linear ccd image sensor

KLI-8023 IMAGE SENSOR
LINEAR CCD IMAGE SENSOR
JUNE 12, 2014
DEVICE PERFORMANCE SPECIFICATION
REVISION 1.1 PS-0052
KLI-8023 Image Sensor
TABLE OF CONTENTS
Summary Specification ......................................................................................................................................................................................... 5
Description .................................................................................................................................................................................................... 5
Features ......................................................................................................................................................................................................... 5
Applications .................................................................................................................................................................................................. 5
Ordering Information ............................................................................................................................................................................................ 6
Device Description ................................................................................................................................................................................................. 7
Dark Reference Pixels ............................................................................................................................................................................ 7
Dynamic Range ........................................................................................................................................................................................ 7
High Dynamic Range Mode (DR) .......................................................................................................................................................... 7
Image Acquisition ........................................................................................................................................................................................ 7
Charge Transport ......................................................................................................................................................................................... 8
Charge Transfer Efficiency .................................................................................................................................................................... 8
Dark Signal Evaluation ........................................................................................................................................................................... 8
Fixed Pattern Noise ................................................................................................................................................................................ 9
Exposure Control ..................................................................................................................................................................................... 9
Lag ............................................................................................................................................................................................................... 9
Imager Responsivity ............................................................................................................................................................................ 10
Linearity .................................................................................................................................................................................................. 10
Linearity Evaluation ............................................................................................................................................................................. 10
Modulation Transfer Function (MTF) .............................................................................................................................................. 10
Noise ........................................................................................................................................................................................................ 11
Noise Evaluation ................................................................................................................................................................................... 11
Photodiode Quantum Efficiency ...................................................................................................................................................... 12
Photoresponse Non-Uniformity (PRNU) ......................................................................................................................................... 12
Resolution .............................................................................................................................................................................................. 12
Saturation Voltage ............................................................................................................................................................................... 13
Smear ....................................................................................................................................................................................................... 13
Physical Description ................................................................................................................................................................................. 14
Pin Description and Device Orientation ......................................................................................................................................... 14
Imaging Performance .......................................................................................................................................................................................... 15
Typical Operational Conditions............................................................................................................................................................. 15
Specifications – High Dynamic Range Mode ...................................................................................................................................... 15
Specifications – Normal Mode ............................................................................................................................................................... 16
Typical Performance Curves ............................................................................................................................................................................ 17
Defective Pixel Classification ................................................................................................................................................................ 17
KLI-8023 Reference Design .................................................................................................................................................................... 21
Reference Design Circuit Overview .............................................................................................................................................................. 22
Programmable Logic ................................................................................................................................................................................ 22
Clock Drivers .............................................................................................................................................................................................. 22
Reset Driver ........................................................................................................................................................................................... 22
Exposure Control and Transfer Gates ............................................................................................................................................. 22
CCD Shift Register Driver ................................................................................................................................................................... 22
Bias Supplies .............................................................................................................................................................................................. 22
VDD, RD and OG ................................................................................................................................................................................... 22
OG, VSSR, VSSG, VSSB ......................................................................................................................................................................... 23
Output Buffers ...................................................................................................................................................................................... 23
Defect Definitions ................................................................................................................................................................................................ 24
Operationing Conditions ........................................................................................................................................................................ 24
Specifications............................................................................................................................................................................................. 24
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Operation .................................................................................................................................................................................................................. 25
Absolute Maximum Ratings ................................................................................................................................................................... 25
Device Input ESD Protection Circuit (schematic) ......................................................................................................................... 25
DC Bias Operating Conditions ............................................................................................................................................................... 26
AC Operating Conditions ........................................................................................................................................................................ 27
AC Electrical Characteristics – AC Timing Requirements ........................................................................................................... 27
AC Electrical Characteristics – Clock Level Conditions for Operation .................................................................................... 28
Clock Line Capacitance........................................................................................................................................................................ 28
Timing ......................................................................................................................................................................................................................... 29
Storage and Handling .......................................................................................................................................................................................... 30
Storage Conditions................................................................................................................................................................................... 30
ESD ............................................................................................................................................................................................................... 30
Cover Glass Care and Cleanliness ......................................................................................................................................................... 30
Environmental Exposure ........................................................................................................................................................................ 30
Soldering Recommendations ................................................................................................................................................................ 30
Mechanical Information ..................................................................................................................................................................................... 31
Completed Assembly ............................................................................................................................................................................... 31
Cover Glass ................................................................................................................................................................................................. 33
Quality Assurance and Reliability .................................................................................................................................................................. 34
Quality and Reliability ............................................................................................................................................................................. 34
Replacement .............................................................................................................................................................................................. 34
Liability of the Supplier ........................................................................................................................................................................... 34
Liability of the Customer ........................................................................................................................................................................ 34
Test Data Retention ................................................................................................................................................................................. 34
Mechanical.................................................................................................................................................................................................. 34
Life Support Applications Policy .................................................................................................................................................................... 34
Revision Changes................................................................................................................................................................................................... 35
MTD/PS-0219 ............................................................................................................................................................................................. 35
PS-0052 ....................................................................................................................................................................................................... 35
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KLI-8023 Image Sensor
TABLE OF FIGURES
Figure 1: Single Channel Schematic ........................................................................................................................................................... 7
Figure 2: KLI-8023 Pinout............................................................................................................................................................................14
Figure 3: Illustration of Defect Classifications ......................................................................................................................................17
Figure 4: KLI-8023 Typical Responsivity ..................................................................................................................................................17
Figure 5: KLI-8023 Typical Modulation Transfer Function ..................................................................................................................18
Figure 6: KLI-8023 (monochrome) Typical Quantum Efficiency (%) .................................................................................................18
Figure 7: KLI-8023 Smear - LDR Operation / 1 MHz / 35 °C ................................................................................................................19
Figure 8: Monochrome KLI-8023 Spectral Response ...........................................................................................................................19
Figure 9: KLI-8023 Typical Saturation Voltage vs. VRD .......................................................................................................................19
Figure 10: KLI-8023 Typical Dark Pixel Voltage Level vs. Temperature ..........................................................................................20
Figure 11: KLI-8023 Typical CCD Temperature Vs. Operating Frequency ......................................................................................20
Figure 12: KLI-8023 Typical Device Response Linearity .....................................................................................................................20
Figure 13: Reference Design ......................................................................................................................................................................21
Figure 14: Illustration of Defect Classifications ....................................................................................................................................24
Figure 15: ESD Circuit ..................................................................................................................................................................................25
Figure 16: Typical Output Bias/Buffer Circuit .......................................................................................................................................26
Figure 17: Line Timing .................................................................................................................................................................................29
Figure 18: Photodiode-to-CCD Transfer .................................................................................................................................................29
Figure 19: Output Timing............................................................................................................................................................................29
Figure 20: Completed Assembly Drawing (1 of 2) ................................................................................................................................31
Figure 21: Completed Assembly Drawing (2 of 2) ................................................................................................................................32
Figure 22: Two-Sided Multilayer Anti-Reflective Cover Glass Specification (MAR) .....................................................................33
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KLI-8023 Image Sensor
Summary Specification
KLI-8023 Image Sensor
DESCRIPTION
The KLI-8023 Image Sensor is a multispectral, linear solid
state image sensor for color scanning applications where
ultra-high resolution is required.
The imager consists of three parallel linear photodiode
arrays, each with 8000 active photosites for the output of
red, green, and blue (R, G, B) signals. This device offers
high sensitivity, high data rates, low noise and negligible
lag. Individual electronic exposure control for each color
allows the KLI-8023 sensor to be used under a variety of
illumination conditions. The imager can be operated in an
Extended Dynamic Range mode for the most demanding
applications.
FEATURES
Parameter
Typical Value
Architecture
3 Channel, RGB Trilinear CCD
Pixel Count
8002 x 3
Pixel Size
9 µm (H) x 9 µm (V)
Pixel Pitch
9 µm
Inter-Array Spacing
108 µm (12 lines effective)
Imager Size
72.0 mm (H) x 0.225 mm (V)
Saturation Signal
185 k electrons (Normal DR mode)
400 k electrons (Extended DR mode)

