ON NOIM1SM9600A-QDC Mano 9600 9.6 megapixel rolling shutter cmos image sensor Datasheet

NOIM1SM9600A,
NOIM2SM9600A
Advance Information
MANO 9600 9.6 MegaPixel
Rolling Shutter CMOS
Image Sensor
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Features
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9.6 MegaPixel Resolution in 3840 × 2500 Format
2.4 mm × 2.4 mm Square Pixels (Shared 4T Pixel Architecture)
2/3 inch Optical Format
Monochrome (SM) Version
20 Frames per Second (fps) at Full Resolution
200 mW / 500 mW Power Consumption at 5 fps / 20 fps
Four Low−Voltage Differential Signaling (LVDS) High Speed Serial
Outputs or One 10−bit CMOS Output
On-chip 10-bit Analog-to-Digital Converter (ADC)
Windowing to Attain Higher Frame Rate
Rolling Shutter
On-chip Fixed Pattern Noise (FPN) Correction
Serial Peripheral Interface (SPI)
Automatic Exposure Control (AEC)
Phase Locked Loop (PLL)
Figure 1. MANO 9600 Package Photograph
High Dynamic Range (HDR)
Dual Power Supply (1.8 V and 3.3 V)
Applications
0°C to 70°C Operational Temperature Range
• Biometrics (Fingerprinting)
52-pin LCC
• Machine Vision
500 mW Power Dissipation (LVDS)
• Inspection
200 mW Power Dissipation (CMOS)
• Microscopy
These Devices are Pb−Free and are RoHS Compliant
Description
The MANO9600 is a rolling shutter CMOS image sensor with a resolution of 3840 x 2500 pixels.
The high sensitivity 2.4 mm x 2.4 mm pixels supports correlated double sampling readout reducing noise and increasing
dynamic range.
A high level of programmability using a four wire serial peripheral interface enables the user to read out specific regions
of interest.
Higher frame rates are achieved with region of interest or sub−sampled readout modes. The sensor has built−in features for
bias control and power supply regulation.
The sensor has on−chip programmable gain amplifiers and 10−bit A/D converters. The integration time and gain parameters
can be reconfigured without any visible image artifact. Optionally the on−chip automatic exposure control loop (AEC) controls
these parameters dynamically. The image’s black level is either calibrated automatically or can be adjusted by adding a user
programmable offset.
The image data interface of the M1−SM part consists of four LVDS lanes running at 620 Mbps, facilitating frame rates up
to 20 frames per second. A separate synchronization and clock channel containing payload information is provided to facilitate
the image reconstruction at the receive end. The M2−SM part provides a parallel CMOS output interface at reduced frame rate
of 5 frames per second.
The MANO 9600 is packaged in a 52−pin LCC package and is available in a monochrome without micro lens.
Contact your local ON Semiconductor office for more information.
This document contains information on a new product. Specifications and information herein are subject to change without notice.
© Semiconductor Components Industries, LLC, 2014
February, 2014 − Rev. P0
1
Publication Order Number:
NOIM1SM9600A/D
NOIM1SM9600A, NOIM2SM9600A
ORDERING INFORMATION
Part Number
Description
NOIM1SM9600A-QDC
LVDS Interface mono
NOIM2SM9600A-QDC
CMOS Interface mono
Package
52−pin LCC package
The M1-SM base part is used to reference the mono version of the LVDS interface; the M2-SM base part is used to reference
the mono version of the CMOS interface.
NOTE: The MANO 9600 does not utilize a micro lens.
ORDERING CODE DEFINITION
N O I M1 S M 9600 A − Q D C
ON Semiconductor
Opto
Image Sensors
Commercial Temperature Range
D = D263 Glass
M1: MANO LVDS
M2: MANO CMOS
Package Q = LCC
Additional Functionality
S: Standard Process
9.6 MegaPixel Resolution
M = Mono (no microlens)
PACKAGE MARK
Following is the mark on the bottom side of the package with Pin 1 to the left center
Line 1: NOI xx SM9600A where xx denotes LVDS (M1) / CMOS (M2)
Line 2: -QDC
Line 3: AWLYYWW; where line 3 is the lot traceability as shown below
XXXXX
A
WL
YY
WW
NNNN
= Specific Device Code
= Assembly Location
= Wafer Lot
= Year
= Work Week
= Serial Number
Figure 2. Generic Package Mark
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NOIM1SM9600A, NOIM2SM9600A
CONTENTS
Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
Applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
Ordering Information . . . . . . . . . . . . . . . . . . . . . . . . . 2
Ordering Code Definition . . . . . . . . . . . . . . . . . . . . . . 2
Package Mark . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2
Contents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3
Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
Operating Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
Sensor Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
Additional Features . . . . . . . . . . . . . . . . . . . . . . . . . . .
Data Output Format . . . . . . . . . . . . . . . . . . . . . . . . . .
Register Map . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Package Information . . . . . . . . . . . . . . . . . . . . . . . . . .
Glass Lid . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Handling Precautions . . . . . . . . . . . . . . . . . . . . . . . . .
Limited Warranty . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Specifications and User References . . . . . . . . . . . . . .
Acronyms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Glossary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
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25
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44
56
62
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64
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NOIM1SM9600A, NOIM2SM9600A
SPECIFICATIONS
Key Specifications
Table 2. ELECTRO−OPTICAL SPECIFICATIONS
Table 1. GENERAL SPECIFICATIONS
Parameter
Specification
Parameter
Active pixels
3840 x 2500
Pixel size
2.4 mm x 2.4 mm
(Shared 4T pixel architecture)
Shutter type
Rolling shutter
Master clock
M1-SM:
62 MHz when PLL is used,
310 MHz (10-bit) / 248 MHz (8-bit)
when PLL is not used
M2-SM: 62 MHz
ADC resolution
10-bit, 8-bit
LVDS outputs
M1-SM: 4 data + sync + clock
CMOS outputs
M2-SM: 10-bit parallel output,
frame_valid, line_valid, clock
Data rate
M1-SM:
4 x 620 Mbps (10-bit) /
4 x 496 Mbps (8-bit)
M2-SM: 62 MHz
Power dissipation
Package type
M1−SM in 10−bit mode:
700 mW at 20 fps frame rate
M2−SM: 540 mW at 5 fps frame rate
52-pin LCC
Specification
Frame rate
at full resolution
M1−SM: 20 fps
M2−SM: 5 fps
Optical format
2/3 inch
Conversion gain
0.072 LSB10/e56 mV/e-
Dark noise
1.5 LSB10,
21 e-
Responsivity at 550 nm
4 LSB10 /nJ/cm2
Full well charge
13500 e-
QE x FF
40% at 550 nm
Pixel FPN
1.3 LSB10
Row FPN
0.07 LSB10
Column FPN
1.3 LSB10
PRNU
< 4% of signal
Dark signal
13.8 e-/s @ 25°C,
2.4 LSB10/s at +24°C
Dynamic range
54 dB
Signal to Noise Ratio
(SNR)
40 dB
Table 3. RECOMMENDED OPERATING RATINGS (Note 1)
Symbol
TJ (Note 2)
Description
Operating temperature range
Min
Max
Units
0
70
°C
Functional operation above the stresses listed in the Recommended Operating Ranges is not implied. Extended exposure to stresses beyond
the Recommended Operating Ranges limits may affect device reliability.
Table 4. ABSOLUTE MAXIMUM RATINGS (Notes 2 and 3)
Symbol
Min
Max
Units
ABS (1.8 V supply group)
ABS rating for 1.8 V supply group
–0.5
2.25
V
ABS (3.3 V supply group)
ABS rating for 3.3 V supply group
–0.5
4.3
V
0
150
°C
85
%RH
TS
Parameter
ABS storage temperature range
ABS storage humidity range at 85°C
Electrostatic discharge (ESD)
LU
Human Body Model (HBM): JS−001−2010
2000
Charged Device Model (CDM): JESD22−C101
500
Latch-up: JESD−78
200
V
mA
Stresses exceeding those listed in the Maximum Ratings table may damage the device. If any of these limits are exceeded, device functionality
should not be assumed, damage may occur and reliability may be affected.
1. Operating ratings are conditions in which operation of the device is intended to be functional.
2. Stresses above these ratings may cause permanent damage. Exposure to absolute maximum conditions for extended periods may degrade
device reliability. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those specified
is not implied.
3. ON Semiconductor recommends that customers become familiar with, and follow the procedures in JEDEC Standard JESD625−A. Refer
to Application Note AN52561.
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NOIM1SM9600A, NOIM2SM9600A
Table 5. ELECTRICAL SPECIFICATIONS
Boldface limits apply for TJ = TMIN to TMAX, all other limits TJ = +30°C. (Notes 4, 5, 6 and 7)
Description
Parameter
Min
Typ
Max
Units
Power Supply Parameters
Vdd_33
Supply voltage, 3.3 V
3.1
3.3
3.6
V
Vdd_18
Supply voltage, 1.8 V
1.6
1.8
2
V
Vdd_pix
Supply voltage, pixel
3.1
3.3
3.6
V
Idd_pix
Current consumption pixel supply
0.8
1
1.2
Ptot_20fps/5fps
Total power consumption at 20 fps / 5 fps
Pstby
Power consumption in standby mode
Pstby_lp
Power consumption in low power standby mode
Popt
Power consumption at lower pixel rates
700 / 540
mA
mW
50
mW
10
mW
Configurable
I/O - LVCMOS (JEDEC- JESD8C-01) - Conforming to standard - additional specifications and deviations listed
fpardata
Data rate on parallel channels
62
Mbps
Cout
Output load
10
pF
tr
Rise time
3
4.5
6
ns
tf
Fall time
2.5
3.5
5
ns
I/O - LVDS (EIA/TIA-644) - Conforming to standard - additional specifications and deviations listed
fserdata
Data rate on data channels for 20 fps / 5 fps
fserclock
Clock rate of output clock for 20 fps / 5 fps
Vicm
LVDS input common mode level
Tccsk
Channel to channel skew
620 / 150
Mbps
310 / 75
0.3
MHz
1.25
2.2
V
50
ps
62 / 15
MHz
55
%
10 / 2.5
MHz
5 / 20
fps
5.8 / 24
fps
Electrical/Interface
fin
Input clock rate for 20 fps / 5 fps
tidc
Input clock duty cycle
tj
Input clock jitter
fspi
SPI clock rate for 20 / 5 fps
ratspi
Ratio: Fin/fspi
45
50
20
ps
6
Sensor Requirements
fps
Frame rate at full resolution (CMOS / LVDS)
fps_roi1
Xres x Yres = 3334 x 2500
fps_roi2
Xres x Yres = 3840 x 2160
6 / 25
fps
fps_roi3
Xres x Yres = 1024 x 1024
32 / 135
fps
fps_roi4
Xres x Yres = 640 x 480
88 / 366
fps
fps_roi5
Xres x Yres = 512 x 512
91 / 377
fps
fps_roi6
Xres x Yres = 256 x 256
227 / 942
fps
ROT
Row Overhead Time at 20 / 5 fps
fpix
Pixel rate minimum at 5 fps, maximum at 20 fps
1.55 / 6.4
60
ms
248
Mpix/s
62
fps
I/O - LVCMOS (JEDEC - JESD8C-01) - Conforming to standard - additional specifications and deviations listed
fpardata
Data rate on parallel channels
4. All parameters are characterized for DC conditions after thermal equilibrium is established.
5. This device contains circuitry to protect the inputs against damage due to high static voltages or electric fields. However, it is recommended
that normal precautions be taken to avoid application of any voltages higher than the maximum rated voltages to this high impedance circuit.
6. Minimum and maximum limits are guaranteed through test and design.
7. For recommendations on power supply management guidelines, refer to Application Note AN65464: VITA 2000 HSMC Cyclone Reference
Board Design Recommendations.
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NOIM1SM9600A, NOIM2SM9600A
OVERVIEW
are controlled by the on-chip sequencer and can access the
pixel array in rolling shutter modes.
The pixel biasing block guarantees that the data on a pixel
is transferred properly to the column multiplexer when the
row drivers select a pixel line for readout.
Figure 3 and Figure 4 give an overview of the major
functional blocks of the M1−SM and M2−SM sensor
respectively. The system clock is received by the CMOS
clock input. A PLL generates the internal, high speed,
clocks, which are distributed to the other blocks. Optionally,
the M1−SM can also accept a high speed LVDS clock, in
which case the PLL will be disabled.
The sequencer defines the sensor timing and controls the
image core. The sequencer is started either autonomously
(master mode) or on assertion of an external trigger (slave
mode). The image core contains all pixels and readout
circuits. The column structure selects pixels for readout and
performs correlated double sampling (CDS). The data
comes out sequentially and is fed into the analog front end
(AFE) block. The programmable gain amplifier (PGA) of
the AFE adds the offset and gain. The output is a fully
differential analog signal that goes to the ADC, where the
analog signal is converted to a 10−bit data stream.
Depending on the operating mode, eight or ten bits are fed
into the data formatting block. This block adds
synchronization information to the data stream based on the
frame timing. For the M1−SM version, the data then goes to
the low voltage serial (LVDS) interface block which sends
the data out through the I/O ring. The M2−SM sensor does
not have an LVDS interface but sends out the data through
a 10−bit parallel interface.
On-chip programmability is achieved through the Serial
Peripheral Interface (SPI). See the Register Map on page 44
for register details.
A bias block generates bias currents and voltages for all
analog blocks on the chip. By controlling the bias current,
the speed-versus-power of each block can be tuned. All
biasing programmability is contained in the bias block.
The sensor can automatically control exposure and gain
by enabling the automatic exposure control block (AEC).
This block regulates the integration time along with the
analog and digital gains to reach the desired intensity.
Phase Locked Loop
The PLL accepts a (low speed) clock and generates the
required high speed clock. Optionally this PLL can be
bypassed. Typical input clock frequency is 62 MHz.
LVDS Clock Receiver
The LVDS clock receiver receives an LVDS clock signal
and distributes the required clocks to the sensor.
Typical input clock frequency is 310 MHz in 10-bit mode
and 248 MHz in 8-bit mode. The clock input needs to be
terminated with a 100 W resistor.
Column Multiplexer
All pixels of one image row are stored in the column
sample-and-hold (S/H) stages. These stages store both the
reset and integrated signal levels.
The data stored in the column S/H stages is read out
through 8 parallel differential outputs operating at a
frequency of 31 MHz.
At this stage, the reset signal and integrated signal values
are transferred into an FPN-corrected differential signal.
The column multiplexer also supports read-1-skip-1 and
checkerboard subsampling.
Bias Generator
The bias generator generates all required reference
voltages and bias currents that the on-chip blocks use. An
external resistor of 47 kW, connected between pin
IBIAS_MASTER and gnd_33, is required for the bias
generator to operate properly.
Analog Front End
The AFE contains 8 channels, each containing a PGA and
a 10-bit ADC.
For each of the 8 channels, a pipelined 10-bit ADC is used
to convert the analog image data into a digital signal, which
is delivered to the data formatting block. A black calibration
loop is implemented to ensure that the black level is mapped
to match the correct ADC input level.
Image Core
The image core consists of:
• Pixel Array
• Address Decoders and Row Drivers
• Pixel Biasing
The pixel array contains 3840 (H) x 2500 (V) readable
pixels with a pixel pitch of 2.4 mm. Four dummy pixel rows
and columns are placed at every side of the pixel array to
eliminate possible edge effects. The sensor uses a 4T pixel
architecture, which makes it possible to read out the pixel
array in rolling shutter mode with correlated double
sampling (CDS).
The function of the row drivers is to access the image array
line by line to reset or read the pixel data. The row drivers
Data Formatting
The data block receives data from two ADCs and
multiplexes this data to one data stream. A cyclic
redundancy check (CRC) code is calculated on the passing
data.
A frame synchronization data block is configured to
transmit synchronization codes such as frame start, line
start, frame end, and line end indications.
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NOIM1SM9600A, NOIM2SM9600A
Frame synchronization information is communicated by
means of frame and line valid strobes.
The data block calculates a CRC once per line for every
channel. This CRC code can be used for error detection at the
receiving end.
Sequencer
The sequencer:
Serializer and LVDS Interface (M1−SM only)
• Controls the image core. Starts and stops integration in
The serializer and LVDS interface block receives the
formatted (10-bit or 8-bit) data from the data formatting
block. This data is serialized and transmitted by the LVDS
output driver.
In 10-bit mode, the maximum output data rate is 620 Mbps
per channel. In 8-bit mode, the maximum output data rate is
496 Mbps per channel.
In addition to the LVDS data outputs, two extra LVDS
outputs are available. One of these outputs carries the output
clock, which is skew aligned to the output data channels. The
second LVDS output contains frame format synchronization
codes to serve system-level image reconstruction.
•
•
•
rolling shutter mode and controls pixel readout.
Applies the window settings. Organizes readouts so that
only the configured window is read.
Controls the column multiplexer and analog core.
