AMI AMIS-710205-A4

AMIS-710205-A4/AMIS-710206-A4: 200dpi CIS Modules
Data Sheet
1.0 General Description
The AMIS-710205-A4 (PI205MC-A4-R) and AMIS-710206-A4 (PI206MC-A4-R) are a family of contact image sensor (CIS) modules. As
a family group they are called AMIS-710205/206 modules. They are long contact image sensor modules, using MOS image sensor
technology for high-speed performance and high sensitivity. They contain their own complete optical system including the light source;
accordingly, they make a very compact imaging system. The four parallel video outputs give this family of CIS modules their high speed
performance. They all possess identical electrical circuit components, as well as the same mechanical and optical components, except
for their LED light sources. They differ in their specification, however, because the different light sources impact the efficacy of the high
speed performance.
The two modules are suitable for scanning A4 size (216mm) documents with eight dots per millimeter (dpm) resolution. Applications
include document scanning, mark readers, gaming and office automation equipment.
2.0 Key Features
•
•
•
•
•
•
•
•
•
•
Light source, lens and sensor are integrated into a single module
Ultra high-speed
Four parallel analog video outputs clocked at 5.0MHz
90µsec/line scanning speed @ 5.0MHz clock rate with optional light sources, selected from the option of two above modules
8dpm resolution, 216mm scanning length
Wide dynamic range
LED light source (selectable among the two above modules)
Standard A4 size ≅ 14mm x 19mm x 232mm
Low power
Light weight
3.0 Functional Description
Each of the two modules in the family AMIS-710205/206 consists of four major components. The first of them is the printed circuit board
(PCB) on which the 27 imaging chips, AMIS-720233 (PI3033), are bonded. These sensor chips, produced by AMI Semiconductor, are
monolithic devices with 64 photo sensing elements. Each of 27 chips are completely self-contained scanning chips with their control
circuits integrated within the chips, so that they can be cascaded to provide a 1728 photo-elements module. The AMIS-720233 chips
are integrated with the photo sensors' associated multiplex switches, a digital shift register and the chip selection switch. The chip's shift
register sequentially clocks out the integrated image charges from each sensing element and passes them through the chip-select
switch and out onto the video line. The chip-select switches are sequentially switched as each of the predecessor chips completes its
scan. These 27 sensors, bonded on a PCB, are grouped into four sub-cascaded sections. Each contiguously cascaded chip section is
connected on separate video lines, providing four video outputs, VOUT1, VOUT2, VOUT3, and VOUT4. Before the signal charges from
the four video lines appear at their respective outputs, they are converted to signal voltages by four on-board buffer amplifiers; one for
each of its corresponding video section. The first three sections, VOUT1, VOUT2 and VOUT3 have seven sensor chips, while the
VOUT4 has six sensor chips. Since each sensor chip has 64 pixels, there are a total of 1728 pixels (see Figure 1).
Mounted in the module housing, along with the PCB, is the second major component. It is a one-to-one graded indexed micro lens
array, which focuses the image of the scanned documents onto the sensing line of the sensor chips. The third major component
mounted in the module is the LED light source (see Figure 2). This pictorial cross section shows the LED bar light source and its
illumination path as it reflects the image from the document and focuses through the ROD lens on to the image sensing line of the
sensing chips. All components are housed in a small plastic housing and covered with the fourth major component, a glass window.
This cover glass not only serves to protect all of the critical components within the housing from dust, but it also serves a minor role in
the optical system. Together with rest of the module's optical system, the module is adjusted to obtain the optimum depth-of-focus.
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AMIS-710205-A4/AMIS-710206-A4: 200dpi CIS Modules
Figure 1: AMIS-710205/206 Module Block Diagram (See Table 1 for Pin Out Designation)
Figure 2: AMIS-710205/206's Cross Section
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Data Sheet
AMIS-710205-A4/AMIS-710206-A4: 200dpi CIS Modules
Data Sheet
4.0 I/O Designation
I/O to the module is a 12-pin connector located on one end of the module (see Figure 5). Table 1 lists the pin numbers and their
designations for the I/O connector. It is an ECE manufacturer EBW-PK23-P012L2-3Z connector.
Table 1: Pin Configuration
Pin Number
1
2
3
4
5
6
7
8
9
10
11
12
Symbol
VOUT1
VOUT2
GND
VOUT3
VOUT4
Vdd
SP (START)
GND
CP (CLOCK)
Vn
GLED
VLED
Names and Functions
Analog video output 1
Analog video output 2
Ground; 0V
Analog video output 3
Analog video output 4
Positive power supply
Shift register start pulse
Ground; 0V
Sampling clock pulse
Negative power supply
Ground for the light source; 0V
Supply for the light source
5.0 Module vs. LED Light Source
Table 2 lists the module's model and its corresponding LED light source.
