols used in the ratio is defined in Section 7.2.
7.2 Clock Timing Characteristics
This table defines the symbols used in the timing diagram (Figure 3). It is for a single video section, however it applies to all eight video
sections. Accordingly, the system-timing diagram is a composition of this timing diagram repeated eight times, with all waveforms in
parallel, so electrically the system produces pixels from all eight video sections simultaneously.
Table 7-2: Clock Timing Characteristics
Item
(2)
Clock cycle time
(2)
Clock pulse width
(2)
Clock duty cycle
Prohibit crossing time of SP
Data setup time
Data hold time
Signal delay time
Signal sample time
Signal fall time
Recommended SP generation
Notes:
(1)
(2)
(3)
(4)
Symbol
to
tw
duty
tprh
tds
tdh
tdl
(3)
tsmp
tsigf
(4)
Tonoff
Min.
0.1666
25
30
30
25
Typ.
0.200
0.100
50
Max.
10
75
75
125
75
Units
µs
ns
%
ns
ns
ns
ns
ns
ns
This applies to the whole chart. All of the symbol definitions in Table 7-2 are used in Figure 3. For the complete system, there are only two clocks, CP and SP and
their logic levels are compatible with CMOS 74HCXX series logic devices.
See the notes on clock periods (the inverse of freq) and their duty cycles under Table 5-1 Notes 3 and 4.
See AMIS-720639 data sheet Page 6, Table 6A, Note 6.
This is the recommended method for SP generation because the shift register loads only on the falling edge.
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AMIS-710616-AS: CIS PCB
Data Sheet
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8.0 Maximum Ratings
Table 8-1: Maximum Ratings (Not to be Used for Continuous Operation)
Item
Symbol
DC supply voltage
VDD
Input voltage
(1)
Ambient temperature
(1)
Ambient humidity
(1)
Maximum operating case temperature
VIN
TA (PCB surface)
HA
PCB temperature
Specification
7V
Note
0 to VDD +0.3
°
0 to 70 C (see note below)
°
°
-10 to +75 C (see note below)
0 to 80% (see note below)
°
70 C (see note below)
SP & CP
Operational
storage
Non-condensing
Note:
(1)
All the referenced parameters are conservative engineering estimates based on a few of the prototypes’ PCB. They are based on measurements of similar CIS
modules and/or simple bench top tests using heat guns and freeze sprays. However, these parameters will be re-measured during the pilot production using
standard QA practices, which are under the control of ISO 9000 regulations.
9.0 I/O Connector Pin Configuration
There are two I/0 connectors on the stiffener plate with the two sensor boards. They are MOLEX 52610-1590. They serve to connect
the sensor boards to the amplifier boards (see the outline drawing of the system, Figure 2). Two 15 conductor strip lines serve as the
interfacing harness. It is depicted with harnesses coming from under the stiffener plate, crossing to the top of the amplifier board and
connecting to the two input connectors MOLEX 52207-1950. The final connectors are the two ERNI-594083s. They are the system
I/Os.
Only one of the two connectors on the stiffener board is specified because both connectors have identical pin-out definitions. There are
eight video taps, four from each sensor board and they are sequential re-numbered. The first sensor board video outputs are, 1, 2, 3
and 4. The second sensor board’s videos are 5, 6, 7 and 8.
