AMI PI6049A

REVISION NUMBER : REV 2
PAGES : 1 of 13
DATE : 2-13-04
PI6049A Contact Image Sensor
Data Sheet
PI6049A Data Sheet
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Key Features
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600 dots per inch (dpi)
344 image sensor elements (pixels)
42.3 µm pixel center-to-center spacing (23.62 dots/mm)
On-chip amplifier
Single 5.0V power supply
5.0V input clocks
2.5 MHz maximum pixel rate
Parallel / integrate and transfer
Power down circuit
High sensitivity
Low power
Low noise
General Description
Peripheral Imaging Corporation’s PI6049A Contact Image sensor is a 600 dpi resolution linear image sensor,
which employs PIC’s proprietary CMOS Image Sensing Technology. The sensor contains an on-chip output
amplifier, power down circuitry and parallel transfer features that are uniquely combined with present-day activepixel-sensor technology. The image sensors are designed to be cascaded end-to-end on a printed circuit board
(PCB) and packaged in an image sensing module. Applications for the sensor array includes facsimiles, PC
scanners, check readers, and office automation equipment.
Figure 1 is a block diagram of the sensor. Each sensor consists of 344 active pixels, their associated multiplexing
switches, buffers, and an output amplifier circuit with a power down feature. The detector’s element-to-element
spacing is approximately 42.3 µm. The size of each sensor without the scribe lines is 14560 µm by 380 µm.
14560µm
42.3µm
1
3
2
4
341
Row of 344 Pixels
and Video Line
Multiplexer
342
343
344
380µm
Parallel Transfer, Storage Cells and Readout Registers
Amplifier, PowerDown and Offset
Control
GBST
SI
SIC
CLK
AVDD DVDD AVSS DVSS
VOUT
Figure 1. Sensor Block Diagram
Page 2 of 13, Revised 2-13-04
OR
OS
VR
SO
PI6049A Data Sheet
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PI6049A Unique Features
There are five unique features incorporated in the PI6049A which improve the sensor’s performance.
1. Pixel-to-Pixel Offset Cancellation Circuit
The sensor employs a pixel-to-pixel offset cancellation circuit, which reduces the Fix Pattern Noise (FPN), and
amplifier offsets. In addition, this innovative circuit design greatly improves the optical linearity and low noise
sensitivity.
2. Parallel Integrate, Transfer and Hold
The sensor has a parallel integrate, transfer and hold feature, which allows the sensor to be read out while photon
integration is taking place. These features are approached through the use of an integrate and hold cell, located
at each pixel site. Each pixel’s charge is read from its storage site as the sensor’s shift register sequentially
transfers each pixel’s charge onto a common video line.
3. Dual Scan Initiation Inputs, GBST and SI
Each sensor has two scan initiation inputs, the Global Start Pulse (GBST) and the Start Pulse (SI). These clocks
help to reduce the sensor-to-sensor transition Fix Pattern Noise by initializing and preprocessing all sensors
simultaneously before they start their readout scan. The internal shift register starts the scan after GBST is
clocked in on the falling edge of the Clock input (CLK).
The Start Input Control (SIC) selects the first sensor in a sequence of cascaded sensors to operate with 29 clock
cycles of delay by connecting it to Vdd on the first sensor, and to Ground for all subsequent sensors. Then, only
the first sensor clocks out 29 inactive pixels before accessing its first active pixel. During these 29 clock cycles,
the first sensor and all of the subsequent cascaded sensors cycle through their pre-scan initialization process.
After initialization, only the first sensor starts its read cycle with its first-active pixel appearing on the 30th clock
cycle. The second and subsequent sensors await the entry of their Start Pulse (SI). Furthermore, the first sensor’s
Start Pulse (SI) is left unconnected, while the subsequent sensors all have their Start Pulse’s (SI) connected to
the SO of their respective preceding sensor. The external scan Start Pulse (SI) is connected to all of the sensors'
Global Start Pulse (GBST) inputs.
As the first sensor completes its scan, its End-of-Scan (SO), appears 1 pixel before its last pixel. The second and
subsequent sensors will then start their registers 1 clock cycle before the appearance of their respective first
pixels, and their SO also appears 1 pixel before their last pixel.
4. Power Saving
Each sensor incorporates a power-saving feature when multiple sensors are cascaded together to form a linear
imaging array. The Start Input Control (SIC) on each sensor selects a unique feature of powering up a particular
sensor’s output amplifier when it’s selected and powering it down when not selected. For the PI6049A, only the
first sensors’ amplifier is used and all subsequent sensors have their amplifiers turned off. The pixels from each
sensor are transferred onto a common video line which is connected to the amplifier of the first sensor. The
advantage of using only one active amplifier is two fold; saving on power consumption and reducing sensor-tosensor FPN.