Table 2: Module vs. LED Light Source
Module
AMIS-710205-A4
AMIS-710206-A4
LED Light Source
880nm IR SMD LED bar
630nm Red SMD LED bar
6.0 Absolute Maximum Rating
Table 3 shows the absolute maximum ratings. The parameters are common to all the modules. Table 4 shows the absolute maximum
ratings that are different among the three modules.
Table 3: Electrical Absolute Maximum Rating
Parameter
Symbols
Power supply
Vdd
Idd
Vn
In
Input clock pulse (high level)
Vih
Input clock pulse (low level)
Vil
Maximum Rating
7
100
-15
35
Vdd – 0.5V
-0.5
Units
V
ma
V
ma
V
V
Note: These parameters are absolute maximums. Do not operate under these conditions.
Table 4: LED Power Absolute Maximum Rating
Parameter
Symbols
Power supply: LED light source
Module
VLED
ILED
Maximum Rating
AMIS-710205-A4
AMIS-710206-A4
6.0
6.0
0.6
0.6
Note: These parameters are absolute maximums. Do not operate under these conditions.
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Units
V
A
AMIS-710205-A4/AMIS-710206-A4: 200dpi CIS Modules
Data Sheet
7.0 Environmental Specifications
Table 5: Operating and Storage Environment
Parameter
Symbols
(1)
Operating temperature
Top
(1)
Operating humidity
Hop
(1)
Storage temperature
Tstg
(1)
Storage humidity
Hstg
Range
0 to 50
10 to 90
-20 to +75
10 to 90
Units
°
C
%
°
C
%
Note:
(1)
These are standard specifications for the CIS modules.
8.0 Electro-Optical Characteristics (25°C)
Table 6 is the electro-optical characteristics common to all three modules. Table 7 shows the characteristics for each of the two LED
light sources.
Table 6: Common Electro-Optical Characteristics
Parameter
Total number of photo detectors
Section 1, 2 & 3 number of photo
detectors
Section 4 number of detectors
Pixel-to-pixel spacing
Symbol
Table 7: AMIS-710205/206-A4 Electro-Optical Characteristics
AMIS-710205-A4
AMIS-710206-A4
Parameter
Symbol
(1)
Line scanning rate
Tint
(2)
Clock frequency
(3)
Bright output voltage
(4)
Bright output non-uniformity
(5)
Dark non-uniformity
(6)
Dark output voltage
(7)
Modulation transfer function
Notes:
(1)
(2)
(3)
(4)
(5)
(6)
Value
1728
448
Units
Elements
Elements
384
125
Elements
µm
IR LED (880nm)
Red LED (630nm)
Value
90
Fclk
Video output
Up
Ud
Dark level (DL)
MTF
5.0
1.0
<+/-30
<40
<200
>40
Units
µsec
MHz
Volt
%
mV
mV
%
Tint is the line scanning rate or integration time. Tint is determined by the interval between two start pulses (SP).
Fclk: main clock frequency also equals the video sampling frequency.
Video output level is controlled with a voltage adjustment as well as the Integration time and the LED light power.
Up = {[Vp(max) –Vp(min)]/Vp(max)}x100%
Where Vp(max) = maximum peak pixel and Vp(min) = minimum pixel.
Ud = Vdmax – Vdmin
Vdmin is the minimum output voltage with the LED off.
Vdmax is maximum output voltage with the LED on.
See Section.9.0.
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Notes
Note
@ 5.0MHz clock
frequency
AMIS-710205-A4/AMIS-710206-A4: 200dpi CIS Modules
Data Sheet
9.0 Reset Level and Video Sampling Time
Figure 3: Video Pixel Definition
Figure 3 graphically shows the video signal waveform and defines the single video pixel structure. The signal output waveform is shown
relative to the input clock waveform, as well as the symbols and terminologies used to define the performance specifications. Figure 3
explains the terminology used to characterize the dark signal levels and the recommended video pixel sampling times.
Note 6, under Table 7, specifies the dark level (DL). This is the level seen during the dark read out; for example, either the module sits
on a black target or the light source is turned off. It is measured from ground or 0V. The reset level is a reference level for the reset
switch, which is not necessarily on ground because after the reset occurs, the signal is passed through an amplifier. The difference
between the dark level and the reset level is called the pedestal (PED). In most cases, the offset control of the amplifier is used to
adjust the dark level to 0V or ground. Hence, the reset level will sit below ground.