12 line spacing between color channels
Dynamic Range
(2 MHz Data Rate)
84 dB (Normal DR mode)
90 dB (Extended DR mode)

Single shift register per channel
Responsivity
(wavelength= 460, 540, 650 nm)
14, 17, 26 V/µJ/cm2

High offband spectral rejection
Output Sensitivity
14.4 µV/electron

Dark reference pixels provided
Dark Current
0.002 pA/pixel

Antireflective glass
Dark Current Doubling Rate
8 °C
Charge Transfer Efficiency
0.999998/Transfer
Photoresponse Non-uniformity
3% Peak-Peak
Lag (First Field)
0.025%
Maximum Data Rate
6 MHz/Channel
Package
CERDIP (Sidebrazed, CuW)

Wide dynamic range, low noise

Dual dynamic range mode operation

No image lag

Electronic exposure control

High charge transfer efficiency

Two-phase register clocking

74 ACT logic compatible clocks

6 MHz maximum data rate
Cover Glass
AR coated, 2 sides
Parameters above are specified at T = 25 °C (junction temperature) and
1 MHz clock rates unless otherwise noted.
APPLICATIONS

Digitization

Medical Imaging

Photography
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KLI-8023 Image Sensor
Ordering Information
Catalog Number
Product Name
Description
KLI- 8023-AAA-ED-AA
Monochrome, No Microlens, CERDIP Package (leadframe), Clear Cover
Glass with AR coating (both sides), Standard Grade
4H0617
KLI- 8023-AAA-ED-AE
Monochrome, No Microlens, CERDIP Package (leadframe), Clear Cover
Glass with AR coating (both sides), Engineering Sample
4H0615
KLI- 8023-DAA-ED-AA
Color (RGB), No Microlens, CERDIP Package (leadframe), Clear Cover
Glass with AR coating (both sides), Standard Grade
4H0618
KLI- 8023-DAA-ED-AE
Color (RGB), No Microlens, CERDIP Package (leadframe), Clear Cover
Glass with AR coating (both sides), Engineering Sample
4H0093
KEK-4H0093-KLI-8023-12-5
Evaluation Board (Complete Kit)
4H0614
Marking Code
KLI-8023-AAA
(Serial Number)
KLI-8023-DAA
(Serial Number
N/A
See Application Note Product Naming Convention for a full description of the naming convention used for image
sensors. For reference documentation, including information on evaluation kits, please visit our web site at
www.truesenseimaging.com.
Please address all inquiries and purchase orders to:
Truesense Imaging, Inc.
1964 Lake Avenue
Rochester, New York 14615
Phone: (585) 784-5500
E-mail: [email protected]
ON Semiconductor reserves the right to change any information contained herein without notice. All information
furnished by ON Semiconductor is believed to be accurate.
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KLI-8023 Image Sensor
Device Description
LS
LOGn
Photodiode Array 14 Test
TG1
IG
TG2
6 Blank
ID
CCD Cells
2A
8002 Active Pixels
16 Dark
RD
VDD
R
6 Blank
CCD Cells
FD
VIDn
OG
1A
1B
2B
SUB
VSSn
Figure 1: Single Channel Schematic
Dark Reference Pixels
Dark reference pixels are groups of photosensitive pixels covered by a metal light shield. These pixels are used as a
black level reference for the image sensor output. Since the incident light is blocked from entering these pixels, the
signal contained in these pixels is due only to dark current. It is assumed that each photosensitive pixel (active and dark
reference) will have approximately the same dark signal; thus, subtracting the average dark reference signal from each
active pixel signal will remove the background dark signal level. Dark reference pixels are typically located at one or
both ends of the arrays, as shown earlier in this document for a linear image sensor in the single channel schematic.
Dynamic Range
Dynamic Range (DR) is the ratio of the maximum output signal, or saturation level, of an image sensor to the dark noise
level of the imager. The dark noise level, or noise floor of an imager is typically expressed as the root mean square
(rms) variation in dark signal voltage. The dark signal includes components from dark current within the photosite and
CCD regions, reset transistor and output amplifier noise, and input clocking noise. An input referred noise signal in the
charge domain can be calculated by dividing the dark noise voltage by the imager charge-to-voltage conversion factor.
The dynamic range is typically expressed in units of decibels as: DR = 20 X LOG (Nsat/Noise).
High Dynamic Range Mode (DR)
Two modes of device operation can be realized, the ‘normal mode’ and ‘high dynamic range mode’. In ‘the normal
mode’ of operation, clocking of the output structure reset gate (PHIR, pin 12) remains similar to all other clocks at
6.25 Vp-p. The usable saturation exposure in this mode is approximately 180,000 electrons, yielding a saturation
voltage of 2.5 volts. In the ‘high dynamic range’ mode, the reset gate clocking is increased to 12 Vp-p and the reset
drain bias (RD, pin 29) is increased to the upper amplifier supply voltage (VDD, pin 26). The usable saturation exposure
in this mode increases to 400,000 electrons with a saturation voltage in excess of 5 volts.
IMAGE ACQUISITION
During the integration period, an image is obtained by gathering electrons generated by photons incident upon the
photodiodes. The charge collected in the photodiode array is a linear function of the local exposure. The charge is
stored in the photodiode itself and is isolated from the CCD shift registers during the integration period by the
transfer gates TG1 and TG2, which are held at barrier potentials. At the end of the integration period, the CCD register
clocking is stopped with the φ1 and φ2 gates being held in a 'high' and 'low' state respectively. Next, the TG gates are
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turned 'on' causing the charge to drain from the photodiode into the TG1 storage region. As TG1 is turned back 'off'
charge is transferred through TG2 and into the φ1 storage region. The TG2 gate is then turned 'off', isolating the shift
registers from the accumulation region once again. Complementary clocking of the φ1 and φ2 phases now resumes for
readout of the current line of data while the next line of data is integrated.
CHARGE TRANSPORT
Readout of the signal charge is accomplished by two-phase, complementary clocking of the φ1 and φ2 gates. The
register architecture has been designed for high speed clocking with minimal transport and output signal degradation,
while still maintaining low (6.25 Vp-p min) clock swings for reduced power dissipation, lower clock noise and simpler
driver design. The data in all registers is clocked simultaneously toward the output structures. The signal is then
transferred to the output structures in a parallel format at the falling edge of the φ2 clocks. Re-settable floating
diffusions are used for the charge-to-voltage conversion while source followers provide buffering to external
connections. The potential change on the floating diffusion is dependent on the amount of signal charge and is given
by ΔVFD = ΔQ/CFD, where ΔVFD is the change in potential of the floating diffusion, ΔQ is the amount of charge
deposited on the floating diffusion, and CFD is the floating diffusion capacitance. Prior to each pixel output, the
floating diffusion is returned to the RD level by the reset clock, φR.
Charge Transfer Efficiency
Charge Transfer Efficiency (CTE) is a measure of how efficiently electronic charge can be transported by a Charge
Coupled Device (CCD). This parameter is especially important in linear imager technology due to the fact that CCDs are
often required to transport charge packets over long distances at very high speeds. The result of poor CTE is to reduce