Applies gain settings and subsampling modes at the
correct time, without corrupting image data.
Starts up the sensor correctly when leaving standby
mode.
Automatic Exposure Control
The AEC block implements a control system to modulate
the exposure of an image. Both integration time and gains
are controlled by this block to target a predefined
illumination level.
Output MUX (M2−SM only)
The output MUX multiplexes the four data channels to
one channel and transmits the data words using a 10-bit
parallel CMOS interface.
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NOIM1SM9600A, NOIM2SM9600A
Block Diagram
Image Core
Row Decoder
Image Core Bias
Pixel Array
(3840 x 2500)
Column Structure
Automatic
Exposure
Control
(AEC)
8 analog channels
Analog Front End (AFE)
8 x 10 bit
digital channels
Control &
Registers
Data Formatting
Clock
Distribution
4 x 10 bit
digital channels
LVDS Clock
Input
Reset
CMOS
Clock Input
Serializers & LVDS Interface
LVDS Receiver
SPI Interface
PLL
LVDS Interface
Figure 3. Block Diagram − M1−SM
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8
4 LVDS channels
1 Sync channel
1 Clock channel
NOIM1SM9600A, NOIM2SM9600A
Block Diagram
Image Core
Row Decoder
Image Core Bias
Pixel Array
(3840 x 2500)
Column Structure
Automatic
Exposure
Control
(AEC)
8 analog channels
Analog Front End (AFE)
8 x 10 bit
digital channels
Control &
Registers
Data Formatting
4 x 10 bit
digital channels
Clock
Distribution
Output MUX
10 bit Parallel Data
Frame Valid Indication
Line Valid Indication
Reset
CMOS
Clock Input
SPI Interface
PLL
CMOS Interface
Figure 4. Block Diagram − M2−SM
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NOIM1SM9600A, NOIM2SM9600A
OPERATING MODES
storage node in the pixel is reset. Afterwards the integrated
signal is transferred to that pixel storage node. The
difference between the reset level and integrated signal is the
FPN corrected signal. The advantage of this technique,
compared to the DS technique used in the global shutter
modes, is that the reset noise of the pixel storage node is
cancelled. This results in a lower temporal noise level.
The MANO 9600 sensor operates in Rolling Shutter
Mode
Rolling Shutter Mode
The shutter mechanism is an electronic rolling shutter and
the sensor operates in a streaming mode similar to a video.
This mechanism is controlled by the on-chip sequencer
logic. There are two Y pointers. One points to the row that
is to be reset for rolling shutter operation, the other points to
the row to be read out. Functionally, a row is reset first and
selected for read out sometime later. The time elapsed
between these two operations is the exposure time.
Figure 5 schematically indicates the relative shift of the
integration times of different lines during the rolling shutter
operation. Each row is read and reset in a sequential way.
Each row in a particular frame is integrated for the same
time, but all lines in a frame ‘see’ a different stare time. As
a consequence, fast horizontal moving objects in the field of
view give rise to motion artifacts in the image; this is an
unavoidable property of a rolling shutter.
In rolling shutter mode, the pixel Fixed Pattern Noise
(FPN) is corrected on-chip by using the CDS technique.
After light integration on all pixels in a row is complete, the
Figure 5. Rolling Shutter Operation
SENSOR OPERATION
Flowchart
Low Power Standby
In low power standby state, all power supplies are on, but
internally every block is disabled. No internal clock is
running (PLL / LVDS clock receiver is disabled). All
register settings are unchanged.
Only a subset of the SPI registers is active for read/write
in order to be able to configure clock settings and leave the
low power standby state. The only SPI registers that should
be touched are the ones required for the ‘Enable Clock
Management’ action described in Enable Clock
Management − Part 1 on page 12
Standby (1)
In standby state, the PLL/LVDS clock receiver is running,
but the derived logic clock signal is not enabled.
Standby (2)
In standby state, the derived logic clock signal is running.
All SPI registers are active, meaning that all SPI registers
can be accessed for read or write operations. All other blocks
are disabled.
Idle
In the idle state, all internal blocks are enabled, except the
sequencer block. The sensor is ready to start grabbing
images as soon as the sequencer block is enabled.
Running
In running state, the sensor is enabled and grabbing
images.
Figure 6 shows the sensor operation flowchart. The sensor
can be in six different ‘states’. Every state is indicated with
the oval circle. These states are:
• Power off
• Low power standby
• Standby (1)
• Standby (2)
• Idle
• Running
These states are ordered by power dissipation. In
‘power-off’ state, the power dissipation is minimal; in
‘running’ state the power dissipation is maximal.
On the other hand, the lower the power consumption, the
more actions (and time) are required to put the sensor in
‘running’ state and grab images.
This flowchart allows the trade-off between power saving
and enabling time of the sensor.
Next to the six ‘states’ a set of ‘user actions’, indicated by
arrows, are included in the flowchart. These user actions
make it possible to move from one state to another.
Sensor States
Power Off
In this state, the sensor is inactive. All power supplies are
down and the power dissipation is zero.
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NOIM1SM9600A, NOIM2SM9600A
Power Off
Power Down
Sequence
Power Up Sequence
Low-Power Standby
Disable Clock Management
Part 1
Enable Clock Management - Part 1
Poll Lock Indication
(only when PLL is enabled)
Enable Clock Management - Part 2
(First Pass after Hard Reset)
Intermediate Standby
Required Register
Upload
Standby (2)
Sensor (re-)configuration
(optional)
Soft Power-Down
Soft Power-Up
Sensor (re-)configuration
(optional)
Idle
Disable Sequencer
Enable Sequencer
Sensor (re-)configuration
(optional)
Running
Figure 6. Sensor Operation Flowchart
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Assertion of reset_n Pin
Disable Clock Management
Part 2
Enable Clock Management - Part 2
(Not First Pass after Hard Reset)
Standby (1)
NOIM1SM9600A, NOIM2SM9600A
User Actions: Power Up Functional Mode Sequences
Enable Clock Management − Part 1
The ‘Enable Clock Management’ action configures the
clock management blocks and activates the clock generation
and distribution circuits in a pre-defined way. First, a set of
clock settings must be uploaded through the SPI register.
These settings are dependent on the desired operation mode
of the sensor.
Table 6 shows the SPI uploads to be executed to configure
the sensor for M1-SM 8-bit serial, M1-SM 10-bit serial, or
M2-SM 10-bit parallel mode, with and without the PLL.
In the serial modes, if the PLL is not used, the LVDS clock
input must be running.
In the M2-SM 10-bit parallel mode, the PLL is bypassed.
The clk_pll clock is used as sensor clock.
It is important to follow the upload sequence listed in
Table 6.
Power Up Sequence
Figure 7 shows the power up sequence of the sensor. The
figure indicates that the first supply to ramp-up is the vdd_18
supply, followed by vdd_33 and vdd_pix respectively. It is
important to comply with the described sequence. Any other
supply ramping sequence may lead to high current peaks
and, as consequence, a failure of the sensor power up.
The clock input should start running when all supplies are
stabilized. When the clock frequency is stable, the reset_n
signal can be de-asserted. After a wait period of 10 ms, the
power up sequence is finished and the first SPI upload can
be initiated.
NOTE: The ‘clock input’ can be the CMOS PLL clock
input (clk_pll), or the LVDS clock input
(lvds_clock_inn/p) in case the PLL is bypassed.
Use of Phase Locked Loop
If PLL is used, the PLL is started after the upload of the
SPI registers. The PLL requires (dependent on the settings)
some time to generate a stable output clock. A lock detect
circuit detects if the clock is stable. When complete, this is
flagged in a status register.
NOTE: The lock detect status must not be checked for
the M2-SM sensor.
Check this flag by reading the SPI register. When the flag
is set, the ‘Enable Clock Management- Part 2’ action can be
continued. When PLL is not used, this step can be bypassed
as shown in Figure 6 on page 11.
clock input
reset_n
vdd_18
vdd_33
vdd_pix
SPI Upload
> 10us
> 10us
> 10us
> 10us
> 10us
Figure 7. Power Up Sequence
Table 6. ENABLE CLOCK MANAGEMENT REGISTER UPLOAD − PART 1
Upload #
Address
Data
Description
M1-SM 8-bit mode with PLL
1
2
0x0000
Monochrome sensor
2
32
0x200C
Configure clock generator
3
8
0x0000
Release PLL soft reset
4
16
0x0003
Enable PLL
M1-SM 8-bit mode without PLL
1
2
0x0000
Monochrome sensor
2
32
0x2008
Configure clock management
3
20
0x0001
Enable LVDS clock input
M1-SM 10-bit mode with PLL
1
2
0x0000
Monochrome sensor
2
32
0x2004
Configure clock generator
7
8
0x0000
Release PLL soft reset
8
16
0x0003
Enable PLL
0x0000
Monochrome sensor
M1-SM 10-bit mode without PLL
1
2
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NOIM1SM9600A, NOIM2SM9600A
Table 6. ENABLE CLOCK MANAGEMENT REGISTER UPLOAD − PART 1
Upload #
Address
Data
2
32
0x2000
Configure clock management
Description
3
20
0x0001
Enable LVDS clock input
1
2
0x0002
Monochrome sensor parallel mode selection
2
32
0x200C
Configure clock management
3
2
0x0002
Parallel Mode selection
4
16
0x0007
Configure PLL bypass mode
M2-SM 10-bit mode
The required uploads are listed in Table 7. Note that it is
important to follow the upload sequence listed in Table 7.
Enable Clock Management - Part 2
The next step to configure the clock management consists
of SPI uploads which enables all internal clock distribution.
Table 7. ENABLE CLOCK MANAGEMENT REGISTER UPLOAD − PART 2
Upload #
Address
Data
Description
M1-SM 8-bit mode with PLL
1
9
0x0000
Release clock generator soft reset
2
32
0x200E
Enable logic clock
3
34
0x0001
Enable logic blocks
M1-SM 8-bit mode without PLL
1
9
0x0000
Release clock generator soft reset
2
32
0x200A
Enable logic clock
3
34
0x0001
Enable logic blocks
M1-SM 10-bit mode with PLL
1
9
0x0000
Release clock generator soft reset
2
32
0x2006
Enable logic clock
3
34
0x0001
Enable logic blocks
M1-SM 10-bit mode without PLL
1
9
0x0000
Release clock generator soft reset
2
32
0x2002
Enable logic clock
3
34
0x0001
Enable logic blocks
1
9
0x0000
Release clock generator soft reset
2
32
0x200E
Enable logic clock
3
34
0x0001
Enable logic blocks
M2-SM 10-bit mode
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NOIM1SM9600A, NOIM2SM9600A
Required Register Upload
In this phase, the ‘reserved’ register settings are uploaded
through the SPI register. Different settings are not allowed
and may cause the sensor to malfunction. The required
uploads are listed in Table 8.
NOTE: This table is subject to change.
Table 8. REQUIRED REGISTERED UPLOAD
Upload #
Address
Data
1
192
0x0800
2
42
0x0002
3
128
0x4320
4
205
0x00A0
5
129
0x0001
6
230
0x0044
7
231
0x09CB
8
197
0x2364
9
256
0x0000
10
257
0x01DF
11
258
0x0000
12
259
0x09C3
13
260
0x0000
14
261
0x01DF
15
262
0x0000
16
263
0x09C3
17
201
0x07D0
18
65
0x885B
19
72
0x0000
20
43
0x4701
21
384
0x0900
22
385
0x0BE1
23
386
0x0BC5
24
387
0x0381
25
388
0x0181
26
389
0x218F
27
390
0x2185
28
391
0x2101
29
392
0x0501
30
393
0x07C6
31
394
0x0781
32
395
0x0581
33
396
0x258F
34
397
0x2585
35
398
0x2501
36
399
0x0102
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37
400
0x1346
38
401
0x0341
39
402
0x0141
40
403
0x214F
41
404
0x2145
42
405
0x2101
43
406
0x0501
44
407
0x0746
45
408
0x0741
46
409
0x0541
47
410
0x254F
48
411
0x2545
49
412
0x2501
50
413
0x0101
51
414
0x8101
52
415
0x8901
53
416
0x990E
54
417
0x8901
55
418
0x8901
56
419
0xC901
57
420
0xD90E
58
421
0xC901
59
422
0xC900
60
423
0x0900
61
424
0x1BE1
62
425
0x1BC5
63
426
0x1B89
64
427
0x0B82
65
428
0x0381
66
429
0x0181
67
430
0x218F
68
431
0x2185
69
432
0x2101
70
433
0x0501
71
434
0x07C6
72
435
0x0781
73
436
0x0581
74
437
0x258F
75
438
0x2585
76
439
0x2501
77
440
0x0102
78
441
0x1346
79
442
0x0341
NOIM1SM9600A, NOIM2SM9600A
REQUIRED REGISTERED UPLOAD
(Table 8. Continued)
110
472
0x0501
111
473
0x07C6
Upload #
Address
Data
112
474
0x0781
80
443
0x0141
113
475
0x0581
81
444
0x214F
114
476
0x258F
82
445
0x2145
115
477
0x2585
83
446
0x2101
116
478
0x2501
84
447
0x0501
117
479
0x0102
85
448
0x0746
118
480
0x1346
86
449
0x0741
119
481
0x0341
87
450
0x0541
120
482
0x0141
88
451
0x254F
121
483
0x2142
89
452
0x2545
122
484
0x2101
90
453
0x2501
123
485
0x0501
91
454
0x0101
124
486
0x0746
92
455
0x8101
125
487
0x0741
93
456
0x990E
126
488
0x0541
94
457
0x8901
127
489
0x2542
95
458
0x8901
128
490
0x2501
96
459
0xC901
129
491
0x0101
97
460
0xD90E
130
492
0x8101
98
461
0xC900
131
493
0x990E
99
220
0x2700
132
494
0x8901
100
462
0x0900
133
495
0x8901
101
463
0x1BE1
134
496
0xC901
102
464
0x1BC5
135
497
0xD90E
103
465
0x1B89
136
498
0xC900
104
466
0x0B82
137
219
0x004E
105
467
0x0381
138
499
0x0010
106
468
0x0181
139
216
0x737F
107
469
0x218F
108
470
0x2185
109
471
0x2101
NOTE: Upload #5: CMOS Mode only. Do NOT show line valid for
black lines. [9:1]=0. Uncalibrated black offset
Upload #8: MUX BL coeffs. [13:13] = 1
Upload #20: Select DAC. [7:4]=0
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NOIM1SM9600A, NOIM2SM9600A
stream. This action exists of a set of SPI uploads. The soft
power up uploads are listed in Table 9.
Soft Power Up
During the soft power up action, the internal blocks are
enabled and prepared to start processing the image data
Table 9. SOFT POWER UP REGISTER UPLOADS FOR MODE DEPENDENT REGISTERS
Upload #
Address
Data
Description
M1-SM 8-bit mode with PLL
1
32
0x200F
Enable analog clock distribution
2
112
0x0007
Enable LVDS transmitters
M1-SM 8-bit mode without PLL
1
32
0x200B
Enable analog clock distribution
2
112
0x0007
Enable LVDS transmitters
M1-SM 10-bit mode with PLL
1
32
0x2007
Enable analog clock distribution
2
112
0x0007
Enable LVDS transmitters
M1-SM 10-bit mode without PLL
1
32
0x2003
Enable analog clock distribution
2
112
0x0007
Enable LVDS transmitters
32
0x200F
Enable analog clock distribution
M2-SM 10-bit mode
1
Table 10. SOFT POWER UP FOR LVDS AND CMOS OUTPUTS
Upload #
Address
LVDS
CMOS
1
32
0x400F
0x200F
2
10
0x0000
0x0000
3
64
0x0001
0x0001
4
72
0x0000
0x0000
5
81
0x8880
0x8880
6
42
0x006E
0x006E
7
40
0x0003
0x0003
8
48
0x0001
0x0001
9
112
0x0007
0x0000
10
128
0x4320
The ‘Enable Sequencer’ action consists of a set of register
uploads. The required uploads are listed in Table 11.
Enable Sequencer
During the ‘Enable Sequencer’ action, the frame grabbing
sequencer is enabled. The sensor starts grabbing images in
the configured operation mode. Refer to Sensor States on
page 10 for an overview of the possible operation modes.
Table 11. ENABLE SEQUENCER REGISTER UPLOAD
Upload #
Address
Data
Description
1
192
0x0003
Enable of Sequencer in rolling shutter mode
Note: this address contains other configuration bits to select the operation
mode
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NOIM1SM9600A, NOIM2SM9600A
User Actions: Functional Modes to Power Down
Sequences
Disable Sequencer
During the ‘Disable Sequencer’ action, the frame
grabbing sequencer is stopped. The sensor stops grabbing
images and returns to the idle mode.
The ’Disable Sequencer’ action consists of a set of register
uploads. as listed in Table 12.
Table 12. DISABLE SEQUENCER REGISTER UPLOAD
Upload #
Address
Data
1
192
0x0002
Description
Disable sequencer.