9.1 Two MOLEX 52610-I590 and its Mate to Amplifier Boards MOLEX 52207-1590
Table 9-1: Sensor Board Connectors and Input Connectors for Amplifier Board Pin-outs
Pin Numbers
Pin Names
Symbols
I/0
Names and Functions
1
Clock pulse
CP
I
2
Start pulse
SP
I
3
Ground
GRD
I
Ground; 0V
4
Power supply
VDD
I
Positive power supply
5
Ground
GRD
I
Ground; 0V
6
Ground
GRD
I
Ground; 0V
7
Ground
GRD
I
Ground; 0V
8
Video output
VSEC1
O
Tapped 1 video output, Section 1 on Board 1; it is Section 5 on Board 2
9
Analog Ground
AGRD
I
Analog video return line, ground; 0V
10
Video output
VSEC2
O
Tapped 2 video output, Section 2 on Board 1; it is Section 6 on Board 2
11
Analog Ground
AGRD
I
Analog video return line, ground; 0V
12
Video output
VSEC3
O
Tapped 3 video output, Section 3 on Board 1; it is Section 7 on Board 2
13
Analog Ground
AGRD
I
Analog video return line, ground; 0V
14
Video output
VSEC4
O
Tapped 4 video output, Section 4 on Board 1; it is Section 8 on Board 2
5
Analog Ground
AGRD
I
Analog video return line, ground; 0V
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AMIS-710616-AS: CIS PCB
Data Sheet
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9.2 Amplifier Board Output Connectors, ERNI594083
There are four connectors on the amplifier board. Two are inputs, which are described above, and two are outputs, which are described
below. There is only one table shown for both connectors. They are both identical in their connections except that one is for the outputs
of Sensor Board 1 and the other is for the outputs of Sensor Board 2. Accordingly, each of the video outputs after amplification for both
sensor boards are labeled, VOUT1, VOUT2, VOUT3 and VOUT4. Videos from Sensor Board 1, VSEC1’s corresponding output is
VOUT1, VSEC2’s corresponding output is VOUT2, VSEC3’s corresponding output is VOUT3 and VSEC4’s corresponding output is
VOUT4. Then the videos from Sensor Board 2 will have their corresponding outputs on the second connector VOUT1, VOUT2, VOUT3
and VOUT4, except their outputs VOUT5, VOUT6, VOUT7 and VOUT8 because those video signals originate from Section 5, Section
6, Section 7 and Section 8 of Sensor Board 2.
Table 9-2: Amplifier Board Output Connectors, ERNI-594083
Pin Numbers
Description Row A
1
VDD
2
VDD
3
No connect
4
Ground
5
SP
6
No connect
7
No connect
8
No connect
9
CLK
10
GND
11
No connect
12
No connect
13
No connect
14
GND
15
No connect
16
VSS
Description Row B
VDD
VDD
No connect
Ground
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
No connect
VSS
Description Row C
AGND
VOUT1
AGND
AGND
AGND
VOUT2
AGND
AGND
AGND
VOUT3
AGND
AGND
AGND
VOUT4
AGND
AGND
Note: The functional description for the symbols used in Table 9-2 are the same as described for the input connector. The two new symbols VSS and CLK are as follows:
VSS is negative supply input. CLK is CP.
The locations of Pin 1 on all the connectors are facing the same end (see Figure 2).
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10.0 Block Diagrams - Figures 1, 2 and 3
Figure 1: Simplified Circuit Block Diagram
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Figure 2: System Configuration Block Diagram
Figure 3: Timing Diagram
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11.0 Schematic Diagram
Two reference schematic diagrams are attached to this document (Figure 4 and Figure 5). Only one schematic, CKT 1, Schematic
(Figure 1), is required to represent both the Sensor Board 1 and 2 because the circuits are identical. The second one is for the amplifier
board and it contains all eight of the amplifiers on one schematic. The circuit description of its structure and operation has been briefly
discussed in Section 1 of this document. Its operation follows from the discussion of the simplified block diagram. There are only two
input control clocks for the circuits, CP and SP. SP starts the shift register scanning while CP clocks the register and produces the
video pixels at its same rate. The clocks are entered through the I/O connectors on both sensor boards. They are both externally
buffered with the 74HC00 hexes and applied to the inputs of the image sensors. On each of the two-image array sensor boards there
are four sequential video sections. Each video section contains a row of five sequential image array sensors, AMIS-720639. These are
all clocks in parallel with CP. The four sections on both boards are clocked with SP in parallel, to initiate all eight video sections and
simultaneously begin the eight sequential readouts. All eight lines, four in each sensor board, have reset switches, BU4S66, which
parallel resets the video pixel charges after they are readout. These pixels, read out in parallel, are applied to their respective output
amplifiers on the amplifier board.