the overall MTF of the line image in a nonlinear fashion: the portion of the line image at the far end of the CCD will be
degraded more than the image at the output end of the CCD, since it will undergo more CCD transfers. There are many
possible mechanisms that can negatively influence the CTE. Amongst these mechanisms are included excessive CCD
clocking frequency, insufficient drive potential on the CCD clocking gates, and incorrect voltage bias on the output
gate (OG signal). The effect of these mechanisms is that some charge is "left behind" during a CCD transfer clocking
cycle. Depending on the limiting mechanism, the lost charge could be added to the immediate trailing cell or to a cell
further back in time; thus, causing a horizontal smearing of the line image.
The charge lost from a CCD cell, after being transferred out of the CCD, is measured with respect to the original charge
level and is termed the charge transfer inefficiency (CTI). CTI is defined as
(
)
The efficiency of the CCD transfer (CTE) is then defined as simply
Note that the total transfer efficiency for the entire line (TTE) is equal to (CTE)N, where N is the total number of
transfers which is equal to the number of phases per cell, times the number of cells (n).
Dark Signal Evaluation
The dark signal evaluation measures the thermally generated electronic current (i.e. background noise signal) at a
specific operating temperature. Dark current is measured will all incident radiation removed (i.e. imager is in the dark).
The current measured by the picoammeter is the dark current of the photodiode array plus the dark current of the CCD
array. Multiplying the dark current by the total integration time yields the quantity of dark charge. And dividing the
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dark current by the number of photodiodes yields the dark current per photodiode (I Dark). Dark voltage increases
linearly with integration time, the worst-case value occurs at the slowest clocking frequency. Additionally, dark current
doubles for approximately every 8 °C increase in temperature.
Fixed Pattern Noise
If the output of an image sensor under no illumination is viewed at high gain, a distinct non-uniform pattern or fixed
pattern noise can be seen. This fixed pattern can be removed from the video by subtracting the dark value of each
pixel from the pixel values read out in all subsequent frames. Dark fixed pattern noise is usually caused by variations in
dark current across an imager, but can also be caused by input clocking signals abruptly starting or stopping, or by
having the CCD clocks not being close compliments of each other. Mismatched CCD clocks can result in high
instantaneous substrate currents, which when combined with the fact that the silicon substrate has some non-zero
resistance, can result in the substrate potential bouncing. The pattern noise can also be seen when the imager is under
uniform illumination. An imager that exhibits a fixed pattern noise under uniform illumination and shows no pattern in
the dark is said to have light pattern noise or photosensitivity pattern noise. In addition to the reasons mentioned
above, light pattern noise can be caused by the imager entering saturation, the nonuniform clipping effect of the
antiblooming circuit, and by non-uniform photosensitive pixel areas often caused by debris covering portions of some
pixels.
Exposure Control
Exposure control is implemented by selectively clocking the LOG gates during portions of the scanning line time. By
applying a large enough positive bias to the LOG gate, the channel potential is increased to a level beyond the 'pinning
level' of the photodiode. (The 'pinning' level is the maximum channel potential that the photodiode can achieve and is
fixed by the doping levels of the structure.) With TG1 in an 'off' state and LOG strongly biased, all of the photocurrent
will be drawn off to the LS drain. Referring to the timing diagrams in Figure 13 and Figure 14, one notes that the
exposure can be controlled by pulsing the LOG gate to a 'high' level while TG1 is turning 'off' and then returning the
LOG gate to a 'low' bias level sometime during the line scan. The effective exposure (texp) is the net time between the
falling edge of the LOG gate and the falling edge of the TG1 gate (end of the line). Separate LOG connections for each
channel are provided, enabling on-chip light source and image spectral color balancing. As a cautionary note, the
switching transients of the LOG gates during line readout may inject an artifact at the sensor output. Rising edge
artifacts can be avoided by switching LOG during the photodiode-to-CCD transfer period, preferably during the TG1
falling edge. Depending on clocking speeds, the falling edge of the LOG should be synchronous with the φ1/φ2 shift
register readout clocks. For very fast applications, the falling edge of the LOG gate may be limited by on-chip RC delays
across the array. In this case artifacts may extend across one or more pixels. Correlated double sampling (CDS)
processing of the output waveform can remove the first order magnitude of such artifacts. In high dynamic range
applications, it may be advisable to limit the LOG fall times to minimize the current transients in the device substrate
and limit the magnitude of the artifact to an acceptable level.
Lag
Lag, or decay lag is a measure of the amount of photogenerated charge left behind during a photodiode-to-CCD
transfer cycle. Ideally, no charge is left behind during such transfers and lag is equal to zero; that is, 100% of the
collected photogenerated charge is transferred to the adjacent CCD. The use of "pinned" photodiode technology
enables the linear imagers to achieve near perfect lag performance. Improper Transfer Gate (TG) clocking levels can
introduce a lag type response. Thus, care must be taken to ensure that the clocking levels are not limiting the lag
performance.
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Imager Responsivity
Responsivity is a measure of the imager output when exposed to a given optical energy density. It is measured on
monochrome and color (if applicable) versions of an imager over the entire wavelength range of operation. Imagers
having multiple photodiode arrays with differing color filters and/or photodiode dimensions have responsivity
measured on each array. Responsivity is reported in units of
Linearity
The non-linearity of an image sensor is typically defined as the percent deviation from the ideal linear response, which
is defined by the line passing through V sat and Vdark. The percent linearity is then 100 minus the non-linearity. The
output linearity of a solid-state image sensor is determined from the linearity of the photon collection process, the
electron exposure structure nonlinearities (if any exists), the efficiency of charge transportation from the photosite to
the output amplifier, and the output amplifier linearity. The absorption of photons within the silicon substrate can be
considered an ideal linear function of incident illumination level when averaged over a given period of time. The
existence of an electronic exposure control circuit adjacent to the photosensitive sites can introduce a non-linearity
into the overall response by allowing small quantities of charge to remain isolated in unwanted potential wells.
Whether or not any potential wells exist depends on the design and manufacturing of the particular image sensor. The