Note that this address contains other configuration bits to select the
operation mode.
current dissipation. This action exists of a set of SPI uploads.
The soft power down uploads are listed in Table 13.
Soft Power Down
During the soft power down action, the internal blocks are
disabled and the sensor is put in standby state to reduce the
Table 13. SOFT POWER DOWN REGISTER UPLOAD
Upload #
Address
Data
Description
1
112
0x0000
Disable LVDS transmitters
2
48
0x0000
Disable AFE
3
40
0x0000
Disable column multiplexer
4
64
0x0000
Disable biasing block
5
10
0x0999
Soft reset
This action can be implemented with the SPI uploads as
shown in Table 14.
Disable Clock Management - Part 2
The ‘Disable Clock Management’ action stops the
internal clocking to further decrease the power dissipation.
Table 14. DISABLE CLOCK MANAGEMENT REGISTER UPLOAD − PART 2
Upload #
Address
Data
Description
M1-SM 8-bit mode with PLL
1
34
0x0000
Disable logic blocks
2
32
0x200C
Disable logic clock
3
9
0x0009
Soft reset clock generator
M1-SM 8-bit mode without PLL
1
34
0x0000
Disable logic blocks
2
32
0x2008
Disable logic clock
3
9
0x0009
Soft reset clock generator
M1-SM 10-bit mode with PLL
1
34
0x0000
Disable logic blocks
2
32
0x2004
Disable logic clock
3
9
0x0009
Soft reset clock generator
M2-SM 10-bit mode without PLL
1
34
0x0000
Disable logic blocks
2
32
0x2000
Disable logic clock
3
9
0x0009
Soft reset clock generator
M2-SM 10-bit mode
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NOIM1SM9600A, NOIM2SM9600A
Table 14. DISABLE CLOCK MANAGEMENT REGISTER UPLOAD − PART 2
Upload #
Address
Data
1
34
0x0000
Disable logic blocks
Description
2
32
0x200C
Disable logic clock
3
9
0x0009
Soft reset clock generator
This action can be implemented with the SPI uploads as
shown in Table 15.
Disable Clock Management - Part 1
The ‘Disable Clock Management’ action stops the
internal clocking to further decrease the power dissipation.
Table 15. DISABLE CLOCK MANAGEMENT REGISTER UPLOAD − PART 1
Upload #
Address
Data
Description
1
16
0x0000
Disable PLL
2
8
0x0099
Soft reset PLL
3
20
0x0000
Configure clock management
Power Down Sequence
Figure 8 illustrates the timing diagram of the preferred
power down sequence. It is important that the sensor is in
reset before the clock input stops running. Otherwise, the
internal PLL becomes unstable and the sensor gets into an
unknown state. This can cause high peak currents.
The same applies for the ramp down of the power
supplies. The preferred order to ramp down the supplies is
first vdd_pix, second vdd_33, and finally vdd_18. Any other
sequence can cause high peak currents.
NOTE: The ‘clock input’ can be the CMOS PLL clock
input (clk_pll), or the LVDS clock input
(lvds_clock_inn/p) in case the PLL is bypassed.
clock input
reset_n
vdd_18
vdd_33
vdd_pix
> 10us
> 10us
> 10us
> 10us
Figure 8. Power Down Sequence
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NOIM1SM9600A, NOIM2SM9600A
Sensor Reconfiguration
Sensor Configuration
During the standby, idle, or running state several sensor
parameters can be reconfigured.
• Frame Rate and Exposure Time: Frame rate and
exposure time changes can occur during standby, idle,
and running states.
• Signal Path Gain: Signal path gain changes can occur
during standby, idle, and running states.
• Windowing: Changes with respect to windowing can
occur during standby, idle, and running states. Refer to
Window Readout on page 25.
• Subsampling: Changes of the subsampling mode can
occur during standby, idle, and running states. Refer to
Subsampling and Binning on page 26 for more
information.
This device contains multiple configuration registers.
Some of these registers can only be configured while the
sensor is not acquiring images (while register 192[0] = 0),
while others can be configured while the sensor is acquiring
images. For the latter category of registers, it is possible to
distinguish the register set that can cause corrupted images
(limited number of images containing visible artifacts) from
the set of registers that are not causing corrupted images.
These three categories are described here.
Static Readout Parameters
Some registers are only modified when the sensor is not
acquiring images. Reconfiguration of these registers while
images are acquired can cause corrupted frames or even
interrupt the image acquisition. Therefore, it is
recommended to modify these static configurations while
the sequencer is disabled (register 192[0] = 0). The registers
shown in Table 16 should not be reconfigured during image
acquisition. A specific configuration sequence applies for
these registers. Refer to the operation flow and startup
description.
Table 16. STATIC READOUT PARAMETERS
Group
Addresses
Description
Clock generator
32
Configure according to recommendation
Image core
40
Configure according to recommendation
AFE
48
Configure according to recommendation
Bias
64–71
Configure according to recommendation
LVDS
112
Configure according to recommendation
All reserved registers
Keep reserved registers to their default state, unless otherwise described in the
recommendation
an image containing visible artifacts. A typical example of
a corrupted image is an image which is not uniformly
exposed.
The effect is transient in nature and the new configuration
is applied after the transient effect.
Dynamic Configuration Potentially Causing Image
Artifacts
The category of registers as shown in Table 16 consists of
configurations that do not interrupt the image acquisition
process, but may lead to one or more corrupted images
during and after the re-configuration. A corrupted image is
Table 17. DYNAMIC CONFIGURATION POTENTIALLY CAUSING IMAGE ARTIFACTS
Group
Addresses
Description
Black level configuration
128–129
197[8]
Reconfiguration of these registers may have an impact on the black-level calibration
algorithm. The effect is a transient number of images with incorrect black level
compensation.
Sync codes
129[13]
130–135
Incorrect sync codes may be generated during the frame in which these registers
are modified.
Datablock test configurations
144–150
Modification of these registers may generate incorrect test patterns during
a transient frame.
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NOIM1SM9600A, NOIM2SM9600A
shown in Table 18. Some reconfiguration may lead to one
frame being blanked. This happens when the modification
requires more than one frame to settle. The image is blanked
out and training patterns are transmitted on the data and sync
channels.
Dynamic Readout Parameters
It is possible to reconfigure the sensor while it is acquiring
images. Frame-related parameters are internally
resynchronized to frame boundaries, such that the modified
parameter does not affect a frame that has already started.
However, there can be restrictions to some registers as
Table 18. DYNAMIC READOUT PARAMETERS
Group
Addresses
Subsampling/binning
232[4:0]
Description
Subsampling or binning is synchronized to a new frame start. Subsampling / binning also
required to reconfigure black line address (230[9:5]), last line address 231[12:0] and
Y−start offset (230[4:0]) as mentioned in detail in register map given in Table 45 on page
44. Reconfiguration of these parameters cause one frame to be blanked out
Black lines
197
Reconfiguration of these parameters causes one frame to be blanked out as the reset
pointers need to be recalculated for the new frame timing.
Dummy lines
198
Reconfiguration of these parameters causes one frame to be blanked out as the reset
pointers need to be recalculated for the new frame timing.
ROI configuration
195
256–263
Optionally, it is possible to blank out one frame after reconfiguration of the active ROI in
rolling shutter mode. Therefore, register 192[9] must be asserted (blank_roi_switch
configuration).
A ROI switch is only detected when a new window is selected as the active window
(reconfiguration of register 195). Reconfiguration of the ROI dimension of the active
window does not lead to a frame blank and can cause a corrupted image.
Exposure reconfiguration
203
Exposure reconfiguration does not cause artifact.
Gain reconfiguration
204
Gains are synchronized at the start of a new frame. Optionally, one frame latency can be
incorporated to align the gain updates to the exposure updates
(refer to register 199[13] - gain_lat_comp).
of the active set of registers can be programmed in the
sync_configuration registers, which can be found at the SPI
address 206.
Figure 9 shows a re-configuration that does not use the
sync_configuration option. As depicted, new SPI
configurations are synchronized to frame boundaries.
With sync_configuration = ‘1’. Configurations are
synchronized to the frame boundaries.
Figure 10 shows the usage of the sync_configuration
settings. Before uploading a set of registers, the
corresponding sync_configuration is de-asserted. After the
upload is completed, the sync_configuration is asserted
again and the sensor resynchronizes its set of registers to the
coming frame boundaries.
As seen in the figure, this ensures that the uploads
performed at the end of frame N+2 and the start of frame
N+3 become active in the same frame (frame N+4).
Freezing Active Configurations
Though the readout parameters are synchronized to frame
boundaries, an update of multiple registers can still lead to
a transient effect in the subsequent images, as some
configurations require multiple register uploads. For
example, to reconfigure sub−sampling / binning scheme we
also need to update black line address, Y−start offset and last
line address registers. Internally, the sensor synchronizes
these configurations to frame boundaries, but it is still
possible that the reconfiguration of multiple registers spans
over two or even more frames. To avoid inconsistent
combinations, freeze the active settings while altering the
SPI registers by disabling synchronization for the
corresponding functionality before reconfiguration. When
all registers are uploaded, re−enable the synchronization.
The sensor’s sequencer then updates its active set of
registers and uses them for the coming frames. The freezing
Time Line
Frame N
Frame N+1
Frame N+2
Frame N+3
Frame N+4
SPI Registers
Active Registers
Figure 9. Frame Synchronization of Configurations (no freezing)
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NOIM1SM9600A, NOIM2SM9600A
Frame NFrame N+1 Frame N+2 Frame N+3 Frame N+4
Time Line
sync_configuration
This configuration is not taken into
account as sync_register is inactive.
SPI Registers
Active Registers
Figure 10. Reconfiguration Using Sync_configuration
NOTE: SPI updates are not taken into account while sync_configuration is inactive. The active configuration is frozen
for the sensor. Table 19 lists the several sync_configuration possibilities along with the respective registers being
frozen.
Table 19. ALTERNATE SYNC CONFIGURATIONS
Group
Affected Registers
Description
sync_rs_x_length
rs_x_length
Update of x−length configuration is not synchronized at start of frame when ‘0’.
The sensor continues with its previous configurations.
sync_black_lines
black_lines
Update of black line configuration is not synchronized at start of frame when ‘0’.
The sensor continues with its previous configurations.
sync_dummy_lines
sync_exposure
sync_gain
sync_roi
dummy_lines
Update of dummy line configuration is not synchronized at start of frame when ‘0’.
The sensor continues with its previous configurations.
mult_timer
fr_length
exposure
Update of exposure configurations is not synchronized at start of frame when ‘0’.
The sensor continues with its previous configurations.
mux_gainsw
afe_gain
roi_active0[7:0]
subsampling
binning
black line address
last line address
Y−start offset
Update of gain configurations is not synchronized at start of frame when ‘0’.
The sensor continues with its previous configurations.
Update of active ROI configurations is not synchronized at start of frame when ‘0’. The
sensor continues with its previous configurations.
Note: The window configurations themselves are not frozen. Reconfiguration of active
windows is not gated by this setting.
Table 20. CONFIGURABLE PARAMETERS FOR BLACK LEVEL ALGORITHM
Group
Addresses
Description
197[7:0]
black_lines
This register configures the number of black lines that are generated at the start of a
frame. At least one black line must be generated. The maximum number is 127.
Note: When the automatic black-level calibration algorithm is enabled, make sure that this
register is configured properly to produce sufficient black pixels for the black-level filtering.
The number of black pixels generated per line is dependent on the operation mode and
window configurations:
As the line length is fundamental for rolling shutter operation, the length of a black line is
defined by the active window.
197[8:9]
gate_first_line
When asserting this configuration, the first black lines of the frame are blanked out and is
not used for black calibration. It is recommended to enable this functionality, because the
first black lines can have a different behavior caused by boundary effects. When enabling,
the number of black lines must be set to at least two in order to have valid black samples
for the calibration algorithm.
Black Line Generation
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NOIM1SM9600A, NOIM2SM9600A
Table 20. CONFIGURABLE PARAMETERS FOR BLACK LEVEL ALGORITHM
Group
Addresses
Description
auto_blackcal_enable
Internal black-level calibration functionality is enabled when set to ‘1’. Required black level
offset compensation is calculated on the black samples and applied to all image pixels.
When set to ‘0’, the automatic black-level calibration functionality is disabled. It is possible
to apply an offset compensation to the image pixels, which is defined by the registers
129[10:1].
Note: Black sample pixels are not compensated; the raw data is sent out to provide external statistics and, optionally, calibrations.
129[9:1]
blackcal_offset
Black calibration offset that is added or subtracted to each regular pixel value when
auto_blackcal_enable is set to ‘0’. The sign of the offset is determined by register 129[10]
(blackcal_offset_dec).
Note: All channels use the same offset compensation when automatic black calibration is
disabled.
The calculated black calibration factors are frozen when this register is set to 0x1FF
(all−‘1’) in auto calibration mode. Any value different from 0x1FF re-enables the black
calibration algorithm. This freezing option can be used to prevent eventual frame to frame
jitter on the black level as the correction factors are recalculated every frame. It is recommended to enable the black calibration regularly to compensate for temperature changes.
129[10]
blackcal_offset_dec
Sign of blackcal_offset. If set to ‘0’, the black calibration offset is added to each pixel. If set
to ‘1’, the black calibration offset is subtracted from each pixel.
This register is not used when auto_blackcal_enable is set to ‘1’.
black_samples
The black samples are low-pass filtered before being used for black level calculation. The
more samples are taken into account, the more accurate the calibration, but more samples
require more black lines, which in turn affects the frame rate.
The effective number of samples taken into account for filtering is 2^ black_samples.
Note: An error is reported by the device if more samples than available are requested
(refer to register 136).
Black Value Filtering
129[0]
128[10:8]
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NOIM1SM9600A, NOIM2SM9600A
Serial Peripheral Interface
indicated in Figure 11. The sensor samples this
data on a rising edge of the sck clock (mosi needs
to be driven by the system on the falling edge of
the sck clock).
3. The tenth bit sent by the master indicates the type
of transfer: high for a write command, low for a
read command.
4. Data transmission:
- For write commands, the master continues
sending the 16-bit data, most significant bit first.
- For read commands, the sensor returns the
requested address on the miso pin, most significant
bit first. The miso pin must be sampled by the
system on the falling edge of sck (assuming
nominal system clock frequency and maximum
10 MHz SPI frequency).
5. When data transmission is complete, the system
deselects the sensor one clock period after the last
bit transmission by pulling ss_n high.
Maximum frequency for the SPI depends on the input
clock and type of sensor. The frequency is 1/6th of the PLL
input clock or 1/30th (in 10-bit mode) and 1/24th (in 8-bit
mode) of the LVDS input clock frequency.
At nominal input frequency (62 Mhz / 310 MHz /
248 MHz), the maximum frequency for the SPI is 10 MHz.
Bursts of SPI commands can be issued by leaving at least
two SPI clock periods between two register uploads.
Deselect the chip between the SPI uploads by pulling the
ss_n pin high.
The sensor configuration registers are accessed through
an SPI. The SPI consists of four wires:
• sck: Serial Clock
• ss_n: Active Low Slave Select
• mosi: Master Out, Slave In, or Serial Data In
• miso: Master In, Slave Out, or Serial Data Out
The SPI is synchronous to the clock provided by the
master (sck) and asynchronous to the sensor’s system clock.
When the master wants to write or read a sensor’s register,
it selects the chip by pulling down the Slave Select line
(ss_n). When selected, data is sent serially and synchronous
to the SPI clock (sck).
Figure 11 shows the communication protocol for read and
write accesses of the SPI registers. The MANO 9600 sensor
uses 9-bit addresses and 16-bit data words.
Data driven by the system is colored blue in Figure 11,
while data driven by the sensor is colored yellow. The data
in grey indicates high-Z periods on the miso interface. Red
markers indicate sampling points for the sensor (mosi
sampling); green markers indicate sampling points for the
system (miso sampling during read operations).
The access sequence is:
1. Select the sensor for read or write by pulling down
the ss_n line.
2. One SPI clock cycle after selecting the sensor, the
9-bit data is transferred, most significant bit first.
The sck clock is passed through to the sensor as
SP I − W R ITE
ss_n
t_sc ks s
ts ck
t_sssck
sck
ts _mos i
mo si
A8
th_mosi
A7
..
..
..
A1
A0
`1'
D15
D14
..
..
..
..
D1
D0
miso
SPI − REA D
ss_n
t_sssck
t_sc ks s
ts ck
sck
ts_mosi
mo si
A8
th_mosi
A7
..
..
..
A1
A0
`0'
ts _mi so
miso
D15
th_mi so
D14
..
..
Figure 11. SPI Read and Write Timing Diagram
http://onsemi.com
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..
..
D1
D0
NOIM1SM9600A, NOIM2SM9600A
Rolling Shutter Mode
frame rate by adding so called dummy lines. A dummy line
lasts for the same time as a regular line, but no pixel data is
transferred to the system. The number of dummy lines is
controlled by the register dummy_lines. The rolling shutter
exposure mechanism is graphically shown in Figure 12.