The second schematic, CKT 2, Amplifier Board Schematic (Figure 5), is the amplifier board. There are eight amplifiers for processing
the output videos from both sensor boards. The amplifier board receives the inputs from the sensor board output connector, J1, through
two harnesses. They are connected into the input I/O connectors, J1 and J2, of the amplifier board. Since there are two sensor boards
using the same schematic representation, the connector on Sensor Board 1, J1, becomes J2 for the second board. They are physically
differentiated and marked as J1 and J2 on the stiffener board. Since all eight sections process their video signals through identical
amplifiers, only one amplifier circuit is discussed. The AD8051 is an operational amplifier, which is configured into a non-inverting buffer
amplifier with a gain of ≅ 4.5. It is used to isolate the video line from its external circuits. The isolated video line then serves as a storage
capacitance for the pixels outputs. The pixel charges are read out onto the video line capacitance and integrated. This integrated pixel
charge, converted to a voltage pulse, is amplified and produced at the output I/O. The reset switch on the video line, which is located on
the sensor board schematic, resets the pixel signal charge prior to the readout of following pixel.
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11.1 Schematic Drawings; CKT 1 and CKT 2
Figure 4: CKT 1 - Sensor Board Schematic
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Figure 5: CKT 2 - Amplifier Board Schematic
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12.0 Drawing on Mechanical Structure
Attached are six mechanical drawings. The first drawing (Figure 6) shows an outline drawing of the complete CIS system, consisting of
the stiffener plate, the interconnecting harness and the amplifier board. There are two connector pin configuration tables, one is for the
two sensor boards and the input for the amplifier board and the other is for the two output connectors on the amplifier boards. These
two tables show the pin numbering and names for the six connectors that are seen in the drawing. For detailed descriptions of the
interconnections and their functions, see section 9.0.
The second drawing (Figure 7) shows the view of the stiffener board. The stiffener board is a ¼” aluminum backing plate on which the
two image sensor boards are mounted. The schematic drawing provides the dimensions of the plate, its access holes for the twosensor board’s connectors, along with all of the required dimensions.
The third drawing (Figure 8) shows a view of the two sensor boards mounted on the stiffener board. It shows the direction of the scan,
its first pixel location and its video read line location. It provides the dimensions on the connector height, the thickness of PCB board
and its component height.
The fourth drawing (Figure 9), is a backside view of the stiffener plate. It shows the location of the connectors and its pin order and
direction.
The fifth drawing (Figure 10) shows a view of the PCB outline. The three views of the board provide the outline dimensions, its length,
its width and its thickness. It also depicts the mounting holes and their dimensions and locations.
The six drawing (Figure 11), shows a view of the PCB with its connectors.
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1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
Pin
Description
Row A
VDD
VDD
No connect
GND
SP
No connect
No connect
No connect
CLK
GND
No connect
No connect
No connect
GND
No connect
VSS
Description
Row B
VDD
VDD
No connect
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
No connect
VSS
Description
Row C
Agnd
Vout 1
Agnd
Agnd
Agnd
Vout 2
Agnd
Agnd
Agnd
Vout 3
Agnd
Agnd
Agnd
Vout 4
Agnd
Agnd
Molex~52207-1590
ERNI~594083
ERNI~594083
Pin signal assignments : PIC version
Scan Direction
Molex~52610-1590
Description
CLK
SP
GND
VDD
GND
GND
GND
VSEC1
Agnd
VSEC2
Agnd
VSEC3
Agnd
VSEC4
Agnd
Pin
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
Pin
CLK
SP
GND
VDD
GND
GND
GND
VSEC1
Agnd
VSEC2
Agnd
VSEC3
Agnd
VSEC4
Agnd
Description
Molex~52610-1590
Molex~52207-1590
Pin signal assignments : Pin signal assignments :
Figure 6: Drawing 1 -Top Assemble Outline
1
Ingrid Chang
Ingrid Chang
7
PI616MC-AS
27-Nov-02
27-Nov-02
A1
NOTE:
1. No component may excede 5.08mm (0.200inch) from ether side of the board.
2. The ERNI~594083 connectors are exempt from this height limit.
3. 3.175mm (0.125inch) clearance around 6 mounting holes.