existence of such potential wells in the exposure circuitry, also called exposure control defects, will degrade the
linearity only at small signal levels and may be different from one photosite to the next. An image sensor with
excessive exposure control defects would be rejected during quality assurance testing. The loss of charge during the
transportation of charge packets from the photosite to the CCD, which is termed lag, tends to affect the linearity only
at very small signal levels. "Pinned" photodiodes, or buried photodiodes, have extremely small lag (< 0.5%), and can be
considered to be lag free. The CCD charge transfer inefficiency (CTI) will reduce the amplitude of the charge packet as
it is transported towards the output amplifier, with the greatest effect realized at very small signal levels. Modern
CCD's have CTE in excess of 0.999999 per CCD transfer; thus, the overall effect on linearity is generally not a concern. If
biased properly, the output amplifier will yield a nonlinearity of typically less than 2%. Non linearity at signal levels
beyond the saturation level is expected and can often vary significantly from pixel to pixel.
Linearity Evaluation
Ideally, the output video amplitude should vary linearly with incident light intensity over the entire input range of
irradiance. There are many possible phenomena that can cause non-linearity in the response curve; inadequate CTE and
improper biasing or clocking to name a few.
Electronic exposure control could be used to vary the photodiode integration time; however, since electronic exposure
control can introduce non-linearity, it is not recommended as a method of limiting the input signal. The output signal
versus relative irradiance is graphed and a least squares, linear regression fit to the data is performed. The best fit data
2
curve should pass through zero volts and remain linear (R > 0.99) up to the Vsat level.
Modulation Transfer Function (MTF)
MTF is the magnitude of the spatial frequency response of a solid-state imager. The three main components of imager
MTF are termed the aperture MTF, diffusion MTF, and charge transfer efficiency MTF. The aperture MTF results from
the discrete sampling nature of solid-state imagers, with smaller pixel pitches yielding a better high frequency MTF
response. The diffusion of photogenerated charge degrades the imager response and is responsible for the second
component. The third component is due to inefficient charge transfer in the shift register. The maximum spatial
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frequency an imager can detect without aliasing occurring is defined as the Nyquist frequency and is equal to the
inverse of two times the pixel pitch. MTF is typically reported at the Nyquist frequency, 1/2 Nyquist, and 1/4 Nyquist.
The aperture MTF limits the maximum response at Nyquist to 0.637. (Note that the maximum MTF response is 1.0). The
diffusion component will further degrade this value, especially at longer optical wavelengths.
Noise
Noise is defined as any unwanted signal added to the imager output. Temporal noise sources present in a typical
imager include the dark current, photon shot noise, reset transistor noise, CCD clocking noise, and the output amplifier
noise. Dark current is dependent on the imager operating temperature and can be reduced by cooling the imager. The
reset transistor noise can be removed using correlated double sampling signal processing. The photon shot noise
cannot be eliminated; however, by acquiring and averaging several frames it, and all temporal noise sources, can be
reduced. Another source of noise is the variation in dark current from pixel to pixel leads to a dark noise pattern across
an imager. The effects of this dark pattern noise can also be minimized by averaging several frames and then using the
pixel-referenced, dark frame data as the zero reference level for each pixel.
Noise Evaluation
The noise evaluation measures the noise levels associated with operating the imager at the specified clocking speeds
and temperatures. The test is performed with imager temperature held stable and all incident light removed. The
noise contributions of the evaluation circuitry also need to be removed from the calculation. Once this is done, the
total imager noise will be approximately equal to the sum of squares of each of the CCD clocking noise, output
amplifier noise, and the dark current noise.
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Photodiode Quantum Efficiency
For a given area, absolute quantum efficiency is defined as the ratio of the number of photogenerated electrons
captured during an integration period to the number of impinging photons during that period. Higher values indicate a
more efficient photon conversion process and hence are more desirable.
Absolute photodiode quantum efficiency is calculated from the charge-to-voltage, imager responsivity, and measured
active photodiode area. It is calculated over the entire wavelength range of operation and graphed on a curve as
percent Quantum Efficiency versus Wavelength.
Once the charge-to-voltage, responsivity, and active photodiode dimensions have all been measured, the absolute
quantum efficiency can be calculated as:
where
and
Care should be taken to ensure that all quantities are represented in similar units before any calculations are
performed. Using the above formulas, the absolute quantum efficiency can be expressed as:
Photoresponse Non-Uniformity (PRNU)
The PRNU measurement is taken in a flat field of collimated white light. The intensity of the light is set to a value
approximately 10% to 20% below the saturated signal level. One region (or “window”) of pixels is observed for
uniformity at a given time, and the average response is calculated for each non-overlapping windowed section. In the
case of medium or low frequency PRNU measurements, a medium filter of 3-7 pixels is applied to this region to
eliminate the effects of single point defects. The maximum and minimum pixel is determined for each windowed
section. Again, for each section, the following formula is applied:
(
)
Each section is then compared against the specification to identify the region with the largest percent deviation from
the average response for the imager.
Resolution
The resolution of a solid-state image sensor is the spatial resolving power of that sensor. The spatial resolution
of a sensor is descried in the spatial frequency domain by the modulation transfer function (MTF). The discrete
sampling nature of solid-state image sensors gives rise to a sampling frequency that will determine the upper limit of
the sensor's frequency response. Resolution is frequently described in terms of the number of dots or photosites per
inch (DPI) in the imager or object planes. For example, a linear image sensor with a single array of 1000 photosites of
pitch 10 µm would have a resolution of 2540 DPI (1000 / (1000 x .01 mm x 1"/25.4 mm)). If the sensor were used in an
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optical system to image an 8" wide document, then the resolution in the document plane would be 125 DPI
(1000 pixels / 8"). This example is slightly misleading in that it does not consider the frequency response of the sensor
or the optics. In reality, the sensor will have an MTF of between 0.2 and 0.7 at the Nyquist spatial frequency and the