The exposure time during rolling shutter mode is always
an integer multiple of line-times. The exposure time is
defined by the register exposure and expressed in number of
lines. The register fr_length and mult_timer are not used in
this mode.
The maximum exposure time is limited by the frame time.
It is possible to increase the exposure time at the cost of the
Figure 12. Integration Control in Rolling Shutter Mode
It is clear that when the number of rows and/or the length
of a row are reduced (by windowing or subsampling), the
frame time decreases and consequently the frame rate
increases.
To be able to artificially increase the frame time, it is
possible to:
• add dummy clock cycles to a row time
• add dummy rows to the frame
Note:
The duration of one line is the sum of the ROT and the time
required to read out one line (depends on the number of
active kernels in the window). Optionally, this readout time
can be extended by the configuration rs_x_length. This
register, expressed in number of periods of the logic clock
(16.129 ns for the M1-SM version and 64.516 ns for the
M2-SM version), determines the length of the x-readout.
However, the minimum for rs_x_length is governed by the
window size (x-size).
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NOIM1SM9600A, NOIM2SM9600A
ADDITIONAL FEATURES
• x−start[8:0]
Multiple Window Readout
The MANO9600 sequencer supports windowed readout.
The user can limit the data output per frame, which allows
increasing the frame rate.
x-start defines the x-starting point of the desired window.
The sensor reads out 8 pixels in one single clock cycle. As
a consequence, the granularity for configuring the x-start
position is also 8 pixels for no sub sampling. The value
configured in the x-start register is multiplied by 8 to find the
corresponding column in the pixel array when there is no
subsampling / binning.
• x-end[8:0]
This register defines the window end point on the x-axis.
Similar to x-start, the granularity for this configuration is
one kernel. x-end needs to be larger than x-start.
• y-start[12:0]
The starting line of the readout window. The granularity
of this setting is one line.
• y-end[12:0]
The end line of the readout window. y-end must be
configured larger than y-start. This setting has the same
granularity as the y-start configuration.
Pixel array addressing scheme for no−subsampling/
binning.
Address mapping of pixel array rows to on−chip
sequencer is shown in Table 21 as per following formula:
Y-address of sequencer = row number
Window Configuration
Only a single window is supported. Do not activate more
than one window (register 195). However, it is possible to
configure more than one window and dynamically switch
between the different window configurations. Note that
switching between two different windows might result in a
corrupted frame. This is inherent in the rolling shutter
mechanism, where each line must be reset sequentially
before being read out. This corrupted window can be
blanked out by setting register 206[8]. In this case, a dead
time is noted on the LVDS interface when the
window−switch occurs in the sensor. During this blank out,
training patterns are sent out on the data and sync channels
for the duration of one frame.
Silicon Restriction when Switching between ROIs
• TRIGGER CONDITION(S)
♦ Y_start line is lower than previous y_start line
• SCOPE OF IMPACT
♦ Frame_valid fails and sensor stops operating
• RECOMMENDATION
♦ Ensure that register 206[8] = 1. (blank_roi_switch)
♦ To set a new roi:
reg 206[5] = 0 // Disable sync_roi
… // Update roi−settings of the _active_roi here.
reg 206[5] = 1 // Re−enable sync_roi
Table 21. SEQUENCER Y-ADDRESS MAPPING FOR
NO-SUBSAMPLING / BINNING
Figure 13 shows the four parameters defining a region of
interest (ROI).
3480 pixels
2500 pixels
y-end
y-start
Row number
Sequencer Y-address
0
0
1
1
2
2
3
3
4
4
5
5
…
…
…
…
2497
2497
2498
2498
2499
2499
Even columns of pixel array are addressed by the
sequencer through following mapping:
X-address of sequencer × 8 + 1 = pixel array column
number
Odd columns of pixel array are addressed by sequencer
through following mapping:
(X-address of sequencer − 1) × 8 + 1 = pixel array column
number
Table 22 shows the column to its read out address mapping
in sequencer for even and odd kernels of a row.
x-start x-end
Figure 13. Region of Interest Configuration
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NOIM1SM9600A, NOIM2SM9600A
Subsampling and Binning
Table 22. SEQUENCER X-ADDRESS MAPPING FOR
NO-SUBSAMPLING / BINNING
Pixel Array Column No.
Kernel
Number
Sequencer
X-address
0−14 (every second pixel)
0
0
1−15 (every second pixel)
1
1
16−30 (every second pixel)
2
2
17−31 (every second pixel)
3
3
−
−
−
3808−3822 (every second pixel)
476
476
3809−3823 (every second pixel)
477
477
3824−3838 (every second pixel)
478
478
3825−3839 (every second pixel)
479
479
Subsampling is used to reduce the image resolution. This
allows increasing the frame rate. Two subsampling modes
are supported: Read−1−Skip−1 and checkerboard
subsampling. Pixel binning is also supported to increase the
dynamic range of the sensor. Two binning schemes are
supported: 1x2 and 2x2. During these sub−sampling/
binning schemes, address mapping of pixel array rows and
columns to on−chip sequencer Y−address and X−address
respectively, is different from no−subsampling. So user
should configure windows according to the appropriate
address mapping explained in detail for each subsampling/
binning scheme in following sections.
Following table shows an example of freezing and
releasing of the register updates, to reconfigure
subsampling/binning scheme.
Table 23. UPLOAD SEQUENCE FOR SUBSAMPLING / BINNING
Addresses
Data
206[5]
0x0
Description
De−assert sync_roi. The sensor continues with its previous configurations.
232
Enable/disable the required sub−sampling / binning as mentioned in detail in register map,
given in Table 45 on page 44
230
Reconfigure Y−start offset and black line address as mentioned in detail in register map,
given in Table 45 on page 44 for required subsampling / binning
231
Reconfigure last line address as mentioned in detail in register map,
given in Table 45 on page 44 for required subsampling / binning
206[5]
0x1
Assert sync_roi, to enable above uploads for next frame. This Reconfiguration will cause one
frame to be blanked out.
2 y 2 Binning
The 2 × 2 binning scheme can also be enabled. During this
binning scheme, pixels being readout are charge binned
(summed) with pixel adjacent to them in the next row (in
Y−direction) and then charge binned pixels of two rows are
voltage binned (averaged) with adjacent charge binned
pixels in X−direction. (See Table 15).
Read-1-Skip-1
The read−1−skip−1 subsampling scheme can be enabled.
Subsampling occurs both in x− and y− direction. Figure 14
shows which pixels are read and which ones are skipped.
Y
Y
read
X
pixel (0;0)
skip
pixel (0;0)
Charge (summing)
binning in y−direction
X
Figure 14. Read-1-Skip-1 Subsampling
Voltage (averaging)
binning after above
summing in x−direction
Figure 15. 2 x 2 Binning
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NOIM1SM9600A, NOIM2SM9600A
Row/column address mapping during read−1−skip−1
subsampling and 2 y 2 binning.
During read−1−skip−1 sub−sampling, only even pixels of
every alternative row are read out. These rows are addressed
by on−chip sequencer according to the following formula:
Y−sequencer address of a row = row number / 2
For 2 × 2 binning, mapping of binned rows is done to
sequencer addresses according to the following formula.
Y−sequencer address of a row = Binning of (row
number / 2, row number / 2+1), where Y−address = row
number / 2.
Table 24. SEQUENCER Y-ADDRESS MAPPING FOR
READ-1-SKIP-1 SUBSAMPLING AND 2 x 2 BINNING
Row No. (for R1S1
subsampling)
Row No.
(for 2 x 2 binning)
Sequencer
Y-address
0
(0,1)
0
2
(2,3)
1
4
(4,5)
2
6
(6,7)
3
…
…
…
2494
(2494, 2495)
1247
2496
(2496, 2497)
1248
2498
(2498, 2499)
1249
Table 24 shows address mapping of rows to be read out in
read−1−skip−1 subsampling and 2 × 2 binning mode to the
sequencer Y−address.
Table 25 shows the address mapping of pixel array columns to X−address in sequencer for read−1−skip−1 subsampling and
2 × 2 binning schemes.
Table 25. SEQUENCER X-ADDRESS MAPPING FOR READ-1-SKIP-1 SUBSAMPLING AND 2 x 2 BINNING
Pixel Array Even Column No.
(for R1S1 subsampling)
Pixel Array Even Column No.
(for 2 x 2 binning)
Kernel No.
Sequencer
X-address
0−14 (every second pixel)
(0,1) − (14,15)
0
0
16−30 (every second pixel)
(16,17) − (30,31)
1
1
…
…
…
…
3808−3822 (every second pixel)
(3808,3809) − (3822,3823)
238
238
3824−3838 (every second pixel)
(3824,3825) − (3838,3839)
239
239
1 y 2 Binning
The 1 × 2 binning can be enabled to increase the dynamic
range. During this binning scheme, pixels being read out are
charge binned (summed) with adjacent pixels in the same
column, as shown in Figure 17.
Checkerboard Subsampling
In this subsampling scheme, read out of even pixels of one
row is followed by odd pixels of the next row. Figure 16
shows the pixels that are read and the pixels that are skipped.
Y
1 x 2 charge
(summing)
binning
Y
read
pixel (0;0)
skip
pixel (0;0)
X
Figure 17. 1 x 2 Binning Scheme
X
Figure 16. Checkerboard Subsampling
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NOIM1SM9600A, NOIM2SM9600A
Row/column addressing scheme during checkerboard
subsampling and 1 y 2 binning
During check−board pattern subsampling, readout of
even pixel segment (only even pixels of row) of a row is
followed by odd pixel segment (only odd pixels of row) of
next row. These segments are addressed according to
following relation:
Y−address of even pixel segment of even row = row number
Y−address of odd pixel segment of odd row = row number
Address mapping of rows to Y−address during
checkerboard subsampling is shown in Table 26.
For checkerboard subsampling, columns for even pixels
of an even row are addressed with mapping shown in
Table 28, which is according to the following formula.
X−address of sequencer × 8 × 2 = Pixel array column
number
Columns for odd pixels of an odd row are addressed with
mapping shown in Table 29, which is according to the
following formula.
Table 28. SEQUENCER X-ADDRESS MAPPING FOR
EVEN PIXELS OF EVEN ROWS DURING
CHECKERBOARD SUBSAMPLING
Table 26. SEQUENCER Y-ADDRESS MAPPING FOR
CHECKERBOARD SUBSAMPLING
Pixel Array Even Column No.
Kernel
Number
Sequencer
X-address
0−14 (every second pixel)
0
0
16−30 (every second pixel)
1
1
Row No.
(checkerboard
subsampling)
Row Segment
(checkerboard
subsampling)
Sequencer
Y-address
0
Even
0
−
−
−
238
238
239
239
1
Odd
1
3808−3822 (every second pixel)
2
Even
2
3824−3838 (every second pixel)
3
Odd
3
4
Even
4
5
Odd
5
…
…
…
2494
Even
2494
2495
Odd
2495
2496
Even
2497
2498
2499
Table 29. SEQUENCER X-ADDRESS MAPPING FOR
ODD PIXELS OF ODD ROWS DURING
CHECKERBOARD SUBSAMPLING
Kernel
Number
Sequencer
X-address
0−15 (every second pixel)
0
0
2496
17−31 (every second pixel)
1
1
Odd
2497
−
−
−
Even
2498
3809−3823 (every second pixel)
238
238
2499
3825−3839 (every second pixel)
239
239
Odd
Pixel Array Even Column No.
For 1 × 2 binning, even columns of pixel array are
addressed by sequencer with the following mapping:
X−address of sequencer × 8 = pixel array column number
Odd columns of pixel array are addressed by sequencer
with the following mapping:
(X−address of sequencer − 1) × 8 + 1 = pixel array column
number
Table shows the column to its X−address mapping in
sequencer for 1 × 2 binning.
For 1 × 2 binning, every pixel in one row is binned with
adjacent pixel of its next row, so there is one output data row,
for every two consecutive rows.
Y−address of sequencer × 2 = binning of (row number,
row number + 1), where Y−address = row number/2
For 1 × 2 binning, row address mapping to sequencer is
shown in Table 27.
Table 27. SEQUENCER Y-ADDRESS MAPPING FOR
1 x 2 BINNING
Row No. (1 x 2 binning)
Sequencer Y-address
(0, 1)
0
(2, 3)
1
(4, 5)
2
(6, 7)
Table 30. SEQUENCER X-ADDRESS MAPPING FOR
1 x 2 BINNING
Pixel Array Column No.
Kernel
Number
Sequencer
X-address
0−14 (every second pixel)
0
0
3
1−15 (every second pixel)
1
1
…
…
16−30 (every second pixel)
2
2
…
…
17−31 (every second pixel)
3
3
(2496, 2497)
1248
−
−
−
(2498, 2499)
1249
3808−3822 (every second pixel)
476
476
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NOIM1SM9600A, NOIM2SM9600A
3809−3823 (every second pixel)
477
477
3824−3838 (every second pixel)
478
478
3825−3839 (every second pixel)
479
479
The black references are used to perform black calibration
and offset compensation in the data channels. The raw black
pixel data is transmitted over the usual output interface,
while the regular image data is compensated (can be
bypassed).
On the output interface, black lines can be seen as a
separate window, however without Frame Start and Ends
(only Line Start/End). The Sync code following the Line
Start and Line End indications (“window ID”) contains the
active window number for rolling shutter operation. Black
reference data is classified by a BL code.
Black line address should be configured through SPI
register 230[9:5] according to the following table.
Black Calibration
The sensor automatically calibrates the black level for
each frame. Therefore, the device generates a configurable
number of electrical black lines at the start of each frame.
The desired black level in the resulting output interface can
be configured and is not necessarily targeted to ‘0’.
Configuring the target to a higher level yields some
information on the left side of the black level distribution,
while the other end of the distribution tail is clipped to ‘0’
when setting the black level target to ‘0’.
The black level is calibrated for the 8 columns contained
in one kernel. Configurable parameters for the black−level
algorithm are listed in Table 20.
Table 31. BLACK LINE ADDRESS FOR DIFFERENT
SUBSAMPLING AND BINNING SCHEMES
Scheme / Pixel Architecture
Black Line Address
Normal
2
R1S1
1
R2S2
1
Checkerboard
2
1 x 2 binning
1
2 x 2 binning
1
Black Reference
The sensor reads out one or more black lines at the start of
every new frame. The number of black lines to be generated
is programmable and is minimal equal to 1. The length of the
black lines depends on the operation mode. For rolling
shutter mode, the length of the black line is equal to the line
length configured in the active window.
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NOIM1SM9600A, NOIM2SM9600A
Signal Path Gain
Digital Gain Stage
The digital gain stage allows fine gain adjustments on the
digitized samples. The gain configuration is an absolute 5.7
unsigned number (5 digits before and 7 digits after the
decimal point).
Interpreting the actual temperature for the digital code
readout:
The formula used is
TJ = R (Nread - Ncalib) + Tcalib
TJ = junction die temperature
R = resolution in degrees/LSB (typical 0.75 deg/LSB)
Nread = Tsensor output (LSB count between 0 and 255)
Tcalib = Tsensor calibration temperature
Ncalib = Tsensor output reading at Tcalib
Automatic Exposure Control
Monitor Pins
Analog Gain Stages
The default settings are optimized for the best
performance.
The default settings are optimized for the best
performance.
The internal sequencer has two monitor outputs (Pin 44
and Pin 45) that can be used to communicate the internal
states from the sequencer. A three-bit register configures the
assignment of the pins.
Temperature Sensor
The MANO 9600 has an on-chip temperature sensor
which can output a digital code (Tsensor) of the silicon
junction temperature. The Tsensor output is a 8-bit digital
count between 0 and 255, proportional to the temperature of
the silicon substrate. This reading can be translated directly
to a temperature reading in °C by calibrating the 8-bit
readout at 0°C and 70°C to achieve an output accuracy of
±2°C. The Tsensor output can also be calibrated using a
single temperature point (example: room temperature or the
ambient temperature of the application), to achieve an
output accuracy of ±5°C.
The resolution of the temperature sensor in ºC / bit is made
almost constant over process variations by design.
Therefore any process variation will result in an offset in the
bit count and this offset will remain within ±5°C over the
temperature range of 0°C and 70°C.
Tsensor output digital code can be read out through the
SPI interface. Refer to the Register Map on page 44.
The output of the temperature sensor to the SPI:
tempd_reg_temp<7:0>: This is the 8-bit N count readout
proportional to temperature.
The input from the SPI:
The reg_tempd_enable is a global enable and this enables
or disables the temperature sensor when logic high or logic
low respectively. The temperature sensor is reset or disabled
when the input reg_tempd_enable is set to a digital low state.
Calibration using one temperature point
The temperature sensor resolution is fixed for a given type
of package for the operating range of 0°C to +70°C and
hence devices can be calibrated at any ambient temperature
of the application, with the device configured in the mode of
operation.