The video pixels demonstrated in this graph emanate from an ideal CIS module with a phototransistor imaging structure. The video
output at high speeds, such as 5.0MHz, does not instantly rise to its final value, although given enough time; it would asymptotically
approach its steady state value. But, at high speeds it is impractical to wait for the final stable value. Accordingly, as Figure 3 indicates,
the output signal continues to rise towards its steady state value. Consistent with the forgoing comments, under Table 7, instead of the
conventional signal sampling time, tst is defined to substitute the conventional settling time definition. This definition is used because
the output signal continues to rise asymptotically to the final stable value but not within a practical time in high speed applications. This
is true even when the video rises to its peak value, Vp, defined in the algorithm used in the measurements described by the following
equation:
MTF={[Vp(n)+Vp(n+1)]/2-[Vp(n+2)+Vp(n+3)]/2}/{[Vp(n)+Vp(n+1)]/2+[Vp(n+2)+Vp(n+3)]/2}
th
th
Where n is 1, 2, .....1728 , Vp(n) is the signal amplitude of the n pixel.
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AMIS-710205-A4/AMIS-710206-A4: 200dpi CIS Modules
Data Sheet
10.0 Operating Conditions (25°C)
°
Table 8: Recommended Operating Conditions (25 C)
Item
Symbol
Min.
Power supply
Vdd (positive)
4.5
Vn (negative)
-10
Idd (positive)
60
(1)
In (negative)
20
Input voltage at digital high
Vih
Vdd-1.0
Input voltage at digital low
Vil
0
(2)
Clock frequency
Fclk
0.2
Clock pulse high duty cycle
Clock pulse high duration
45.5
Integration time
Tint
82
(4)
Operating temperature
Top
AMIS-710205-A4
Parameter
Min.
Typ.
VLED
5.0
ILED
480
AMIS-710206-A4
Min.
Typ.
VLED
5.0
ILED
480
Notes:
(1)
(2)
(3)
(4)
Typ.
5.0
-5
66
20
Vdd-0.5
25
50
150
25
Max.
5.5
-4.0
75
20
Vdd
0.6
(3)
5.5
Units
V
V
ma
ma
V
V
MHz
%
ns
µs
°
C
50
Max.
5.5
550
V
ma
Max.
5.5
550
V
ma
Current is essential constant current with supply voltage.
This is determined by the longest tolerable integration time. Because of leakage current build up, the integration time is recommended to be no greater than 10ms.
The maximum call out is for the modules' electrical speed. The light source still dictates the highest speed performance.
This specification is a standard used by the CIS makers for the fax industry.
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AMIS-710205-A4/AMIS-710206-A4: 200dpi CIS Modules
Data Sheet
11.0 Switching Characteristics (25°C)
The switching characteristics at 25°C for the I/O clocks are shown in Figure 4. Each switch timing characteristic for each waveform is
represented by its symbolic acronym. Each corresponding switching time is defined in Table 9.
Figure 4: Module Timing Diagram
Note: Only one video output is shown because all four videos have identical electrical characteristics. The only physical difference between the outputs is in the Section 4
output, VOUT4. Section 4 has only six sensor chips; hence, its active scan is shorter by 64 pixels (see Figure 4).
Table 9: Timing Symbol’s Definitions and Timing Values
Item
Symbol
Clock cycle time
to
Clock pulse width
tw
Clock duty cycle
Prohibit crossing time of Start
tprh
(1)
Pulse
Data setup time
tds
Data hold time
tdh
Signal delay time
tdl
Signal settling time
tsh
Min.
0.20
50
25
0
Typ.
Max.
4.0
75
20
0
20
100
Units
µs
ns
%
ns
ns
ns
ns
ns
Note:
(1)
"Prohibit crossing of start pulse" is used to indicate that the start pulse should not be active high between any two consecutive clock pulses; specifically, between
two consecutive low going clock pulses (see the Figure 4). All falling clock edges under an active high start pulse load the internal shift register, therefore the start
pulse must be active over only one falling clock edge. A high start pulse over all rising clock edges is ignored by the shift register. One simple way to ensure that
the start pulse will not be actively high during two consecutive falling clock edges is to generate the start pulse on a rising clock edge and terminate it on the
following rising clock edge.
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AMIS-710205-A4/AMIS-710206-A4: 200dpi CIS Modules
Data Sheet
12.0 Mechanical Drawing of the Module
Figure 5 depicts the isometric sketch of the module housing, showing the connector location, the approximate overall dimensions of the
module and its general geometric layout. It is not intended for use as a design reference. Detailed drawings for the AMIS-710205/206
modules are available upon request.
Figure 5: AMIS-710205/206 Module Mechanical Overview
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AMIS-710205-A4/AMIS-710206-A4: 200dpi CIS Modules
Data Sheet
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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