5. Common Reference Voltage between Cascaded Sensors
Each sensor has an input/output bias control (VR), which serves as an offset voltage reference. Each bias control
pad is connected to an internal bias source and tied to its own amplifier’s reference bias input. In operation, these
pads on every sensor are connected together. Each sensor then “shares” the same bias level to maintain a
constant bias among all of the sensors.
Page 3 of 13, Revised 2-13-04
PI6049A Data Sheet
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Functional Description
¾ Input / Output Terminals
The PI6049A image sensor has 13 input and output (I/O) pads. Their symbols and function descriptions are listed
in Table 1.
Symbol
I/O
GBST
I
SI
I
SIC
I
CLK
I
AVDD
DVDD
AVSS
DVSS
I
I
I
I
VOUT
O
OR
OS
O
O
VR
I
SO
O
Description
Global Start Pulse:
Globally initializes the start inputs of all sensors and starts the scanning process of the
first sensor. (See discussion of the sensors unique features for further details).
Start Pulse:
Input to start a line scan. (See discussion of the sensors unique features for further
details).
Start Input Control:
Input to control the Start Pulse to the first sensor. (See discussion of the sensors unique
features for further details).
Clock:
Clock Input for the Shift Register.
Analog Power Supply.
Digital Power Supply.
Analog Signal Ground.
Digital Signal Ground.
Video Output Voltage:
Output Video Signal from the Amplifier.
Differential Reference Output.
Differential Video Output.
Reference Voltage: Reference input voltage for the Amplifier Output. Sets the Output’s
reset (dark) level
End of Scan Pulse:
Output from the Shift Register at the end of a scan.
Table 1. Input and Output Terminals
Page 4 of 13, Revised 2-13-04
PI6049A Data Sheet
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¾ Bonding Pad Layout Diagram
Figure 2 shows the bonding pad locations for the PI6049A sensor.
14560µm
380µm
Figure 2. Bonding Pad Locations
¾ Wafer Scribe Line
Figure 3 outlines the scribe line dimensions surrounding the sensor die on a wafer.
60µm
15µm
380µm
55µm
14560µm
60µm
Figure 3. Wafer Scribe Line
Page 5 of 13, Revised 2-13-04
55µm
PI6049A Data Sheet
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Electro-Optical Specifications
Table 2 lists the electro-optical specifications of the PI6049A sensor at 25oC and Vdd = 5.0 volts.
Parameter
Number of Pixels
Pixel-to-Pixel Spacing
Sensitivity (1)
Saturation Voltage (2)
Photo-Response Non-Uniformity (3)
Adjacent Photo-Response Non-Uniformity(4)
Dark Output Voltage Level (5)
Dark Output Non-Uniformity (6)
Random Thermal Noise (rms) (7)
Sensor-to-Sensor Photo-Response NonUniformity (8)
Photo Response Linearity (9)
Symbol
Min
344
42.3
Typical
Sv
Vsat
Up
Upn
Vd
Ud
Vno
Max
344
42.3
665
2.0
7.5
7.5
0.7
100
4
Units
µm
V / µJ / cm2
V
%
%
V
mV
mV
Usensor
7.5
%
PRL
2.0
%
Table 2. Electro-Optical Specifications
•
Notes for the above Table 2 are listed on the next page under “Definitions of Electro-Optical Specifications”.
Page 6 of 13, Revised 2-13-04
PI6049A Data Sheet
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Definitions of Electro-Optical Specifications
All electrical specifications are measured at a pixel rate of 2.0 MHz, a temperature of 25oC, Vdd=5.0 volts, and at
an integration time of 2.2ms. The average output voltage (Vpavg), is adjusted to approximately 1.0V, unless
stated otherwise. The modules’ internal Green LED (525 ± 20 nm) was used as the light source for
measurements requiring illumination. As a guideline, the recommended load on the output should be
1KΩ<RL<10kΩ. All measurements were taken with a 2k ohm load on the output.
1. Sensitivity (Sv) is defined as the slope of the Vpavg vs Exposure curve.
2. Saturation Voltage (VSat) is defined as the maximum video output voltage swing measured from the dark
level to the saturation level. It is measured by using the module LED light source with the module imaging a
uniform white target. The LED light level is increased until the output voltage no longer increases with an
increase in the LED brightness. The dark level is set by the voltage on VR and in a typical CIS module
application, sits at approximately 0.7V.