Table 32. REGISTER SETTING FOR THE MONITOR
SELECT PIN
monitor_select
[2:0]
192 [13:11]
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monitor
pin
Description
0x0
monitor0
monitor1
‘0’
‘0’
0x1
monitor0
monitor1
Integration Time
ROT Indication (‘1’ during
ROT, ‘0’ outside)
0x2
monitor0
monitor1
Integration Time
Dual/Triple Slope Integration
(asserted during DS/TS FOT
sequence)
0x3
monitor0
monitor1
Start of x-Readout Indication
Black Line Indication (‘1’
during black lines,
‘0’ outside)
0x4
monitor0
monitor1
Frame Start Indication
Start of ROT Indication
0x5
monitor0
monitor1
First Line Indication
(‘1’ during first line, ‘0’ for all
others)
Start of ROT Indication
0x6
monitor0
monitor1
ROT Indication (‘1’ during
ROT, ‘0’ outside)
Start of X-Readout
Indication
0x7
monitor0
monitor1
Start of X-readout Indication
for Black Lines
Start of X-readout Indication
for Image Lines
NOIM1SM9600A, NOIM2SM9600A
DATA OUTPUT FORMAT
The MANO 9600 is available in two different versions:
Frame Format
The frame format is explained by example of the readout
of two (overlapping) windows as shown in Figure 18 (a).
The readout of a frame occurs on a line-by-line basis. The
read pointer goes from left to right, bottom to top.
Figure 18 indicates that, after the FOT is completed, the
sensor reads out a number of black lines for black calibration
purposes. After these black lines, the windows are
processed. First a number of lines which only includes
information of ‘ROI 0’ are sent out, starting at position
y0_start. When the line at position y1_start is reached, a
number of lines containing data of ‘ROI 0’ and ‘ROI 1’ are
sent out, until the line position of y0_end is reached. From
there on, only data of ‘ROI 1’ appears on the data output
channels until line position y1_end is reached.
During read out of the image data over the data channels,
the sync channel sends out frame synchronization codes
which give information related to the image data that is sent
over the four data output channels.
Each line of a window starts with a Line Start (LS)
indication and ends with a Line End (LE) indication. The
line start of the first line is replaced by a Frame Start (FS);
the line end of the last line is replaced with a Frame End
indication (FE). Each such frame synchronization code is
followed by a window ID (range 0 to 7). For overlapping
windows, the line synchronization codes of the overlapping
windows with lower IDs are not sent out (as shown in the
illustration: no LE/FE is transmitted for the overlapping part
of window 0).
NOTE: In Figure 18, only Frame Start and Frame End
Sync words are indicated in (b). CRC codes are
also omitted from the figure.
• M1-SM: Four LVDS output channels, together with an
•
LVDS clock output and an LVDS synchronization
output channel.
M2-SM: A 10-bit parallel CMOS output, together with
a CMOS clock output and ‘frame valid’ and ‘line valid’
CMOS output signals.
M1-SM: LVDS Interface Version
LVDS Output Channels
The image data output occurs through four LVDS data
channels where a synchronization LVDS channel and an
LVDS output clock signal synchronizes the data.
The four data channels are used to output the image data
only. The sync channel transmits information about the data
sent over these data channels (includes codes indicating
black pixels, normal pixels, and CRC codes).
8-bit / 10-bit Mode
The sensor can be used in 8-bit or 10-bit mode.
In 10-bit mode, the words on data and sync channel have
a 10-bit length. The output data rate is 620 Mbps.
In 8-bit mode, the words on data and sync channel have an
8-bit length, the output data rate is 496 Mbps.
Note that the 8-bit mode can only be used to limit the data
rate at the consequence of image data word depth. It is not
supported to operate the sensor in 8-bit mode at a higher
clock frequency to achieve higher frame rates.
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NOIM1SM9600A, NOIM2SM9600A
y1_end
ROI 1
y0_end
y1_start
ROI 0
y0_start
x0_start
x0_end
x1_start
x1_end
(a)
Integration Time
Handling
Readout
Handling
FOT
É
É
B
L
Reset
N
Exposure Time N
FOT
Readout Frame N-1
ROI
1
ROI 0
FS0
FS1
FOT
FE1
Reset
N+1
É
É
Exposure Time N+1
FOT
Readout Frame N
B
L
ROI
1
ROI 0
FS0
FS1
FOT
FE1
(b)
Figure 18. M1−SM: Frame Sync Codes
Figure 19 shows the detail of a black line readout during global or full-frame readout.
Sequencer
Internal State
FOT
ROT
ROT
black
line Ys
ROT
ROT
line Ys+1
line Ye
data channels
sync channel
data channels
sync channel
Training
TR
Training
LS
0
timeslot
0
BL
BL
BL
timeslot
1
BL
timeslot
157
BL
BL
timeslot
158
LE
0
timeslot
159
CRC
CRC
timeslot
Figure 19. M1−SM: Time Line for Black Line Readout
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TR
NOIM1SM9600A, NOIM2SM9600A
Figure 20 shows the details of the readout of a number of lines for single window readout, at the beginning of the frame.
Sequencer
Internal State
FOT
ROT
ROT
black
line Ys+1
ROT
line Ys
line Ye
ROT
data channels
sync channel
Training
data channels
TR
sync channel
Training
FS
ID
timeslot
Xstart
IMG
IMG
IMG
timeslot
Xstart + 1
IMG
timeslot
Xend - 2
IMG
IMG
timeslot
Xend - 1
LE
ID
CRC
timeslot
Xend
TR
CRC
timeslot
Figure 20. M1−SM: Time Line for Single Window Readout (at the start of a frame)
Figure 21 shows the detail of the readout of a number of lines for readout of two overlapping windows.
Sequencer
Internal State
FOT
black
ROT
ROT
line Ys
ROT
line Ys+1
ROT
line Ye
data channels
sync channel
data channels
sync channel
Training
Training
TR
LS
IDM
IMG
IMG
LS
timeslot
XstartM
IDN
IMG
IMG
IMG LE
timeslot
XstartN
IDN
CRC
TR
timeslot
XendN
Figure 21. M1−SM: Time Line Showing the Readout of Two Overlapping Windows
active at the same time, the sync channel transmits the frame
synchronization codes of the window with highest index
only.
Frame Synchronization for 10−bit Mode
Table 33 shows the structure of the frame synchronization
code. Note that the table shows the default data word
(configurable) for 10-bit mode. If more than one window is
Table 33. FRAME SYNCHRONIZATION CODE DETAILS FOR 10-BIT MODE
Sync Word Bit
Position
Register
Address
Default
Value
9:7
N/A
0x5
Frame start indication
9:7
N/A
0x6
Frame end indication
9:7
N/A
0x1
Line start indication
Line end indication
9:7
N/A
0x2
6:0
131[6:0]
0x2A
Description
These bits indicate that the received sync word is a frame synchronization code. The
value is programmable by a register setting
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• Window Identification
• Data Classification Codes
Frame synchronization codes are always followed by a
3-bit window identification (bits 2:0). This is an integer
number, ranging from 0 to 7, indicating the active window.
If more than one window is active for the current cycle, the
highest window ID is transmitted.
For the remaining cycles, the sync channel indicates the
type of data sent through the data links: black pixel data
(BL), image data (IMG), or training pattern (TR). These
codes are programmable by a register setting. The default
values are listed in Table 31.
Table 34. SYNCHRONIZATION CHANNEL DEFAULT IDENTIFICATION CODE VALUES FOR 10-BIT MODE
Sync Word Bit
Position
Register
Address
Default
Value
9:0
132 [9:0]
0x015
Black pixel data (BL). This data is not part of the image. The black pixel data is used internally to correct channel offsets.
9:0
133 [9:0]
0x035
Valid pixel data (IMG). The data on the data output channels is valid pixel data (part of the
image).
9:0
134 [9:0]
0x059
CRC value. The data on the data output channels is the CRC code of the finished image
data line.
9:0
135 [9:0]
0x3A6
Training pattern (TR). The sync channel sends out the training pattern which can be programmed by a register setting.
Description
and not sent out. Table 32 shows the structure of the frame
synchronization code, together with the default value, as
specified in SPI registers. The same restriction for
overlapping windows applies in 8-bit mode.
Frame Synchronization in 8-bit Mode
The frame synchronization words are configured using
the same registers as in 10-bit mode. The two least
significant bits of these configuration registers are ignored
Table 35. FRAME SYNCHRONIZATION CODE DETAILS FOR 8-BIT MODE
Sync Word Bit
Position
Register
Address
Default
Value
7:5
N/A
0x5
Frame start (FS) indication
7:5
N/A
0x6
Frame end (FE) indication
7:5
N/A
0x1
Line start (LS) indication
7:5
N/A
0x2
Line end (LE) indication
4:0
[6:2]
0x0A
Description
These bits indicate that the received sync word is a frame synchronization code. The
value is programmable by a register setting.
• Window Identification
• Data Classification Codes
Similar to 10-bit operation mode, the frame
synchronization codes are followed by a window
identification. The window ID is located in bits 4:2 (all other
bit positions are ‘0’). The same restriction for overlapping
windows applies in 8-bit mode.
BL, IMG, CRC, and TR codes are defined by the same
registers as in 10-bit mode. Bits 9:2 of the respective
configuration registers are used as classification code with
default values shown in Table 33.
Table 36. SYNCHRONIZATION CHANNEL DEFAULT IDENTIFICATION CODE VALUES FOR 8-BIT MODE
Sync Word Bit
Position
Register
Address
Default
Value
7:0
132 [9:2]
0x05
Black pixel data (BL). This data is not part of the image. The black pixel data is used
internally to correct channel offsets.
7:0
133 [9:2]
0x0D
Valid pixel data (IMG). The data on the data output channels is valid pixel data (part of
the image).
7:0
134 [9:2]
0x16
CRC value. The data on the data output channels is the CRC code of the finished image
data line.
7:0
135 [9:2]
0xE9
Training Pattern (TR). The sync channel sends out the training pattern which can be
programmed by a register setting.
Description
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NOIM1SM9600A, NOIM2SM9600A
In 8-bit mode, the training pattern for the data channels is
defined by the same register as in 10-bit mode, where the
lower two bits are omitted; see Table 35.
Training Patterns on Data Channels
In 10-bit mode, during idle periods, the data channels
transmit training patterns, indicated on the sync channel by
a TR code. These training patterns are configurable
independent of the training code on the sync channel as
shown in Table 34.
Table 37. TRAINING CODE ON SYNC CHANNEL IN 10-BIT MODE
Sync Word Bit
Position
Register
Address
Default
Value
[9:0]
130 [9:0]
0x3A6
Description
Data channel training pattern. The data output channels send out the training pattern,
which can be programmed by a register setting. The default value of the training pattern
is 0x3A6, which is identical to the training pattern indication code on the sync channel.
Table 38. TRAINING PATTERN ON DATA CHANNEL IN 8-BIT MODE
Data Word Bit
Position
Register
Address
Default
Value
[7:0]
130 [9:2]
0xE9
Description
Data Channel Training Pattern (Training pattern).
at the start of a new line and updated for every (valid) data
word received. The CRC seed is configurable using the
crc_seed register. When ‘0’, the CRC is seeded by all-‘0’;
when ‘1’ it is seeded with all-‘1’.
In 8-bit mode, the polynomial is x8 + x6 + x3 + x2 + 1.
The CRC seed is configured by means of the crc_seed
register.
Note The CRC is calculated for every line. This implies
that the CRC code can protect lines from multiple windows.
Cyclic Redundancy Code
At the end of each line, a CRC code is calculated to allow
error detection at the receiving end. Each data channel
transmits a CRC code to protect the data words sent during
the previous cycles. Idle and training patterns are not
included in the calculation.
The sync channel is not protected. A special character
(CRC indication) is transmitted whenever the data channels
send their respective CRC code.
The polynomial in 10-bit operation mode is
x10 + x9 + x6 + x3 + x2 + x + 1. The CRC encoder is seeded
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kernels is read out descending. Similarly, all even pairs of
kernels are read out in ascending order and odd pairs of
kernel are read out in descending order.
Table 39 indicates the pixel data order of each channel for
1st 16 data−outputs. Shaded grey cells shows data order for
even pair of kernels and the non−shaded cells shows data
order for odd pair of kernels.
Data Order for M1−SM
To read out the image data through the output channels,
the pixel array is organized in kernels. Each row consists of
480 kernels. Even positioned kernel consists of 8
consecutive even pixels and odd positioned kernel consists
of 8 consecutive odd kernels. So the kernel size is 8 pixels
in x−direction by 1 pixel in y−direction. Figure 22 indicates
how the kernels are organized. The first kernel (kernel [0, 0])
is located in the bottom left corner. The data order of this
image data on the data output channels depends on the
subsampling mode.
Data
Number
Pixels on
Channel 0
Pixels on
Channel 1
Pixels on
Channel 2
Pixels on
Channel 3
0
0
4
8
12
1
2
6
10
14
2
1
5
9
13
3
3
7
11
15
4
30
26
22
18
5
28
24
20
16
6
31
27
23
19
7
29
25
21
17
8
32
36
40
44
9
34
38
42
46
10
33
37
41
45
kernel
(479,2499)
pixel array
ROI
kernel
(x_start,y_start)
5
6
7
Figure 22. Kernel Organization in Pixel Array
• M1−SM: No Subsampling
The image data is read out in kernels of eight pixels in
x−direction by one pixel in y−direction. One data channel
output delivers two pixel values of one kernel sequentially.
Figure 23 shows how a kernels are read out over the four
output channels. Each row consists of 480 kernels. First pair
of kernels is read out ascending, while the next pair of
11
35
39
43
47
12
62
58
54
50
13
60
56
52
48
14
63
59
55
51
15
61
57
53
49
1st kernel of 2nd pair
22
18
channel#2
20
16
31
29
27
channel #0
24
channel#3
26
channel #1
28
channel #0
30
2nd kernel of 2nd pair
25
23
21
19
17
channel#3
3
1st pair of kernel
kernel 0
kernel 1
kernel 2
kernel 3
2nd pair of kernel
1st kernel of 1st pair
10
12
14
1
3
channel #0
8
channel#3
6
channel#2
4
channel #1
2
channel #0
0
2nd kernel of 1st pair
5
7
9
11
13
15
channel#3
2
channel#2
1
channel #1
0
pixel
(3839,0)
channel#2
kernel
(0,0)
channel #1
pixel
(0,2499)
Table 39. M1−SM: DATA OUTPUT ORDER WHEN
SUBSAMPLING IS DISABLED
Figure 23. M1−SM: Data Output Order when Subsampling is Disabled
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• M1−SM: Read−1−Skip−1 Subsampling
kernels. Data for even kernels are read out in ascending
order and for odd kernels it is read out in descending order
as shown in Figure 24. Table 40 shows the data order for first
eight data outputs of a row.
For read−1−skip−1 sub−sampling, only even pixels of a
row are readout with next full row of pixels (even/odd pixels
of next row) skipped. Hence one line is read out in 240
kernel 1
kernel 2
12
channel#2
10
MSB
14
30
LSB
28
MSB
10−bit
26
24
22
20
18
16
channel#3
8
channel #0
6
channel#3
4
channel #1
2
channel #0
0
pixel # (odd kernel)
channel#2
pixel # (even kernel)
kernel 3
channel #1
kernel 0
Note: The bit order is always MSB first,
regardless the kernel number
LSB
10−bit
Figure 24. M1−SM: Data Output Order for Read−1−Skip−1 Subsampling
Table 40 shows data order for readout of even and odd
kernels for read−1−skip−1 subsampling for first eight data
outputs on output channels.
Note that there is no difference in data order for even/odd
kernel numbers, as opposed to the ‘no−subsampling’
readout.
M1−SM: Checkerboard Subsampling
Table 40. M1−SM: DATA OUTPUT ORDER
READ−1SKIP−1 SUBSAMPLING
Data
Number
Pixels on
Channel 0
Pixels on
Channel 1
Pixels on
Channel 2
Pixels on
Channel 3
0
0
4
8
12
1
2
6
10
14
2
30
26
22
18
3
28
24
20
16
4
32
36
40
44
5
34
38
42
46
6
62
58
54
50
7
60
56
52
48
For checkerboard subsampling, readout of even pixels of
one row is followed by readout of odd pixels of the next row.
Figure 25 and Figure 40 show how a even and odd kernels
are read out over the four output channels, for even and odd
pixels segment of a row respectively. Each segment consists
of 240 kernels. For even pixel segment of a row, even
positioned kernels are read out ascending, while for odd
positioned kernels the data order is reversed (descending).
For odd pixel segment of a line also, even positioned kernels
are read out ascending, while for odd positioned kernel the
data order is reversed (descending).
Note that a window should always start at an even
x−address, such that the first kernel of a segment is always
at an even position.