optics are likely to have an MTF of 0.6 to 0.9 at the Nyquist frequency. It is important to note that even though a sensor
may have a high enough sampling frequency for a particular application, the overall frequency response of the sensor
and optics may not be sufficient for that application!
Saturation Voltage
The saturated signal level is the output voltage corresponding to the maximum charge packet the imager can handle.
Adding charge above the saturated level results in the excess charge "spilling" over into neighboring photosites or CCD
structures. Either the photodiode capacity or the CCD capacity, with the latter being the most typical case, can limit
the charge capacity. The saturated signal level is measured by monitoring the dark-to-light transition between the
first-out dark reference pixels and the first active pixels while the irradiance is slowly increased. Note that improper
settings on either the output gate (OG) or the reset gate (φR) can have a clipping effect on the output waveform.
Smear
Smear, also referred to as Photodiode-to-CCD Crosstalk, occurs when photogenerated charge diffuses to an adjacent
CCD (such as a transfer register) and is collected, as opposed to being collected in the photodiode where the photon
absorption occurred. The result of smear is to increase the background signal within the dark reference pixels and CCD
buffer pixels. This increased background signal reduces the achievable dynamic range; hence, a high smear value is
undesirable. The further the photodiode array and the CCD are apart, the less the smear. Contributors to increased
smear are a short photodiode-to-CCD separation and improper transfer gate clocking levels or timing. Smear is also
highly dependent on incident photon wavelength. In the application, an IR cut-off filter (~710 nm) is recommended.
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KLI-8023 Image Sensor
PHYSICAL DESCRIPTION
Pin Description and Device Orientation
SUB
1
40
2A
2
39
1A
SUB
3
38
SUB
SUB
4
37
N/C
SUB
5
36
IG
LOGG
6
35
ID
LOGB
7
34
LOGR
SUB
LS
8
33
SUB
TG2
9
32
TG1
SUB
10
31
SUB
SUB
11
30
12
29
RD
13
28
OG
14
27
SUB
15
26
VDD
16
25
17
24
18
23
19
22
2B
20
21
SUB
R
VSSB
VIDB
SUB
VIDG
VSSG
SUB
1B
SUB
SUB
VIDR
VSSR
SUB
Figure 2: KLI-8023 Pinout
Pin
Name
Description
Pin
Name
Description
1
SUB
Substrate/Ground
40
SUB
Substrate/Ground
2
φ2n
Phase 2 CCD Clock (n = A or B)
39
φ1n
Phase 1 CCD Clock (n = A or B)
3
SUB
Substrate/Ground
38
SUB
Substrate/Ground
4
SUB
Substrate/Ground
37
SUB
Substrate/Ground
5
SUB
Substrate/Ground
36
IG
Test Input - Input Gate
6
LOGn
Exposure Control for Channel (n = R, G, B)
35
ID
Test Input - Input Diode
7
LOGn
Exposure Control for Channel (n = R, G, B)
34
LOGn
Exposure Control for Channel (n = R, G, B)
8
LS
Light Shield / Exposure Drain
33
SUB
Substrate/Ground
9
TG2
Transfer Gate 2 Clock
32
TG1
Transfer Gate 1
10
SUB
Substrate/Ground
31
SUB
Substrate/Ground
11
SUB
Substrate/Ground
30
SUB
Substrate/Ground
12
φR
Reset Clock
29
RD
Reset Drain
13
VSSn
Ground Reference (n = R, G, B)
28
OG
Output Gate
14
VIDn
Blue Output Video (n = R, G, B)
27
SUB
Substrate/Ground
15
SUB
Substrate/Ground
26
VDD
Amplifier Supply
16
VIDn
Blue Output Video (n = R, G, B)
25
VIDn
Blue Output Video (n = R, G, B)
17
VSSn
Ground Reference (n = R, G, B)
24
VSSn
Ground Reference (n = R, G, B)
18
SUB
Substrate/Ground
23
SUB
Substrate/Ground
19
φ1n
Phase 1 CCD Clock (n = A or b)
22
φ2n
Phase 2 CCD Clock (n = A or B)
20
SUB
Substrate/Ground
21
SUB
Substrate/Ground
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Revision 1.1 PS-0052 Pg 14
KLI-8023 Image Sensor
Imaging Performance
TYPICAL OPERATIONAL CONDITIONS
Specifications given under nominally specified operating conditions for the given mode of operation at 25 °C,
fCLK = 1 MHz, AR coverglass, color filters, and an active load as shown in Figure 3 unless otherwise specified. See notes
on next page for further descriptions.
SPECIFICATIONS – HIGH DYNAMIC RANGE MODE
VRD = 15 V, φR (High) = 12 V
Description
Saturation Output Voltage
Output Sensitivity
Saturation Signal Charge
Responsivity
(@ 450nm)
(@ 550nm)
(@ 650nm)
Dynamic Range
Dark Signal Non-Uniformity
Units
Notes
Verification
Plan
5.5
Vp-p
1, 9
die17
Vo/Ne
14
-
µV/e
design18
Ne,sat
400k
electrons
design18
R
14
19
28
V/µJ/cm2
DR
87
dB
DSNU
0.006
0.02
0.775
0.825
0.003
0.005
Symbol
Min.
Nom.
Vsat
5.2
DC Gain, amplifier
ADC
Dark Current
Idark
Charge Transfer Efficiency
Lag
DC Output Offset
Photoresponse Uniformity, Low Frequency
Photoresponse Uniformity, Medium
Frequency
Photoresponse Uniformity, High
Frequency
CTE, 
0.725
Max.
design18
3
design18
design18
V
design18
design18
pA/pixel
0.999995
L
2, 9, 10
± 10 %
± 10 %
± 10 %
5
die17
design18
0.003
0.06
%
11
13
Volts
9
design18
PRNU, Low
4
7
% p-p
6
die17
PRNU, Medium
4
7
% p-p
7
die17
PRNU, High
4
7
% p-p
8
die17
Vo,dc
8
Darkfield Defect, brightpoint
Dark Def
0
Allowed
12
die17
Brightfield Defect, dark or bright
Bfld Def
0
Allowed
13
die17
Exposure Control Defects
Exp Def
32
Allowed
11, 14, 15, 16
die17
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Revision 1.1 PS-0052 Pg 15
KLI-8023 Image Sensor
SPECIFICATIONS – NORMAL MODE
VRD= 11 V, φR(High) = 6.5 V
Description
Symbol
Min.
Nom.
Units
Notes
Verification Plan
Saturation Output Voltage
Vsat
2.3
2.6
Vp-p
1, 9
design18
Saturation Signal Charge
Nsat
200K
electrons
dB
3
design18
Volts
9
design18
Dynamic Range
DR
78
82
DC Output Offset
Vodc
5.5
7.75
Notes:
1.
2.
3.
4.
5.
6.
7.
8.
9.
10.
11.
12.
13.
14.
15.
16.
17.
18.
Max
10
design18
Defined as the maximum output level achievable before linearity or PRNU performance is degraded beyond specification
With color filter. Values specified at filter peaks. 50% bandwidth = ±30 nm. Color filter arrays become transparent after
710 nm. It is recommended that a suitable IR cut filter be used to maintain spectral balance and optimal MTF. See Figure 4.
As measured at 2 MHz data rate. This device utilizes 2-phase clocking for cancellation of driver displacement currents.
Symmetry between φ1 and φ2 phases must be maintained to minimize clock noise.
Dark current doubles approximately every +8 °C.
Measured per transfer. For the total line: (.999995) * 16044 = 0.9229.
Low frequency response is measured across the entire array with a 1000 pixel-moving window and a 5 pixel median filter
evaluated under a flat field illumination.
Medium frequency response is measured across the entire array with a 50 pixel-moving window and a 5 pixel median filter
evaluated under a flat field illumination.
High frequency response non-uniformity represents individual pixel defects evaluated under a flat field illumination. An
individual pixel value may deviate above or below the average response for the entire array. Zero individual defects
allowed per this specification.
Increasing the current load (nominally 4 mA) to improve signal bandwidth will decrease these parameters.
If resistive loads are used to set current, the amplifier gain will be reduced, thereby reducing the output sensitivity and net
responsivity. (e.g. with 2.2K Ohm loads to ground, the sensitivity drops to 12.5 microvolts per electron).
Defective pixels will be separated by at least one non-defective pixel within and across channels.
Pixels whose response is greater than the average response by the specified threshold, (16 mV). See Figure 3.
Pixels whose response is greater or less than the average response by the specified threshold, (±10%). See Figure 3.