4. Dimensions are in millimeter.
Scan Direction
AMIS-710616-AS: CIS PCB
Data Sheet
Product Specification
12.1 Mechanical Drawings; Drawing 1, 2, 3, 4, 5 and 6
AMIS-710616-AS: CIS PCB
Data Sheet
2
6
Product Specification
Figure 7: Drawing 2 - Stiffner Plate
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AMI Semiconductor – July 06, M-20595-001
Figure 8: Drawing 3 - Two Sensor Board
15
(Connector Height)
Top Layer
(Sensor chip and
components side)
See SIDE
VIEW B.
Bottom Layer
(Connector side)
(Components Height)
Pin 1
See SIDE VIEW A.
Sensor Board 2
Sensor Board 1
Pin 15
Reading Line Specification :
(1) A1=5.00±0.2mm & A2=5.00±0.2mm.
(2) | A1-A2 | = ±0.4mm.
(3) Both (1) & (2) use the stiffner plate edge as the reference.
Scan Direction
Scan Direction
3
6
AMIS-710616-AS: CIS PCB
Data Sheet
Product Specification
AMIS-710616-AS: CIS PCB
Data Sheet
Scan Direction
Scan Direction
Sensor Board 2 at the back side
Scan Direction
Scan Direction
Figure 9: Drawing 4 - Connectors on Stiffner
AMI Semiconductor – July 06, M-20595-001
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6
4
(Pin 1 Location)
Sensor Board 1 at the back side
(Pin 1 Location)
Product Specification
16
AMIS-710616-AS: CIS PCB
Data Sheet
Figure 10: Drawing 5 - Amplifier Board
AMI Semiconductor – July 06, M-20595-001
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17
(PCB Thickness)
(PCB Thickness)
5
6
Product Specification
AMIS-710616-AS: CIS PCB
Data Sheet
Figure 11: Drawing 6 - Amplifier Board with Connectors
AMI Semiconductor – July 06, M-20595-001
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18
6
(PCB Thickness)
(PCB Thickness)
(ERNI~Connector Height)
6
Product Specification
AMIS-710616-AS: CIS PCB
Data Sheet
Product Specification
13.0 Company or Product Inquiries
For more information about AMI Semiconductor, our technology and our product, visit our Web site at: http://www.amis.com
North America
Tel: +1.208.233.4690
Fax: +1.208.234.6795
Europe
Tel: +32 (0) 55.33.22.11
Fax: +32 (0) 55.31.81.12
Production Technical Data - The information contained in this document applies to a product in production. AMI Semiconductor and its subsidiaries (“AMIS”) have made every effort to ensure
that the information is accurate and reliable. However, the characteristics and specifications of the product are subject to change without notice and the information is provided “AS IS” without
warranty of any kind (express or implied). Customers are advised to obtain the latest version of relevant information to verify that data being relied on is the most current and complete. AMIS
reserves the right to discontinue production and change specifications and prices at any time and without notice. Products sold by AMIS are covered by the warranty and patent
indemnification provisions appearing in its Terms of Sale only. AMIS makes no other warranty, express or implied, and disclaims the warranties of noninfringement, merchantability, or fitness
for a particular purpose. AMI Semiconductor's products are intended for use in ordinary commercial applications. These products are not designed, authorized, or warranted to be suitable for
use in life-support systems or other critical applications where malfunction may cause personal injury. Inclusion of AMIS products in such applications is understood to be fully at the
customer’s risk. Applications requiring extended temperature range, operation in unusual environmental conditions, or high reliability, such as military or medical life-support, are specifically
not recommended without additional processing by AMIS for such applications. Copyright © 2006 AMI Semiconductor, Inc.
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19