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kernel 1
kernel 2
channel#2
10
12
14
30
28
26
24
22
20
18
16
channel#3
8
channel #0
6
channel#3
4
channel #1
2
channel #0
0
pixel # (odd kernel)
channel#2
pixel # (even kernel)
kernel 3
channel #1
kernel 0
Note: The bit order is always MSB first,
regardless the kernel number
MSB
LSB
MSB
10−bit
LSB
10−bit
Figure 25. M1−SM: Data Output Order for Even Pixels of Line During Checkerboard Subsampling
Table 41 shows data order for readout of even and odd
kernels of even pixels of a line for first eight data outputs on
output channels.
Table 42 shows data order for readout of even and odd
kernels of odd pixels of a line for first eight data outputs on
output channels.
Table 41. M1−SM: DATA OUTPUT ORDER FOR EVEN
PIXELS OF LINE DURING CHECKERBOARD
SUBSAMPLING
Table 42. M1−SM: DATA OUTPUT ORDER FOR ODD
PIXELS OF LINE DURING CHECKERBOARD
SUBSAMPLING
Data
Number
Pixels on
Channel 0
Pixels on
Channel 1
Pixels on
Channel 2
Pixels on
Channel 3
Data
Number
Pixels on
Channel 0
Pixels on
Channel 1
Pixels on
Channel 2
Pixels on
Channel 3
0
0
4
8
12
0
1
5
9
13
1
2
6
10
14
1
3
7
11
15
2
30
26
22
18
2
31
27
23
19
3
28
24
20
16
3
29
25
21
17
4
32
36
40
44
4
33
37
41
45
5
34
38
42
46
5
35
39
43
47
6
62
58
54
50
6
63
59
55
51
7
60
56
52
48
7
61
57
53
49
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NOIM1SM9600A, NOIM2SM9600A
kernel 1
kernel 2
Pixel # (odd kernel)
15
31
29
27
25
time
MSB
LSB
MSB
10−bit
LSB
23
time
21
19
17
channel#3
13
channel#2
11
channel #0
9
channel#3
7
channel #1
5
channel #0
3
channel#2
Pixel # (even kernel)
1
kernel 3
channel #1
kernel 0
Note: The bit order is always MSB first
10−bit
Figure 26. M1−SM: Data Output Order for Odd Pixels of Line During Checkerboard Subsampling
M1−SM: 1 x 2 Binning
that every pixel in even row is binned with the corresponding
pixel in the next odd row.
For 1 × 2 binning, every pixel in an even row is binned
with a similar positioned pixel in the odd row. Data output
format is the same as readout of normal row readout with no
subsampling. Data order is similar to that shown in
Figure 23 and Table 40 on page 37. The only difference is
For 2 × 2 binning, data order for even and odd kernel is
shown in Figure 27, showing binning between two adjacent
pixels in X−direction for row 0 and row 1.
kernel 1
kernel 2
channel#2
10,11
12,13
14,15
30,31
28,29
26,27
24,25
22,23
20,21
18,19
16,17
channel#3
8,9
channel #0
6,7
channel#3
4,5
channel #1
2,3
channel #0
0,1
pixel # (odd kernel)
channel#2
pixel # (even kernel)
kernel 3
channel #1
kernel 0
M1−SM: 2 x 2 Binning
Note:
Binning of 22,23 pixel of row 0 and 22,23
pixel of row1.
The bit order is always MSB first
MSB
LSB
10−bit
MSB
LSB
10−bit
Figure 27. M1−SM: Data Output Order for 2 x 2 Binning
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Table 43 shows data order for 2 × 2 binning of two pixels
in even row with same pixel# in odd row for first eight data
outputs on output channels.
Frame Format
Frame timing is indicated by means of two signals:
frame_valid and line_valid.
The frame_valid indication is asserted at the start of a new
frame and remains asserted until the last line of the frame is
completely transmitted.
The line_valid indication serves the following needs:
• While the line_valid indication is asserted, the data
channels contain valid pixel data.
• The line valid communicates frame timing as it is
asserted at the start of each line and it is de-asserted at
the end of the line. Low periods indicate the idle time
between lines (ROT).
• The data channels transmit the calculated CRC code
after each line. This can be detected as the data words
right after the falling edge of the line valid.
Table 43. M1−SM: DATA OUTPUT ORDER FOR 2 x 2
BINNING
Data
Number
Pixels on
Channel 0
Pixels on
Channel 1
Pixels on
Channel 2
Pixels on
Channel 3
0
bin(0,1)
bin(4,5)
bin(8,9)
bin(12,13)
1
bin(2,3)
bin(6,7)
bin(10,11)
bin(14,15)
2
bin(30,31)
bin(26,27)
bin(22,23)
bin(18,19)
3
bin(28,29)
bin(24,25)
bin(20,21)
bin(16,17)
4
bin(32,33)
bin(36,37)
bin(40,41)
bin(44,45)
5
bin(34,35)
bin(38,39)
bin(42,43)
bin(46,47)
6
bin(62,63)
bin(58,59)
bin(54,55)
bin(50,51)
7
bin(60,61)
bin(56,57)
bin(52,53)
bin(48,49)
The readout of a frame occurs on a line−by−line basis. The
read pointer goes from left to right, bottom to top as shown
in Figure 29.
Reset handling is shown in Figure 29 (b). The row
“y_start” is reset and then after a wait period of one line time,
with line length defined by window size in X−direction,
reset pointer moves to next row “y_start + 1” and this row
is reset. And sequence will continue until row “y_end” is
reset. After exposure time, readout happens according to
readout handling shown in Figure 29 (c). After ROT, row
“y_start” is read out. Then after next ROT, the pixels of the
row addressed by “y_start + 1” are read out. And sequence
will continue until row “y_end” is read out.
M2−SM: CMOS Interface Version
CMOS Output Signals
The image data output occurs through a single 10-bit
parallel CMOS data output, operating at 62 Mbps. The
function of the CMOS clock output, ‘frame valid’ and ‘line
valid’ signal is to synchronize the output data.
No windowing information is sent out by the sensor.
8-bit/10-bit Mode
The 8-bit mode is not supported when using the parallel
CMOS output interface.
Sequencer
Internal State
FOT
ROT
black
ROT
line Ys
ROT
line Ys+1
ROT
line Ye
data channels
frame_valid
line_valid
Figure 28. M2−SM: Frame Timing Indication
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FOT
ROT
black
NOIM1SM9600A, NOIM2SM9600A
3840 columns
(3840,2500)
2500 rows
y_end
ROI
y_start
x_start
x_end
(a)
Reset handling
ROT
Reset row
y_start
ROT
Reset Row
y_start + 1
ROT
Reset Row
y_start + 2
ROT
Reset row
y_end-1
ROT
Reset Row
y_end
Readout handling
ROT
Read row
y_start
ROT
Read Row
y_start + 1
ROT
Read Row
y_start + 2
ROT
Read row
y_end-1
ROT
Read Row
y_end
FS LELSLELE
LSLS LELS LE
(b)
Frame valid
Line Valid
(c)
Figure 29. M2−SM: Frame Format to Read Out Image Data
Black Lines: Black pixel data is also sent through the data
channels. To distinguish these pixels from the regular image
data, it is possible to ‘mute’ the frame and/or line valid
indications for the black lines.
Table 44. BLACK LINE FRAME_VALID AND LINE_VALID SETTINGS
bl_frame_valid_enable
bl_line_valid_enable
0x1
0x1
The black lines are handled similar to normal image lines. The frame valid indication is asserted
before the first black line and the line valid indication is asserted for every valid (black) pixel.
0x1
0x0
The frame valid indication is asserted before the first black line, but the line valid indication is not
asserted for the black lines. The line valid indication indicates the valid image pixels only. This
mode is useful when one does not use the black pixels and when the frame valid indication needs
to be asserted some time before the first image lines (for example, to precondition ISP pipelines).
0x0
0x1
In this mode, the black pixel data is clearly unambiguously indicated by the line valid indication,
while the decoding of the real image data is simplified.
0x0
0x0
Black lines are not indicated and frame and line valid strobes remain de-asserted. Note however
that the data channels contains the black pixel data and CRC codes (Training patterns are interrupted).
Description
M2−SM: No Subsampling
Data Order
To read out the image data through the parallel CMOS
output, the pixel array is divided in kernels. The kernel size
is eight pixels in x−direction by one pixel in y−direction.
Figure 22 on page 35 indicates how the kernels are
organized.
The data order of this image data depends on the
subsampling mode.
The image data is read out in kernels of 8 pixels in
x−direction by 1 pixel in y−direction. Figure 30 shows how
a kernel is read out over parallel output channel. One row
consists of 480 kernels. These kernels are divided further
into pairs of two kernels, hence forming 240 pairs. Even pair
of kernels is read out in ascending order, while for odd pair
of kernels the data order is reversed (descending).
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time
time
30
28
26
24
22
20
18
16
31
29
1st kernel of 1st pair
27
25
23
21
19
17
2 nd kernel of 1st pair
even pair of kernel
kernel 0
kernel 1
kernel 2
kernel 3
odd pair of kernel
1st kernel of 0th pair
0
4
8
12
2
6
2nd kernel of 0th pair
10
14
1
5
9
13
3
7
11
15
time
time
Figure 30. M2−SM: Data Output Order without Subsampling
M2−SM: Read−1−Skip−1 Subsampling
pixel positions inside that kernel are read out. Figure 31
shows the data order.
Note that there is no difference in data order for even/odd
kernel numbers, as opposed to the ‘no−subsampling’
readout.
To read out the image data with subsampling enabled on
a monochrome sensor, two neighboring kernels are
combined to a single kernel of 16 pixels in the x−direction
and one pixel in the y−direction. Only the pixels at the even
kernel 0
kernel 1
kernel 2
Pixel # of even kernel
0
4
8
12
2
6
10
kernel 3
Pixel # of odd kernel
14
30
26
22
18
time
28
24
20
16
time
Figure 31. M2−SM: Data Output Order with Read−1−Skip−1 Subsampling
M2−SM: Checkerboard Subsampling
as read−1−skip−1 as shown in Figure 31. Data order for
readout of odd pixels is shown in Figure 32.
Note that there is no difference in data order for even/odd
kernel numbers, as opposed to the ‘no−subsampling’
readout.
To read out the image data with check−board pattern
sub−sampling enabled on a monochrome sensor, readout of
even pixels of one row will be followed by readout of odd
pixels of next row. Data order for even pixels will be same
kernel 0
kernel 1
kernel 2
Pixel # of even kernel
0
5
9
13
3
7
11
kernel 3
Pixel # of odd kernel
15
31
27
time
23
19
29
25
21
17
time
Figure 32. M2−SM: Data Output Order for Odd Pixel during Checkerboard Subsampling
M2−SM: 1 x 2 Binning
M2−SM: 2 x 2 Binning
For 1 × 2 binning, data output order will be same as
no−subsampling as shown in Figure 30. The only difference
is that pixels is binned with same positioned pixel in the next
row.
To read out the image data with 2 × 2 binning enabled on
a monochrome sensor, data order will be same as
read−1−skip−1sub−sampling but pixel being readout will be
binned with odd pixel next to it and same positioned pixels
in the next row as shown in Figure 33.
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kernel 0
kernel 1
kernel 2
even kernel
Binned pixel #
in row 0 and
row 1
0,1
4,5
8,9
12,13
2,3
6,7
kernel 3
odd kernel
10,11
14,15
30,31
25,27
time
22,23
18,19
28,29
time
Figure 33. M2−SM: Data Output Order for 2 x 2 Binning
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43
24,25
20,21
16,17
Binned pixel #
in row 0 and
row 1
NOIM1SM9600A, NOIM2SM9600A
REGISTER MAP
Each functional entity has a dedicated address space,
starting at a block offset. The register address is obtained by
adding the address offset to the block offset. This address
must be used to perform SPI uploads and is shown in the
Address column of the register map table.
Table 45. REGISTER MAP
Address
Offset
Address
Default
Default
(Hex)
(Dec)
chip_id
0x04D60
19808
id
Bit Field
Register Name
Description
Type
Chip ID [Block Offset: 0]
0
0
1
1
[15:0]
0x04D60
19808
reserved
0x0000
0
reserved
0x0000
0
chip_configuration
0x0000
0
0x0
0
soft_reset_pll
0x099
153
[3:0]
pll_soft_reset
0x9
9
PLL Reset
0x9: Soft Reset State
Others: Operational
[7:4]
pll_lock_soft_reset
0x9
9
PLL Lock Detect Reset
0x9: Soft Reset State
Others: Operational
soft_reset_cgen
0x09
9
cgen_soft_reset
0x9
9
0x0999
2457
[3:0]
2
RO
2
[1:0]
ON Semiconductor chip ID
RO
Reserved
RW
Configure as per part number:
NOIM1SM9600A-QDC: 0x0
NOIM2SM9600A-QDC: 0x2
Reset Generator [Block Offset: 8]
0
1
8
9
[3:0]
2
10
soft_reset_analog
RW
RW
Clock Generator Reset
0x9: Soft Reset State
Others: Operational
RW
[3:0]
mux_soft_reset
0x9
9
Column MUX Reset
0x9: Soft Reset State
Others: Operational
[7:4]
afe_soft_reset
0x9
9
AFE Reset
0x9: Soft Reset State
Others: Operational
[11:8]
ser_soft_reset
0x9
9
Serializer Reset
0x9: Soft Reset State
Others: Operational
0x0004
4
PLL [Block Offset: 16]
0
16
power_down
RW
[0]
pwd_n
0x0
0
PLL Power Down
‘0’ = Power Down,
‘1’ = Operational
[1]
enable
0x0
0
PLL Enable
‘0’ = disabled,
‘1’ = enabled
[2]
bypass
0x1
1
PLL Bypass
‘0’ = PLL Active,
‘1’ = PLL Bypassed
http://onsemi.com
44
NOIM1SM9600A, NOIM2SM9600A
Table 45. REGISTER MAP
Address
Offset
Address
1
17
Default
Default
(Hex)
(Dec)
config
0x2113
8467
[7:0]
mdiv
0x13
19
M-divider
19: 10 bit LVDS,
15: 8 bit LVDS
[12:8]
ndiv
0x1
1
N-divider
[14:13]
pdiv
0x1
1
P-divider
0x0000
0
clock_in_pwd_n
0x0
0
Power down Clock Input
reserved
0x0
0
Reserved
pll_lock
0x0000
0
0x0
0
Bit Field
Register Name
Description
Type
RW
IO [Block Offset: 20]
0
20
config
[0]
[10:8]
RW
PLL lock detector [Block Offset: 24]
0
24
[0]
lock
RO
PLL lock Indication
Clock Generator [Block Offset: 32]
0
32
0x0004
4
[0]
config
enable_analog
0x0
0
Enable analog clocks
‘0’ = disabled,
‘1’ = enabled
RW
[1]
enable_log
0x0
0
Enable logic clock
‘0’ = disabled,
‘1’ = enabled
[2]
select_pll
0x1
1
Input Clock Selection
‘0’ = Select LVDS clock input,
‘1’ = Select PLL clock input
[3]
adc_mode
0x0
0
Set operation mode
‘0’ = 10-bit mode,
‘1’ = 8-bit mode
[4]
enable_div_2
0x0
0
Enable the divide by 2 circuit
‘0’ = PLL input direct to cgen
‘1’ = Divide PLL input by 2 before
applying it to cgen
[11:8]
reserved
0x0
0
Reserved
[14:12]
reserved
0x0
0
Reserved
config
0x0000
0
enable
0x0
0
General Logic [Block Offset: 34]
0
34
[0]
http://onsemi.com
45
RW
Logic General Enable
Configuration
‘0’ = Disable
‘1’ = Enable
NOIM1SM9600A, NOIM2SM9600A
Table 45. REGISTER MAP
Address
Offset
Address
Bit Field
Register Name
Default
Default
(Hex)
(Dec)
Description
Type
Image Core [Block Offset: 40]
0
40
0x0000
0
[0]
image_core_config
imc_pwd_n
0x0
0
Image Core Power Down
‘0’ = powered down,
‘1’ = powered up
RW
[1]
mux_pwd_n
0x0
0
Column Multiplexer Power Down
‘0’ = powered down,
‘1’ = powered up
[2]
colbias_enable
0x0
0
Bias Enable
‘0’ = disabled
‘1’ = enabled
0x0000
0
0x0
0
0x0000
0
0x0
0
0x888B
34955
AFE [Block Offset:48]
0
48
power_down
[0]
pwd_n
RW
Power down for AFE’s
(64 columns)
‘0’ = powered down,
‘1’ = powered up
Bias [Block Offset: 64]
0
64
power_down
[0]
1
65
configuration
3
RW
extres
0x1
1
External Resistor Selection
‘0’ = internal resistor,
‘1’ = external resistor
[3:1]
bgrtrim
0x5
5
Bandgap Trim
[7:4]
imc_colpc_ibias
0x8
8
Column Precharge ibias
Configuration
[11:8]
imc_colbias_ibias
0x8
8
Column Bias ibias Configuration
cp_ibias
0x8
8
Charge Pump Bias
afe_bias
0x53C8
21448
[3:0]
afe_ibias
0x8
8
AFE ibias Configuration
[7:4]
afe_adc_iref
0xC
12
ADC iref Configuration
[14:8]
afe_pga_iref
PGA iref Configuration
66
67
mux_bias
0x53
83
0x08888
34952
RW
RW
[3:0]
mux_25u_stage1
0x8
8
Column Multiplexer Stage 1 Bias
Configuration
[7:4]
mux_25u_stage2
0x8
8
Column Multiplexer Stage 2 Bias
configuration
[11:8]
mux_25u_delay
0x8
8
Column Multiplexer Delay Bias
Configuration
mux_25u_vcmbuff
0x8
8
Column Multiplexer Vcm Bias
Configuration
lvds_bias
0x0088
136
lvds_ibias
0x8
8
[15:12]
4
Power down bandgap
‘0’ = powered down,
‘1’ = powered up
[0]
[15:12]
2
pwd_n
RW
68
[3:0]
http://onsemi.com
46
RW
LVDS Ibias
NOIM1SM9600A, NOIM2SM9600A
Table 45. REGISTER MAP
Address
Offset
Address
Bit Field
[7:4]
5
69
Default
Default
(Hex)
(Dec)
lvds_iref
0x8
8
fine_trim
Register Name
Description
LVDS Iref
0x0000
0
[1:0]
mux_stage1_fine_trim
0x0
0
fine trim setting for col−mux
stage1 bias
[3:2]
mux_stage2_fine_trim
0x0
0
fine trim setting for col−mux
stage2 bias
[5:4]
mux_auxamp_stage1
_fine_trim
0x0
0
fine trim setting for auxiliary
amplifier stage1 bias
[7:6]
mux_auxamp_stage2
_fine_trim
0x0
0
fine trim setting for auxiliary
amplifier stage2 bias
[9:8]
afe_5u_fine_trim
0x0
0
fine trim setting for afe bias
adcref_5u_fine_trim
0x0
0
fine trim setting for ADC reference
bias
config
0x8881
34945
reserved
0x8881
34945
sensor enable
0x0000
0
0x0
0
0x0000
0
0x00
0
0x0000
0
[11:10]
Type
RW
Col−Mux
1
81
[15:0]
RW
Temperature Sensor [Block Offset: 96]
0
96
[0]
1
97
reg_tempd_enable
sensor output
[7:0]
tempd_reg_temp
RW
Temperature Diode Enable
‘0’ = disabled
‘1’ = enabled
RO
Temperature Readout
Serializer/LVDS [Block Offset: 112]
0
112
power_down
RW
[0]
clock_out_pwd_n
0x0
0
Power down for Clock Output.