3. Photo-Response Non-Uniformity (Up).
Up = ((Vpmax-Vpavg)/Vpavg) x 100% or ((Vpavg-Vpmin)/Vpavg) x 100%, whichever is the greater, where
Vpmax is the maximum pixel output voltage in the light, Vpmin is the minimum pixel output voltage in the light
and Vpavg is average output voltage of all pixels in the light.
4. Adjacent Photo-Response Non-Uniformity (Upn).
Upn = Max ((Vpn – Vpn+1) / Min (Vpn, Vpn+1)) x 100%, where Vpn is the pixel output voltage of pixel n in the
light.
5. Dark Output Voltage (Vd).
Vd is the average dark output level and is essentially the offset level of the video output in the dark. The dark
level is set by the voltage on VR and in a typical CIS module application, sits at approximately 0.7V.
6. Dark Output Non-Uniformity (Ud).
Ud = Vdmax-Vdmin, where Vdmax is the maximum pixel output voltage in the dark and Vdmin is the minimum
pixel output voltage in the dark.
7. Random Thermal Noise (rms), (Vno), is the standard deviation of n pixels in the dark. A sample size n=64
was used. A 4 mV rms value has a peak-peak equivalent of 24 mV.
8. Sensor-to-Sensor Photo-Response Non-Uniformity (Usensor).
Usensor = (Vpavg – Wavg) / Wavg), where Wavg is the average output of all sensors on the same wafer that
pass all other specifications.
9. Photo-Response Linearity (PRL).
Photo-Response Linearity is defined as the max deviation of response compared to a best fit line. The data
points plotted are those that lie within 10% of the saturation level and 90% of the saturation level. Outside
these ranges the module is operating close to non-linearity.
Page 7 of 13, Revised 2-13-04
PI6049A Data Sheet
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Recommended Operating Conditions
Table 3 lists the recommended operating conditions @ 25oC.
Parameter
Power Supply
Clock Input Voltage high level (1)
Clock Input Voltage low level (1)
Power Supply Current
Reference Voltage (2)
Clock Frequency (3)
Pixel Rate
Integration Time (Line Scan Rate) (4)
First Die
Subsequent Die
Clock Pulse Duty Cycle (5)
Symbol
Vdd
IDD (sensor selected)
IDD (sensor not selected)
VR
Tint
Min
4.5
2.8
0
0.6
0.5
0.5
Typ
5.0
Vdd
0
3.2
2.6
0.7
2.0
2.0
Max
5.5
Vdd
0.8
5
4
1.1
2.5
2.5
Units
V
V
V
mA
mA
V
MHz
MHz
µs
µs / die
150
138
75
%
Table 3. Recommended Operating Conditions @ 25oC
Notes:
1. Applies to all clocks; GBST, SIC, SI and CLK.
2. The dark level is set by the voltage on the VR input pad, which is internally set to a typical value of 0.7 volts.
Alternatively, if the user wishes to use a dark level greater than this, then VR can be supplied externally.
3. Although the device will operate with a pixel rate of less than 500 KHz, it is recommended that the device be
operated above 500 KHz to maintain performance characteristics. Operating below 500 KHz may result in a
significant integration of dark current.
4. Tint is the integration time of a single sensor and is the time between two Start Pulses. The minimum
integration time is the time it takes to clock out 29 inactive pixels and 344 active pixels. If several sensors are
cascaded together in a module then the minimum integration time is the time it takes to clock out 29 inactive
pixels and 344 active pixels from the first sensor and 344 pixels from each of all subsequent sensors, at a
given frequency.
5. The clock duty cycle is defined as the ratio of the positive duration of the clock to its period.
Page 8 of 13, Revised 2-13-04
PI6049A Data Sheet
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Absolute Maximum Ratings
Table 4 lists the absolute maximum ratings.
Parameter
Power Supply Voltage (Vdd)
Clock Input Voltage high level (1)
Clock Input Voltage low level (1)
Operating Temperature
Operating Humidity
Storage Temperature
Storage Humidity
Max
10
Vdd + 0.5
-0.5
-10 to +50
+10 to +85
-25 to +75
+10 to +90
Table 4. Absolute Maximum Ratings
Note
1. Applies to all clocks; GBST, SIC, SI and CLK
Page 9 of 13, Revised 2-13-04
Units
V
V
V
°C
RH%
°C
RH%
PI6049A Data Sheet
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Timing Requirements
The timing requirements and their symbols are listed in Table 5 and its accompanying timing diagrams are shown
in Figures 4 and 5.