Pixels whose response deviates from the average pixel response by the specified threshold, (4 mV), when operating in
exposure control mode. See Figure 3. If dark pattern correction is used with exposure control, the dark pattern acquisition
should be completed with exposure control actuated. Dark current tends to suppress the magnitude of these defects as
observed in typical applications, hence line rate changes may affect perceived defect magnitude. Note: Zero defects
allowed for those pixels whose response deviates from the average pixel response by a 20 mV threshold.
Defect coordinates are available upon request.
The quantity and type of defects acceptable for a specific application will be negotiated with each customer.
A parameter that is measured on every sensor during production testing.
A parameter that is quantified during the design verification activity.
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Revision 1.1 PS-0052 Pg 16
KLI-8023 Image Sensor
Typical Performance Curves
DEFECTIVE PIXEL CLASSIFICATION
Average
Pixel
Note 13: Bright
Field Bright Pixel
Note 14: Bright Field
Exposure Control
Bright Defect
Average
Pixel
Signal Out
Signal Out
Note 12: Dark Field
Bright pixel
Note 13: Bright
Field Dark Pixel
Note 14: Bright
Field Exposure
Control Dark
Defect
Exposure
Exposure
Figure 3: Illustration of Defect Classifications
35
Blue
Green
Red
Monochrome
Responsivity (V/uJ/cm^2)
30
25
20
15
10
5
0
350
400
450
500
550
600
650
700
750
800
850
900
Wavelength (nm)
Figure 4: KLI-8023 Typical Responsivity
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Revision 1.1 PS-0052 Pg 17
KLI-8023 Image Sensor
KLI-8013 (9um) Typical Modulation Transfer Function (MTF)
Unified Aperture and Two-Layer Diffusion Calculation Model
100
450 nm
95
550 nm
90
650 nm
85
750 nm
80
850 nm
75
70
65
MTF (%)
60
55
50
45
40
35
30
25
20
15
10
5
0
0
10
20
30
40
50
60
Spatial Frequency (cyc/mm)
Figure 5: KLI-8023 Typical Modulation Transfer Function
100%
90%
80%
70%
60%
50%
40%
30%
20%
10%
0%
350
450
550
650
750
850
Wavelength (nm)
Figure 6: KLI-8023 (monochrome) Typical Quantum Efficiency (%)
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Revision 1.1 PS-0052 Pg 18
KLI-8023 Image Sensor
0.4
0.35
Smear (%)
0.3
0.25
0.2
0.15
0.1
0.05
0
450
500
550
600
650
700
750
800
Wavelength (nm)
Figure 7: KLI-8023 Smear - LDR Operation / 1 MHz / 35 °C
Response
(V/uJ/cm^2)
30
25
20
15
10
5
0
350
450
550
650
750
850
Wavelength (nm)
Figure 8: Monochrome KLI-8023 Spectral Response
φRHIGH=12V
Vsat (Volts)
5.5
5
4.5
4
3.5
3
12
12.5
13
13.5
14
14.5
15
VRD (Volts)
Figure 9: KLI-8023 Typical Saturation Voltage vs. VRD
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Revision 1.1 PS-0052 Pg 19
KLI-8023 Image Sensor
Device Temp (degC)
70
60
50
40
30
20
10
0
0
50
100
Dark Voltage Level (mV)
150
200
Figure 10: KLI-8023 Typical Dark Pixel Voltage Level vs. Temperature
60
58
56
CCD Temperature
(Degrees C)
54
52
50
48
46
44
42
40
0
1
2
3
4
5
6
7
Pixel Frequency (MHz)
Figure 11: KLI-8023 Typical CCD Temperature vs. Operating Frequency
6
Sensor Output
Sensor Output [V]
5
Linear
4
3
2
1
0
0
0.5
1
1.5
2
2.5
Relative Light Level
Figure 12: KLI-8023 Typical Device Response Linearity
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Revision 1.1 PS-0052 Pg 20
KLI-8023 Image Sensor
KLI-8023 REFERENCE DESIGN
The KLI-8023 Reference Design provides a baseline reference for the design of a KLI-8023 image sensor into your
electronic imaging application. The circuit below uses inexpensive off-the-shelf components to provide
voltage-translated clock signals and DC bias supplies required to support the KLI-8023.
8
.1
.1
Ferrite Bead
+ 15V
100 uF
10 uF
LS
35
26
29
28
.1
24
1N914
or
eqiv
17
OG
VSSR
VSSG
.1
13
100
EL7202
RD
.1
.1
EL7202
+6.8 V
KLI-8023
IMAGE SENSOR
.1
820
10 K
+6.8 V
VDD
.1
.1 uF
18K
MASTER
OSCILLATOR
ID
VSSB
.1
9
100
32
TG2
TG1
+15 V
.1
EL7202
+6.8 V
100
34
6
25
VIDR
LOGR
LOGG
2N3904
180
100
Vout
RED
750
+6.8 V
74ACT11244
1/G
1A1
1A2
1A3
1A4
2/G
2A1
2A2
2A3
2A4
PLD
Rd
39
Rd
2
1Y1
1Y2
1Y3
1Y4
1A
+ 15V
.1
2Y1
2Y2
2Y3
2Y4
2A
VIDG
16
2N3904
180
+6.8 V
74ACT11244
1/G
1A1
1A2
1A3
1A4
2/G
2A1
2A2
2A3
2A4
1Y1
1Y2
1Y3
1Y4
Rd
19
Rd
22
1B
+15 V
2Y1
2Y2
2Y3
2Y4
.1
2B
VIDB
14
2N3904
180
+12.0V
750
12
.1
100K
Vout
BLUE
R
MPS577
1
100K
220pF
1N914A
220pF
1K
Vout
GREEN
750
IG SUB
36
33
1,3,10,11,15,18,20,21
,23,27,30,31,33,38,40
MPS3646
1N914A
Figure 13: Reference Design
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Revision 1.1 PS-0052 Pg 21
KLI-8023 Image Sensor
Reference Design Circuit Overview
PROGRAMMABLE LOGIC
See the timing waveform requirements earlier in this document before programming a logic device.
CLOCK DRIVERS
There are three types of clock drivers (voltage translating buffers) used in this reference design. The most important
performance consideration is the ability of the clock driver to drive the capacitive loads presented by the various gates
of the CCD.
Reset Driver
The RESET, (R), gate presents a small capacitive load of 100 pF, and requires fast rise and fall times. The
complimentary bipolar switching transistor circuit shown in Figure 13 provides a low cost solution. The circuit
alternately drives the PNP and NPN transistors into saturation, which switches the output between VCC and ground. A
33 - ohm series-damping resistor is used to suppress ringing.
Exposure Control and Transfer Gates
The exposure control gates; LOGR and LOGG, and the transfer gates; TG1 and TG2 each present a moderate capacitive
load of 500 pF. The Elantec 7202 Dual-Channel Power MOSFET driver delivers a peak output current of 2 amperes:
more than enough to meet the rise and fall requirements of the LOG and TG gates. Series damping resistors are used
to prevent ringing in the LOGR and LOGG gates. The transfer gates are connected together and driven by a single
EL7202.
CCD Shift Register Driver
The CCD clock phases (1A, 2A, 1B and 2B) present a significant load of 3100 pF per phase. Two 74ACT11244 octal
buffers provide an efficient solution. Each clock phase is driven by four gates connected in parallel to increase output
drive current. The 6.5-volt swing required by the shift register is obtained by setting VCC to 6.8 volts. Series damping
resistors Rd are used to suppress ringing of the clock signals. Values for Rd should be varied to eliminate ringing and
achieve 50% crossover between each pair of shift register clocks.
BIAS SUPPLIES
VDD, RD and OG
VDD and VRD are supplied directly from the 15 V input power supply and OG is supplied by a voltage divider. The input
power should be sufficiently filtered to prevent noise from coupling into the output stage of the KLI-8013 through the
VDD node. Current spikes in the VRD and VDD nodes, due to switching of the on-chip reset FET, are suppressed by the
addition of a 0.1 µF decoupling capacitor to ground at each node. The decoupling capacitors should be located as close
as possible to the pins of the CCD and should have a solid connection to ground. OG is also decoupled to suppress
voltage spikes the output gate of the device. The OG node draws negligible current.
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Revision 1.1 PS-0052 Pg 22
KLI-8023 Image Sensor
OG, VSSR, VSSG, VSSB
A forward-biased diode provides an inexpensive and reliable voltage source for all three VSS nodes. The switching
action of the reset FET of the output stage can cause voltage spikes to occur on the VSS nodes. A decoupling capacitor