‘0’ = powered down,
‘1’ = powered up
[1]
sync_pwd_n
0x0
0
Power down for Sync channel
‘0’ = powered down,
‘1’ = powered up
[2]
data_pwd_n
0x0
0
Power down for data channels
(4 channels)
‘0’ = powered down,
‘1’ = powered up
0x4008
16392
Data Block [Block Offset: 128]
0
128
blackcal
RW
[7:0]
black_offset
0x08
8
Desired black level at output
[10:8]
black_samples
0x0
0
Black pixels taken into account for
black calibration.
Total samples = 2**black_samples
[14:11]
adc_offset
0x8
8
ADC Offset = 2**adc_offset.
This setting should correspond to
the Calibration DAC setting
[15]
crc_seed
0x0
0
CRC Seed
‘0’ = All-0
‘1’ = All-1
http://onsemi.com
47
NOIM1SM9600A, NOIM2SM9600A
Table 45. REGISTER MAP
Address
Offset
Address
1
129
Default
Default
Register Name
(Hex)
(Dec)
general_configuration
0xC001
49153
auto_blackcal_enable
0x1
1
Automatic blackcalibration is
enabled when 1, bypassed
when 0
[9:1]
blackcal_offset
0x00
0
Black Calibration offset used when
auto_black_cal_en = ‘0’.
[10]
blackcal_offset_dec
0x0
0
blackcal_offset is added when 0,
subtracted when 1
[11]
compress_bypass
0x0
0
Bypass compression of 11 bit
ADC data to 10 bit output data
when 1
[12]
bypass
0x0
0
Bypass datablock (test only) when
‘1’. Use default value for normal
operation.
[13]
8bit_mode
0x0
0
Shifts window ID indications by 4
cycles.
‘0’ = 10 bit mode, ‘1’ = 8 bit mode
[14]
bl_frame_valid_
enable
0x1
1
Assert frame_valid for black lines
when ‘1’, gate frame_valid for
black lines when ‘0’.
NOIM2SM9600A-QDC
[15]
bl_line_valid_enable
0x1
1
Assert line_valid for black lines
when ‘1’, gate line_valid for black
lines when ‘0’.
NOIM2SM9600A-QDC
trainingpattern
0x03A6
934
[9:0]
trainingpattern
0x3A6
934
[10]
reserved
0x0
0
sync_code0
0x002A
42
frame_sync
0x02A
42
sync_code1
0x0015
21
bl
0x015
21
sync_code2
0x0035
53
img
0x035
53
sync_code3
0x0059
89
crc
0x059
89
sync_code4
0x03A6
934
tr
0x3A6
934
Bit Field
[0]
2
3
130
131
[6:0]
4
132
[9:0]
5
133
[9:0]
6
134
[9:0]
7
135
[9:0]
http://onsemi.com
48
Description
Type
RW
RW
Training pattern sent on data
channels during idle mode. This
data is used to perform word
alignment on the LVDS data
channels.
Reserved
RW
Frame sync LSBs.
Note: The 10th bit indicates frame/
line sync code, 9th bit indicates
start, 8th bit indicates end.
RW
Black Pixel Identification Sync
Code
RW
Valid Pixel Identification Sync
Code
RW
CRC Value Identification Sync
Code
RW
Training Value Identification Sync
Code
NOIM1SM9600A, NOIM2SM9600A
Table 45. REGISTER MAP
Address
Offset
Address
Bit Field
Register Name
Default
Default
(Hex)
(Dec)
Description
Type
Datablock - Test
16
18
19
20
21
22
144
0x0000
0
[0]
test_configuration
testpattern_en
0x0
0
Insert synthesized testpattern
when ‘1’
[1]
inc_testpattern
0x0
0
Incrementing testpattern when ‘1’,
constant testpattern when ‘0’
[2]
prbs_en
0x0
0
Insert PRBS when ‘1’
[3]
frame_testpattern
0x0
0
Frame test patterns when ‘1’,
unframed testpatterns when ‘0’
[4]
test_adc_select
0x0
0
Configures which ADC of selected
channels is selected to output
ADC data through adc_dout pins
0x0100
256
146
test_configuration0
RW
RW
[7:0]
testpattern0_lsb
0x00
0
Testpattern used on datapath #0
when testpattern_en = ‘1’.
Note: Most significant bits are
configured in register 150.
[15:8]
testpattern1_lsb
0x01
1
Testpattern used on datapath #1
when testpattern_en = ‘1’.
Note: Most significant bits are
configured in register 150.
0x0302
770
147
test_configuration1
RW
[7:0]
testpattern2_lsb
0x02
2
Testpattern used on datapath #2
when testpattern_en = ‘1’.
Note: Most significant bits are
configured in register 150.
[15:8]
testpattern3_lsb
0x03
3
Testpattern used on datapath #3
when testpattern_en = ‘1’.
Note: Most significant bits are
configured in register 150.
0x0504
1284
148
test_configuration2
RW
[7:0]
testpattern4_lsb
0x04
4
Testpattern used on datapath #4
when testpattern_en = ‘1’.
Note: Most significant bits are
configured in register 150.
[15:8]
testpattern5_lsb
0x05
5
Testpattern used on datapath #5
when testpattern_en = ‘1’.
Note: Most significant bits are
configured in register 150.
0x0706
1798
149
test_configuration3
RW
[7:0]
testpattern6_lsb
0x06
6
Testpattern used on datapath #6
when testpattern_en = ‘1’.
Note: Most significant bits are
configured in register 150.
[15:8]
testpattern7_lsb
0x07
7
Testpattern used on datapath #7
when testpattern_en = ‘1’.
Note: Most significant bits are
configured in register 150.
0x0000
0
150
test_configuration16
RW
[1:0]
testpattern0_msb
0x0
0
Testpattern used when
testpattern_en = ‘1’
[3:2]
testpattern1_msb
0x0
0
Testpattern used when
testpattern_en = ‘1’
http://onsemi.com
49
NOIM1SM9600A, NOIM2SM9600A
Table 45. REGISTER MAP
Address
Offset
Address
Bit Field
Register Name
Default
Default
(Hex)
(Dec)
Description
[5:4]
testpattern2_msb
0x0
0
Testpattern used when
testpattern_en = ‘1’
[7:6]
testpattern3_msb
0x0
0
Testpattern used when
testpattern_en = ‘1’
[9:8]
testpattern4_msb
0x0
0
Testpattern used when
testpattern_en = ‘1’
[11:10]
testpattern5_msb
0x0
0
Testpattern used when
testpattern_en = ‘1’
[13:12]
testpattern6_msb
0x0
0
Testpattern used when
testpattern_en = ‘1’
[15:14]
testpattern7_msb
0x0
0
Testpattern used when
testpattern_en = ‘1’
0x0010
16
Type
AEC[Block Offset: 160]
0
1
160
configuration
[0]
enable
0x0
0
AEC Enable
[1]
restart_filter
0x0
0
Restart AEC filter
[2]
freeze
0x0
0
Freeze AEC filter and enforcer
gains
[3]
pixel_valid
0x0
0
Use every pixel from channel
when 0, every 4th pixel when 1
[4]
amp_pri
0x1
1
Stage 1 amplifier gets higher
priority than stage 2 gain
distribution if 1. vice versa if 0
intensity
0x60B8
24760
desired_intensity
0xB8
184
Target average intensity
clipping_threshold_avg
0x018
24
Clipping threshold for average inc
factor
3.3 unsigned
exposure
0x03FF
1023
fixed_exposure
0x03FF
1023
gain
161
[9:0]
[13:10]
6
166
[15:0]
7
8
167
10
RW
Fixed Exposure Time
0x0800
2048
gain_stage1_select
0x0
0
Fixed Column Amplifier gain
[3:2]
gain_stage2_select
0x0
0
Fixed AFE PGA gain
[15:4]
fixed_digital_gain
0x080
128
min_exposure
0x0001
1
min_exposure
0x0001
1
min_gain
0x0800
2048
168
169
RW
Fixed digital gain
5.7 unsigned
RW
Minimum exposure time
RW
[1:0]
min_gain_stage1
0x0
0
Minimum gain stage 1
[3:2]
min_gain_stage2
0x0
0
Minimum gain stage 2
[15:4]
min_digital_gain
0x080
128
max_exposure
0x03FF
1023
max_exposure
0x03FF
1023
max_gain
0x100D
4109
0x1
1
170
[15:0]
11
RW
[1:0]
[15:0]
9
RW
171
[1:0]
max_gain_stage1
http://onsemi.com
50
Minimum digital gain
5.7 unsigned
RW
Maximum exposure time
RW
Maximum gain stage 1
NOIM1SM9600A, NOIM2SM9600A
Table 45. REGISTER MAP
Address
Offset
12
24
Address
Bit Field
3
[15:4]
max_digital_gain
0x100
256
0x00083
131
hysteresis
[13:8]
dim_threshold
0x00
0
Dimming Threshold
[15:14]
dim_factor
0x0
0
Dimming Factor
total_pixels0
0x0000
0
total_pixels[15:0]
0x0000
0
total_pixels1
0x0000
0
0x0
0
average_status
0x0000
0
[9:0]
average
0x000
0
AEC Average Status
[12]
locked
0x0
0
AEC Filter Lock Status
exposure_status
0x0000
0
exposure
[15:0]
29
RW
131
186
188
Maximum digital gain
5.7 unsigned
0x083
total_pixels[24:16]
Digital Hysteresis
1.7 unsigned
RO
Total number of pixels sampled for
Average, LSB
RO
Total number of pixels sampled for
Average, MSB
RO
RO
0x0000
0
gain_status
0x00
0
[1:0]
gain_stage1
0x0
0
Gain Stage 1 Status
[3:2]
gain_stage2
0x0
0
Gain Stage 2 Status
[15:4]
digital_gain
0x000
0
AEC Digital Gain Status
5.7 unsigned
reserved
0x0000
0
reserved
0x000
0
general_configuration
0x00
0
[0]
enable
0x0
0
Enable sequencer
‘0’ = Idle,
‘1’ = enabled
[1]
rolling_shutter_enable
0x0
0
Operation Selection
‘0’ = global shutter,
‘1’ = rolling shutter
[2]
zero_rot_enable
0x0
0
Zero ROT mode Selection
‘0’ = Normal ROT,
‘1’ = Zero ROT
[3]
x_lag
0x0
0
x−lag in Zero ROT mode
‘0’ = No lag,
‘0’ = Lag
[4]
reserved
0x0
0
reserved
[5]
reserved
0x0
0
reserved
189
[12:0]
Type
Maximum gain stage 2
digital_hysteresis
185
28
Description
[7:0]
184
187
(Dec)
0x3
172
27
Default
(Hex)
max_gain_stage2
[8:0]
26
Default
[3:2]
[15:0]
25
Register Name
AEC Exposure Status
RO
RO
Reserved
Sequencer [Block Offset: 192]
0
192
http://onsemi.com
51
RW
NOIM1SM9600A, NOIM2SM9600A
Table 45. REGISTER MAP
Address
Offset
Address
Bit Field
195
5
197
Insert delay between end of ROT
and start of readout in normal
ROT readout mode if ‘1’. ROT
delay is defined by register
xsm_delay
[7]
reserved
0x0
0
reserved
[8]
reserved
0x0
0
reserved
[10]
roi_aec_enable
0x0
0
Enable windowing for AEC
Statistics.
‘0’ = Subsample all windows
‘1’ = Subsample configured
window
[13:11]
monitor_select
0x0
0
Control of the monitor pins
pls_mode
0x0
0
Test mode for PLS measurements
0x0000
0
delay_configuration
rs_x_length
0x00
0
X-Readout duration in rolling
shutter mode (extends lines with
dummy pixels).
[15:8]
xsm_delay
0x00
0
Delay between ROT start and
X−readout (Zero ROT mode)
Delay between ROT end and
X−readout (Normal ROT mode
with nzrot_xsm_delay_enable=‘1’)
roi_active0
0x0001
1
RW
0x01
1
black_lines
0x0102
258
black_lines
0x02
2
Number of black lines. Minimum is
1.
Range 1 − 255
[8]
gate_first_line
0x1
1
Blank out first line
‘0’: No blank-out
‘1’: Blank-out
[11:9]
mask_black_
coefficients
0x0
0
Added for MANO REVB: Can be
used to reduce the number of
black coefficients used during
black calibration. When 000, all 8
coefficients are used
[12]
mux_black_
coefficients
0x1
0
Added for MANO REVB:
Automatically set number of black
coefficients during black
calibration according to readout
mode
dummy_lines
0x0000
0
dummy_lines
0x000
0
exposure
0x0000
0
exposure
0x0000
0
gain_configuration
0x0A2
162
198
201
[15:0]
204
roi_active[7:0]
Active ROI’s selection
RW
RW
Number of Dummy lines
Range 0 − 2047
RW
Exposure time
Rolling shutter: granularity lines
RW
[4:0]
gain_stage1
0x02
2
Gain stage 1
[12:5]
gain_stage2
0x5
5
Gain stage 2
http://onsemi.com
52
Type
RW
[7:0]
[11:0]
12
Description
0
[7:0]
9
(Dec)
0x0
[7:0]
6
Default
(Hex)
nzrot_xsm_delay_
enable
193
3
Default
[6]
[14]
1
Register Name
NOIM1SM9600A, NOIM2SM9600A
Table 45. REGISTER MAP
Address
Offset
Address
Default
Default
(Hex)
(Dec)
Description
0x0
0
Postpone gain update by 1 frame
when ‘1’ to compensate for
exposure time updates latency.
Gain is applied at start of next
frame if ‘0’
digital_gain_
configuration
0x0080
128
db_gain
0x080
128
sync_configuration
0x033F
831
[0]
sync_rs_x_length
0x1
1
Update of rs_x_length will not be
sync’ed at start of frame when ‘0’
[1]
sync_black_lines
0x1
1
Update of black_lines will not be
sync’ed at start of frame when ‘0’
[2]
sync_dummy_lines
0x1
1
Update of dummy_lines will not be
sync’ed at start of frame when ‘0’
[3]
sync_exposure
0x1
1
Update of exposure will not be
sync’ed at start of frame when ‘0’
[4]
sync_gain
0x1
1
Update of gain settings (gain_sw,
afe_gain) will not be sync’ed at
start of frame when ‘0’
[5]
sync_roi
0x1
1
Update of ROI updates
(active_roi) will not be sync’ed at
start of frame when ‘0’
[8]
blank_roi_switch
0x1
1
Blank first frame after ROI
switching
[9]
blank_subsampling_ss
0x1
1
Blank first frame after subsampling/binning mode switching
in snapshot shutter mode (always
blanked out in rolling shutter
mode)
[10]
exposure_sync_mode
0x0
0
When ‘0’, exposure configurations
are sync’ed at the start of FOT.