Parameter
Clock (CLK) Period
Clock (CLK) Pulse Width
Symbol
Min
Typ
Max
Units
CLKp
400
500
2000
ns
CLKpw
Clock (CLK) Duty Cycle
Data Setup Time
Data Hold Time
(1)
(1)
375
ns
75
%
Tset
20
ns
Thold
25
ns
Clock (CLK) rise time
(2)
CLKrt
70
ns
Clock (CLK) fall Time
(2)
CLKft
70
End of Scan Rise Time (2)
ns
SOrt
50
ns
End of Scan Fall Time
(2)
SOft
50
ns
Global Start Rise Time
(3)
GBSTrt
70
ns
GBSTft
70
ns
Global Start Fall Time
Pixel Rise Time
Pixel Fall Time
(4,5)
(4,5)
(3)
Prt
115
ns
Pft
75
ns
Table 5. Timing Requirements
Notes:
1. The shift register will load on all falling CLK edges, so setup and hold times (Tset, Thold) are needed to
prevent the loading of multiple start pulses. This would occur if the GBST remains high during two fallings
edges of the CLK signal.
2. SI starts the register scanning and the first active pixel is read out on the 30th clock cycle of the CLK signal.
However, when multiple sensors are sequentially scanned, as in CIS modules, the SO from the predecessor
sensor becomes the SI to the subsequent sensor, hence the SI clock = the SO clock.
3. As discussed under the third unique feature, the GBST starts the initialization process and preprocesses all
sensors simultaneously in the first 29 clock cycles (29 pixels) before the first pixel is scanned onto the video
line from the first sensor.
4. The transition between pixels does not always reach the dark offset level as shown in Figure 4 (Vout). Figure
4 shows the transition doing so for illustration purposes; however a stable pixel sampling point does exist for
every pixel.
5. The pixel rise time is defined as the time from when the CLK’s rising edge has reached 50% of its maximum
amplitude to the point when a pixel has reached 90% of its maximum amplitude. The pixel fall time is defined
as the time from when a pixel’s charge begins to decrease from its maximum amplitude to within 10% of the
lowest point before the next pixel begins to rise.
Page 10 of 13, Revised 2-13-04
PI6049A Data Sheet
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Figure 4 shows the initialization of the first sensor in relation to its subsequent cascaded sensors. The Start Input
Control (SIC) selects the first sensor to operate with 29 clock cycles of delay by connecting it to Vdd on the first
sensor and to Ground for all subsequent sensors. Hence the first sensor will operate with 29 inactive pixels being
clocked out before its first active pixel is clocked out. The rise and fall times are listed in table 5 above. The End of
Scan Pulse comes out in line with the second last active pixel, and the last active pixel of each sensor is the 344th
pixel which coincides with the 344th clock cycle.
GBST
Last pixel of preceding sensor
First pixel of succeding sensor
CLK
28
29
30
31
32
33
34
35
36
373
27
372
26
371
3
370
2
369
1
1
2
3
1
2
3
4
SO
6
7
5
344 Active Pixels (344 Clocks)
344
4
3
343
CLKpw
2
342
1
29 Inactive pixels (29 Clocks)
341
VOUT
CLKp
CLKpw
50%
CLK
Thold
CLKrt
CLKft
Tset
GBST
GRSTft
GRSTrt
prt
90%
pft
VOUT
10%
Figure 4. Overall Timing Diagram
CLK
Thold
1
Thold
2
29
30
31
32
Tset
GBST
Tset
Video Signal (Vout)
1
2
Figure 5. Timing of GBST-to-First Pixel of the First Sensor
Page 11 of 13, Revised 2-13-04
3
4
PI6049A Data Sheet
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PI6049A Image Sensors in a CIS Module
Figure 6 shows a partial schematic detailing how numerous image sensors are serially concatenated in a CIS
module. Since only the first sensor in the series of sensors is connected differently from the remaining sensors,
only the first three sensors are shown. Note OS and OR are used as internal monitors and are not connected to
the external module connector.
Figure 6. CIS Module with PI6049A Image Sensors
Page 12 of 13, Revised 2-13-04
PI6049A Data Sheet
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2004 Peripheral Imaging Corporation. Printed in USA. All rights reserved. Specifications are subject to change without
notice. Contents may not be reproduced in whole or in part without the express prior written permission of Peripheral
Imaging Corporation. Information furnished herein is believed to be accurate and reliable. However, no responsibility is
assumed by Peripheral Imaging Corporation for its use nor for any infringement of patents or other rights granted by
implication or otherwise under any patent or patent rights of Peripheral Imaging Corporation
Page 13 of 13, Revised 2-13-04