located as close as practical to each VSS pin, and connected to a solid system ground, will minimize voltage spiking. In
high dynamic range systems, crosstalk between VSS channels might present a noise problem. A separate supply for
each of the three VSS nodes will minimize channel crosstalk if it proves to be a problem.
Output Buffers
An emitter follower circuit buffers each output channel. The emitter follower provides a high impedance load to the
on-chip source follower output stage, and provides low output impedance for driving the downstream analog signal
processing circuits. A 180-ohm resistor connected between the base and emitter of the emitter follower uses the
forward biased base to emitter voltage drop to provide a constant current load for the on-chip output stage.
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Revision 1.1 PS-0052 Pg 23
KLI-8023 Image Sensor
Defect Definitions
OPERATIONING CONDITIONS
Test conditions: T = 25 °C, fCLK = 1 MHz, tint = 8.054 msec
SPECIFICATIONS
Field
Dark
Defect Type
Threshold
Units
Notes
Number
0
Bright
16.0
mV
1, 2
Bright
Bright/Dark
10
%
1, 3
0
Bright
Exposure Control
4.0
mV
1, 4, 5
≤32
Notes:
1.
2.
3.
4.
5.
Defective pixels will be separated by at least one non-defective pixel within and across channels.
Pixels whose response is greater than the average response by the specified threshold. See Figure 14 below.
Pixels whose response is greater or less than the average response by the specified threshold. See Figure 14 below.
Pixels whose response deviates from the average pixel response by the specified threshold when operating in exposure
control mode. See Figure 14 below.
Defect coordinates are available upon request.
Average
Pixel
Note 3: Bright
Field Bright Pixel
Note 4: Bright Field
Exposure Control
Bright Defect
Note 3: Bright
Field Dark Pixel
Average
Pixel
Signal Out
Signal Out
Note 2: Dark Field
Bright pixel
Exposure
Note 4: Bright Field
Exposure Control
Dark Defect
Exposure
Figure 14: Illustration of Defect Classifications
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Revision 1.1 PS-0052 Pg 24
KLI-8023 Image Sensor
Operation
ABSOLUTE MAXIMUM RATINGS
Description
Symbol
Minimum
Maximum
Units
Notes
Gate Pin Voltages
VGATE
-0.5
+16
V
1, 2
Pin to Pin Voltage
VPIN-PIN
16
V
1, 3
Diode Pin Voltages
VDIODE
+16
V
1,4
Output Bias Current
IDD
-10
mA
5
Output Load Capacitance
CVID,LOAD
15
pF
CCD Clocking Frequency
fC
20
MHz
-0.5
6
Notes:
1.
2.
3.
4.
5.
Referenced to substrate voltage.
Includes pins: φ1n (n = A or B), φ2n (n = A or B), TG1, TG2, φR, OG, IG, and LOGn (n = R, G, B).
Voltage difference (either polarity) between any two pins.
Includes pins: VIDn, VSSn, RD, VDD, LS and ID (n = R, G, B).
Care must be taken not to short output pins to ground during operation as this may cause permanent damage to the
output structures.
6. Charge transfer efficiency will degrade at frequencies higher than the maximum clocking frequency. VIDn load resistor
values may need to be decreased as well.
7. Noise performance will degrade with increasing temperatures.
8. Long-term storage at the maximum temperature will accelerate color filter degradation.
9. Exceeding the upper limit on output load capacitance will greatly reduce the output frequency response. Thus, direct
probing of the output pins with conventional oscilloscope probes is not recommended.
10. The absolute maximum ratings for the entire table indicate the limits of this device beyond which damage may occur. The
Operating ratings indicate the conditions where the design should operate the device. Operating at or near these ratings
do not guarantee specific performance limits. Guaranteed specifications and test conditions are contained in the Imaging
Performance section.
Device Input ESD Protection Circuit (schematic)
T o Device
Function
I/O Pin
Vt - 20 V
SUB
Figure 15: ESD Circuit
CAUTION:
To allow for maximum performance, this device was designed with limited input protection; thus, it is sensitive to
electrostatic induced damage. These devices should be installed in accordance with strict ESD handling procedures!
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Revision 1.1 PS-0052 Pg 25
KLI-8023 Image Sensor
DC BIAS OPERATING CONDITIONS
Description
Symbol
Minimum
Nominal
Maximum
Units
Substrate
VSUB
-
0
-
V
Output Buffer Return
VVSS
0.5
0.65
0.75
V
Reset Drain Bias (Normal Mode)
VRD
10.5
11
11.5
V
Reset Drain Bias (High DR Mode)
VRD
14.5
VVDD
15.5
V
Output Buffer Supply
VVDD
14.5
15
15.5
V
Output Bias Current/Channel
IIDD
-8
-4
-2
mA
Output Gate Bias
VOG
0.5
0.65
0.75
V
Light Shield/Drain Bias
VLS
12
15
15.5
V
Test Pin – Input Gate
VIG
-
0
-
V
Test Pin – Input Diode
VID
12
15
15.5
V
Notes:
1.
Notes
1
A current sink must be supplied for each output. Load capacitance should be minimized so as not to limit bandwidth. Rx
serves as the load bias for the on-chip amplifiers. Values of Rx and RL should be chose to optimize performance for a given
operating frequency, but Rx should not be less than 75 Ohms. Figure 16 below shows one such solution.
VDD
2N2369
or Similar*
0.1 microF
To Device
Output Pin: VIDn
(Minimize Path Length)
Buffered Output
RX=180
Ohms *
RL=750 Ohms *
Figure 16: Typical Output Bias/Buffer Circuit
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Revision 1.1 PS-0052 Pg 26
KLI-8023 Image Sensor
AC OPERATING CONDITIONS
AC Electrical Characteristics – AC Timing Requirements
Description
CCD Element Duration
Symbol
Minimum
Nominal
Maximum
Units
Notes
1e ( = 1/fCLK )
167
1000
-
ns
1e count
H1A/B, H2A/B Rise Time
trise
20
100
-
ns
Line Integration Period
1L (=tint)
1.343
8054
-
ms
8054e counts
PD-CCD Transfer Period
Tpd
2666
16000
-
ns
16e counts
Transfer Gate 1 Clear
Ttg1
167
1000
-
ns
1e count
Transfer Gate 2 Clear
Ttg2
167
1000
-
ns
1e count
Charge Drain Duration
Tdr
1000
-
-
ns
3
Reset Pulse Duration
Trst
20
-
-
ns
1
Clamp to H2 Delay
Tcd
6
-
-
ns
2
Sample to Reset Edge Delay
Tsd
6
-
-
ns
2
Note:
1.
2.
3.
Minimum values given are for 6 MHz CCD operation.
Recommended delays for Correlated Double Sampling (CDS) for output.
Minimum value required to ensure proper operation, allowing for on-chip propagation delay.
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Revision 1.1 PS-0052 Pg 27
KLI-8023 Image Sensor
AC Electrical Characteristics – Clock Level Conditions for Operation
Description
Symbol
Minimum
Nominal
Maximum
Units
CCD Readout Clocks High (n = A or B)
VH1nH, VH2nH
6.25
6.5
7.0
V
CCD Readout Clocks Low (n = A or B)
Notes
VH1nL, VH2nL
-0.1
0.0
0.1
V
Transfer Clocks High (n = 1 or 2)
VTGnH
6.25
6.5
7.0
V
Transfer Clocks Low (n = 1 or 2)
VTGnL
-0.1
0.0
0.1
V
Reset Clock High (Normal Mode)
VφRH
6.25
6.5
7.0
V
Reset Clock High (High DR Mode)
VφRH
11.5
12.0
12.5
V
Reset Clock Low
VφRL
-0.1
0.0
0.1
V
1
Exposure Clocks High ( n = R, G, B)
VLOGnH
6.25
6.5
7.0
V
2
Exposure Clocks Low (n = R, G, B)
VLOGnL
-0.1
0.0
0.1
V
1, 2
Notes:
1.
2.
1
1
Care should be taken to insure that low rail overshoot does not exceed –0.5 VDC. Exceeding this value may result in
non-photogenerated charge being injected into the video signal.
Connect pin to ground potential for applications where exposure control is not required.
Clock Line Capacitance
Description
Symbol
Minimum
Nominal
Maximum
Units
Notes
Phase 1 Clock Capacitance
Cφ1
-
4180
-
pF
1
Phase 2 Clock Capacitance
Cφ2
-
2000
-
pF
1
Transfer Gate 1 Capacitance
CTG1
-
925
-
pF
Transfer Gate 2 Capacitance
CTG2
-
475
-
pF
Exposure Gate Capacitance
CLOG
-
190
-
pF
Reset Gate Capacitance
CφR
-
11
-
pF
Notes:
1.
This is the total load capacitance per CCD phase. Since the CCDs are driven from both ends of the sensor, the effective load
capacitance per drive pin is approximately half the value listed.
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Revision 1.1 PS-0052 Pg 28
KLI-8023 Image Sensor
Timing
1
2
6e
16e
2040e = ½ line
2040e = ½ line
16e
6
e
6e
24e
2040e = ½ line
2040e = ½ line
16e
6
e
tint
TG1
TG2
LOGn
(R,G,B)
texp
tdr
Figure 17: Line Timing
1
1e
2
First Dark Reference Pixel Data Valid
tpd
TG1
ttg1
TG2
ttg2
LOGn
(R,G,B)
tdr
Figure 18: Photodiode-to-CCD Transfer
1 el
2
tr
tcd
trst
R
VIDn
Vfeedthru
Vsat
Vdark
tsd
tclp
Clamp *
tspl
Sample *
* Required for Optional Off-Chip, Analog, Correlated Double Sampling (CDS) Signal Processing
Figure 19: Output Timing
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Revision 1.1 PS-0052 Pg 29
KLI-8023 Image Sensor
3. Improper cleaning of the cover glass may
damage these devices. Refer to Application
Note Image Sensor Handling Best Practices.
Storage and Handling
STORAGE CONDITIONS
Description
Symbol
Minimum
Maximum
Units
Notes
Operating
Temperature
Top
0
70
°C
1
Storage
Temperature
Tst
-25
+80
°C
2
Notes:
1.
2.
Noise performance will degrade with increasing
temperatures.
Long term storage at these temperatures will
accelerate color filter degradation.
ESD
1. This device contains limited protection against
Electrostatic Discharge (ESD). ESD events may
cause irreparable damage to a CCD image
sensor either immediately or well after the ESD
event occurred. Failure to protect the sensor
from electrostatic discharge may affect device
performance and reliability.
2. Devices should be handled in accordance with
strict ESD procedures for Class 0 (<250 V per
JESD22 Human Body Model test), or Class A
(<200 V JESD22 Machine Model test) devices.
Devices are shipped in static-safe containers
and should only be handled at static-safe
workstations.
3. See Application Note Image Sensor Handling
Best Practices for proper handling and
grounding procedures. This application note
also contains workplace recommendations to
minimize electrostatic discharge.
4. Store devices in containers made of electroconductive materials.
COVER GLASS CARE AND CLEANLINESS
1. The cover glass is highly susceptible to
particles and other contamination. Perform all
assembly operations in a clean environment.
2. Touching the cover glass must be avoided.
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ENVIRONMENTAL EXPOSURE
1. Extremely bright light can potentially harm
CCD image sensors. Do not expose to strong
sunlight for long periods of time, as the color
filters and/or microlenses may become
discolored. In addition, long time exposures to
a static high contrast scene should be avoided.
Localized changes in response may occur from
color filter/microlens aging. For Interline
devices, refer to Application Note Using
Interline CCD Image Sensors in High Intensity
Visible lighting Conditions.
2. Exposure to temperatures exceeding maximum
specified levels should be avoided for storage
and operation, as device performance and
reliability may be affected.
3. Avoid sudden temperature changes.
4. Exposure to excessive humidity may affect
device characteristics and may alter device
performance and reliability, and therefore
should be avoided.
5. Avoid storage of the product in the presence of
dust or corrosive agents or gases, as
deterioration of lead solderability may occur. It
is advised that the solderability of the device
leads be assessed after an extended period of
storage, over one year.
SOLDERING RECOMMENDATIONS
1. The soldering iron tip temperature is not to
exceed 370 °C. Higher temperatures may alter
device performance and reliability.
2. Flow soldering method is not recommended.
Solder dipping can cause damage to the glass
and harm the imaging capability of the device.
Recommended method is by partial heating
using a grounded 30 W soldering iron. Heat
each pin for less than 2 seconds duration.
Revision 1.1 PS-0052 Pg 30
KLI-8023 Image Sensor
Mechanical Information
COMPLETED ASSEMBLY
Figure 20: Completed Assembly Drawing (1 of 2)
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Revision 1.1 PS-0052 Pg 31
KLI-8023 Image Sensor
Figure 21: Completed Assembly Drawing (2 of 2)
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Revision 1.1 PS-0052 Pg 32
KLI-8023 Image Sensor
COVER GLASS
Maximum Reflectance Allowed (two sided)
2.40
2.20
Reflectance (%)
2.00
1.80
1.60
1.40
1.20
1.00
0.80
0.60
0.40
0.20
Reflectance (two sided)
0.00
400
450
500
550
600
650
700
Wavelength (nm)
Figure 22: Two-Sided Multilayer Anti-Reflective Cover Glass Specification (MAR)
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Revision 1.1 PS-0052 Pg 33
KLI-8023 Image Sensor
Quality Assurance and Reliability
QUALITY AND RELIABILITY
All image sensors conform to the specifications stated in this document. This is accomplished through a combination of
statistical process control and visual inspection and electrical testing at key points of the manufacturing process, using
industry standard methods. Information concerning the quality assurance and reliability testing procedures and results
are available from ON Semiconductor upon request. For further information refer to Application Note Quality and
Reliability.
REPLACEMENT
All devices are warranted against failure in accordance with the Terms of Sale. Devices that fail due to mechanical and
electrical damage caused by the customer will not be replaced.
LIABILITY OF THE SUPPLIER
A reject is defined as an image sensor that does not meet all of the specifications in this document upon receipt by the
customer. Product liability is limited to the cost of the defective item, as defined in the Terms of Sale.
LIABILITY OF THE CUSTOMER
Damage from mishandling (scratches or breakage), electrostatic discharge (ESD), or other electrical misuse of the
device beyond the stated operating or storage limits, which occurred after receipt of the sensor by the customer, shall
be the responsibility of the customer.
TEST DATA RETENTION
Image sensors shall have an identifying number traceable to a test data file. Test data shall be kept for a period of 2
years after date of delivery.
MECHANICAL
The device assembly drawing is provided as a reference.
ON Semiconductor reserves the right to change any information contained herein without notice. All information
furnished by ON Semiconductor is believed to be accurate.
Life Support Applications Policy
ON Semiconductor image sensors are not authorized for and should not be used within Life Support Systems without
the specific written consent of ON Semiconductor.
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Revision 1.1 PS-0052 Pg 34
KLI-8023 Image Sensor
Revision Changes
MTD/PS-0219
Revision Number
Description of Changes
1.0
 Initial Issue of Document
2.0
 Removed reference to notes 11 and 16 for Darkfield and Brightfield defects in table on page 3. These do not apply since
no defects allowed.
3.0
 Updated document format.
4.0
 Corrected Completed Assembly Drawings
PS-0052
Revision Number
Description of Changes
1.0
 Initial release with new document number, updated branding and document template
 Updated Storage and Handling and Quality Assurance and Reliability sections
1.1
 Updated branding
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© 2014, Semiconductor Components Industries, LLC.
Revision 1.1 PS-0052 Pg 35