When ‘1’, exposure configurations
sync is disabled (continuously
syncing). This mode is only
relevant for Triggered snapshot −
master mode, where the exposure
configurations are sync’ed at the
start of exposure rather than the
start of FOT. For all other modes it
should be set to ‘0’.
Note: Sync is still postponed if
sync_exposure=‘0’.
gain_status
0x0000
0
[4:0]
gain_stage1
0x00
0
Current stage 1 gain
[12:5]
gain_stage2
0x00
0
Current stage 2 gain
Bit Field
[13]
13
205
[11:0]
14
21
22
206
213
214
Register Name
gain_lat_comp
RW
Digital gain
RW
RO
digital_gain_status
0x0000
0
[11:0]
db_gain
0x000
0
Current Digital Gain
[12]
reserved
0x0
0
reserved
[13]
reserved
0x0
0
reserved
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Type
RO
NOIM1SM9600A, NOIM2SM9600A
Table 45. REGISTER MAP
Address
Offset
Address
38
230
39
Default
Default
(Hex)
(Dec)
pixel_array_
address_config
0x88
136
[4:0]
y_address_offset
0x8
8
Offset to y−address to map the
actual pixel array
Scheme
/ Value
normal
/4
R1S1
/2
R2S2
/2
chk_board / 4
1x2 binning / 2
2x2 binning / 2
[9:5]
black_line_address
0x4
4
Black line address for different
pixel arch/readout
Scheme
/ Value
normal
/2
R1S1
/1
R2S2
/1
chk_board / 2
1x2 binning / 1
2x2 binning / 1
pixel_array_
address_config
0x1397
5015
reg_seq_last_line
0x1397
5015
reg_seq_
subsampling_
binning_modes
0x0
0
[0]
reg_seq_1x2_binning
0x0
0
Enable/disable 1x2 pixel binning
‘0’ − disable 1x2 pixel binning
‘1’ − enable 1x2 pixel binning
[1]
reg_seq_2x2_binning
0x0
0
Enable/disable 2x2 pixel binning
‘0’ − disable 2x2 pixel binning
‘1’ − enable 2x2 pixel binning
[2]
reg_seq_check_board
_subsample
0x0
0
Enable/disable check board
pattern subsampling
‘0’ − disable check board pattern
subsampling
‘1’ − enable check board pattern
subsampling
[3]
reg_seq_r1s1
_subsample
0x0
0
Enable/disable read-1-skip-1
subsampling
‘0’ − disable read-1-skip-1
subsampling
‘1’ − enable read-1-skip-1
subsampling
[4]
reg_seq_r2s2
_subsample
0x0
0
Enable/disable read-2-skip-2
subsampling
‘0’ − disable read-2-skip-2
subsampling
‘1’ − enable read-2-skip-2
subsampling
Bit Field
231
[12:0]
40
232
Register Name
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Description
Type
RW
RW
Sequencer last line address for
different pixel arch/readouts
Scheme
/ Value
normal
/ 2507
R1S1
/ 1253
R2S2
/ 1253
chk_board / 2507
1x2 binning / 1253
2x2 binning / 1253
RW
NOIM1SM9600A, NOIM2SM9600A
Table 45. REGISTER MAP
Address
Offset
Address
54
246
Bit Field
[8:0]
55
247
[8:0]
56
248
[12:0]
57
249
[12:0]
Default
Default
Register Name
(Hex)
(Dec)
roi_aec_configuration0
0x0000
0
0x00
0
roi_aec_configuration0
0x0000
0
x_end
0x000
0
roi_aec_configuration1
0x0000
0
y_start
0x000
0
roi_aec_configuration2
0x0000
0
y_end
0x0
0
roi0_configuration0
0x00
0
x_start
0x00
0
roi0_configuration1
0x0EF
239
x_end
0x0EF
239
roi0_configuration2
0x0000
0
y_start
0x0000
0
roi0_configuration3
0x01387
4999
y_end
0x01387
4999
roi1_configuration0
0x00
0
x_start
0x00
0
roi1_configuration1
0x0EF
239
x_end
0x0EF
239
roi1_configuration2
0x0000
0
y_start
0x0000
0
roi1_configuration3
0x01387
4999
y_end
0x01387
4999
x_start
Description
Type
RW
AEC ROI X Start Configuration
(used for AEC statistics when
roi_aec_enable=‘1’)
RW
AEC ROI X End Configuration
(used for AEC statistics when
roi_aec_enable=‘1’)
RW
AEC ROI Y Start Configuration
(used for AEC statistics when
roi_aec_enable=‘1’)
RW
AEC ROI Y End Configuration
(used for AEC statistics when
roi_aec_enable=‘1’)
Sequencer ROI [Block Offset: 256]
0
256
[8:0]
1
257
[8:0]
2
258
[12:0]
3
259
[12:0]
4
260
[8:0]
5
261
[8:0]
6
262
[12:0]
7
263
[12:0]
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RW
X Start Configuration
RW
X End Configuration
RW
Y Start Configuration
RW
Y End Configuration
RW
X Start Configuration
RW
X End Configuration
RW
Y Start Configuration
RW
Y End Configuration
NOIM1SM9600A, NOIM2SM9600A
PACKAGE INFORMATION
Pin List
TIA/EIA-644-A Standard and the CMOS I/Os have a 3.3 V
signal level. Table 46 and Table 47 show the pin list for both
versions.
MANO 9600 has two output versions; M1-SM (LVDS)
and M2-SM (CMOS). The LVDS I/Os comply to the
Table 46. PIN LIST FOR M1­SM LVDS INTERFACE
Pack Pin
No.
Pin Name
I/O Type
1
gnd_33
Supply
2
vdd_33
Supply
3
mosi
CMOS
Input
SPI master out - slave in
4
miso
CMOS
Output
SPI master in - slave out
5
sclk
CMOS
Input
6
gnd_18
Supply
1.8 V ground
7
vdd_18
Supply
1.8 V supply
Direction
Description
3.3 V ground
3.3 V Supply
SPI clock
8
NC
9
clock_outn
LVDS
Output
Not connected
LVDS clock output (Negative)
10
clock_outp
LVDS
Output
LVDS clock output (Positive)
11
doutn0
LVDS
Output
LVDS data output channel #0 (Negative)
12
doutp0
LVDS
Output
LVDS data output channel #0(Positive)
13
doutn1
LVDS
Output
LVDS data output channel #1 (Negative)
14
doutp1
LVDS
Output
LVDS data output channel #1(Positive)
15
doutn2
LVDS
Output
LVDS data output channel #2 (Negative)
16
doutp2
LVDS
Output
LVDS data output channel #2 (Positive)
17
doutn3
LVDS
Output
LVDS data output channel #3 (Negative)
18
doutp3
LVDS
Output
LVDS data output channel #3 (Positive)
19
syncn
LVDS
Output
LVDS sync channel output (Negative)
Output
LVDS sync channel output (Positive)
20
syncp
LVDS
21
vdd_33
Supply
3.3 V supply
22
gnd_33
Supply
3.3 V ground
23
gnd_18
Supply
1.8 V ground
24
vdd_18
Supply
1.8 V supply
25
lvds_clock_inn
LVDS
Input
LVDS clock input (Negative)
26
lvds_clock_inp
LVDS
Input
LVDS clock input (Positive)
Input
Reference clock input for PLL
27
clk_pll
CMOS
28
vdd_18
Supply
1.8 V supply
29
gnd_18
Supply
1.8 V ground
30
ibias_master
Analog
31
vdd_33
Supply
3.3 V supply
32
gnd_33
Supply
3.3 V ground
33
vdd_pix_low
Supply
1.8 V supply
34
vdd_pix
Supply
Pixel array supply (3.3 V)
35
gnd_colpc
Supply
Pixel array ground (0 V)
36
vdd_pix
Supply
Pixel array supply (3.3 V)
37
gnd_colpc
Supply
Pixel array ground (0 V)
I/O
Master bias reference. Connect 47 k to gnd_33
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NOIM1SM9600A, NOIM2SM9600A
Table 46. PIN LIST FOR M1­SM LVDS INTERFACE
Pack Pin
No.
Pin Name
I/O Type
38
gnd_33
Supply
3.3 V ground
39
vdd_33
Supply
3.3 V supply
40
vdd_pix_low
Supply
1.8 V supply
41
gnd_colpc
Supply
Pixel array ground (0 V)
42
vdd_pix
Supply
Pixel array supply (3.3 V)
43
gnd_colpc
Supply
Pixel array ground (0 V)
44
vdd_pix
Supply
Pixel array supply (3.3 V)
45
NC
Not connected
46
NC
Not connected
47
vdd_pix_low
48
NC
49
monitor0
CMOS
Output
Monitor output #0
50
monitor1
CMOS
Output
Monitor output #1
51
reset_n
CMOS
Input
Sensor reset (active low)
52
ss_n
CMOS
Input
SPI slave select (active low)
Direction
Supply
Description
1.8 V supply
Not connected
Table 47. PIN LIST FOR M2­SM CMOS INTERFACE
Pack Pin
No.
Pin Name
I/O Type
1
gnd_33
Supply
3.3 V ground
2
vdd_33
Supply
3.3 V supply
3
mosi
CMOS
Input
SPI master out - slave in
4
miso
CMOS
Output
SPI master in - slave out
5
sclk
CMOS
Input
6
gnd_18
Supply
1.8 V ground
7
vdd_18
Supply
1.8 V supply
8
NC
9
dout9
CMOS
Output
Data output bit #9
10
dout8
CMOS
Output
Data output bit #8
11
dout7
CMOS
Output
Data output bit #7
12
dout6
CMOS
Output
Data output bit #6
13
dout5
CMOS
Output
Data output bit #5
14
dout4
CMOS
Output
Data output bit #4
15
dout3
CMOS
Output
Data output bit #3
16
dout2
CMOS
Output
Data output bit #2
17
dout1
CMOS
Output
Data output bit #1
18
dout0
CMOS
Output
Data output bit #0
19
frame_valid
CMOS
Output
Frame valid output
20
line_valid
CMOS
Output
Line valid output
21
vdd_33
Supply
3.3 V supply
22
gnd_33
Supply
3.3 V ground
23
clk_out
Analog
Analog clock output
Direction
Description
SPI clock
Not connected
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NOIM1SM9600A, NOIM2SM9600A
Table 47. PIN LIST FOR M2­SM CMOS INTERFACE
Pack Pin
No.
Pin Name
I/O Type
24
vdd_18
Supply
25
lvds_clock_inn
LVDS
Input
LVDS clock input (Negative)
26
lvds_clock_inp
LVDS
Input
LVDS clock input (Positive)
Input
Reference clock input for PLL
Direction
Description
1.8 V supply
27
clk_pll
CMOS
28
vdd_18
Supply
1.8 V supply
29
gnd_18
Supply
1.8 V ground
30
ibias_master
Analog
31
vdd_33
Supply
3.3 V supply
32
gnd_33
Supply
3.3 V ground
33
vdd_pix_low
Supply
1.8 V supply
34
vdd_pix
Supply
Pixel array supply (3.3 V)
35
gnd_colpc
Supply
Pixel array ground (0 V)
36
vdd_pix
Supply
Pixel array supply (3.3 V)
37
gnd_colpc
Supply
Pixel array ground (0 V)
38
gnd_33
Supply
3.3 V ground
39
vdd_33
Supply
3.3 V supply
40
vdd_pix_low
Supply
1.8 V supply
41
gnd_colpc
Supply
Pixel array ground (0 V)
42
vdd_pix
Supply
Pixel array supply (3.3 V)
43
gnd_colpc
Supply
Pixel array ground (0 V)
44
vdd_pix
Supply
Pixel array supply (3.3 V)
45
NC
Not connected
46
NC
Not connected
47
vdd_pix_low
48
NC
49
monitor0
CMOS
Output
Monitor output #0
50
monitor1
CMOS
Output
Monitor output #1
51
reset_n
CMOS
Input
Sensor reset (Active Low)
52
ss_n
CMOS
Input
SPI slave select (Active Low)
I/O
Master bias reference. Connect 47 k to gnd_33
Supply
1.8 V supply
Not connected
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NOIM1SM9600A, NOIM2SM9600A
Package Specification
Table 48. MECHANICAL SPECIFICATION FOR MANO 9600 CERAMIC LCC PACKAGE
Parameter
Die
(with Pin 1 to the left
center)
Description
Min
Die thickness
Max
750
Die placement accuracy in package
-50
Die center, X offset to the center of package
2.5
Units
mm
+50
mm
52.5
102.5
mm
-268.3
-218.3
-168.3
mm
Die position, tilt to the Die Attach Plane
-1
0
1
deg
Die rotation accuracy (referenced to die scribe and lead
fingers on package on all four sides)
-1
0
1
deg
Die center, Y offset to the center of the package
Optical center referenced from the die/package center (X-dir)
-4.4
mm
Optical center referenced from the die/package center (Y-dir)
-1359.8
mm
1.3
mm
Distance from PCB plane to top of the die surface
Distance from top of the die surface to top of the glass lid
Glass Lid
Specification
Typ
0.9
mm
(-10%)
19.05 x 19.05
(+10%)
mm2
Thickness
0.5
0.55
0.6
mm
Spectral response range
400
1000
nm
92
%
2000
G
2000
Hz
260
°C
XY size
Transmission of glass lid (refer to Figure 44)
Mechanical Shock
JESD22-B104C; Condition G
Vibration
JESD22-B103B; Condition 1
Mounting Profile
Reflow profile according to J-STD-020D.1
20
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NOIM1SM9600A, NOIM2SM9600A
Package Outline Drawing
Figure 34. 52−Pin LCC Package (dimensions in mm)
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NOIM1SM9600A, NOIM2SM9600A
• Active Area outer dimensions
Optical Center Information
The center of the die (CD) is offset from the center of the
cavity by (52.5, −218.3) mm.
The center of the cavity is exactly at 50% between the
insides of the finger pads.
• Die outer dimensions:
♦ B4 is the reference for the Die (0,0) in mm
♦ B1 is at (0,10150) mm
♦ B2 is at (10900,10150) mm
♦ B3 is at (10900,0) mm
A1 is the at (785.53, 9663.86) mm
A2 is at (10018.33, 9663.86) mm
♦ A3 is at (10018.33, 3642.26) mm
♦ A4 is at (785.53, 3642.26) mm
Center of the Active Area
♦ AA is at (5401.93, 6653.06) mm
Center of the Die
♦ CD is at (5450, 5075) mm
♦
♦
•
•
Figure 35. Package Outline Drawing
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NOIM1SM9600A, NOIM2SM9600A
GLASS LID
The MANO 9600 image sensor uses a glass lid without
any coatings. Figure 36 shows the transmission
characteristics of the glass lid.
As shown in Figure 36, no infrared attenuating color filter
glass is used. (source: http://www.pgo-online.com).
Figure 36. Transmission Characteristics of the Glass Lid
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62
NOIM1SM9600A, NOIM2SM9600A
HANDLING PRECAUTIONS
For proper handling and storage conditions, refer to the ON Semiconductor application note AN52561, Image Sensor
Handling and Best Practices.
LIMITED WARRANTY
ON Semiconductor’s Image Sensor Business Unit
warrants that the image sensor products to be delivered
hereunder, if properly used and serviced, will conform to
Seller’s published specifications and will be free from
defects in material and workmanship for two (2) years
following the date of shipment. If a defect were to manifest
itself within 2 (two) years period from the sale date,
ON Semiconductor will either replace the product or give
credit for the product.
procedures and ships all image sensor products in ESD-safe,
clean-room-approved shipping containers. Products
returned to ON Semiconductor for failure analysis should be
handled under these same conditions and packed in its
original packing materials, or the customer may be liable for
the product.
Refer to the ON Semiconductor RMA policy procedure at
http://www.onsemi.com/site/pdf/CAT_Returns_FailureAn
alysis.pdf
Return Material Authorization (RMA)
ON Semiconductor packages all of its image sensor
products in a clean room environment under strict handling
SPECIFICATIONS AND USER REFERENCES
Acceptance Criteria Specification
Specifications, Application Notes and useful resources
can be accessible via customer login account at MyOn CISP Extranet.
https://www.onsemi.com/PowerSolutions/myon/erCispFol
der.do
The Product Acceptance Criteria is available on request.
This document contains the criteria to which the
MANO 9600 is tested prior to being shipped.
Application Note and References
• AN65464 VITA 2000 HSMC Cyclone Reference Board
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NOIM1SM9600A, NOIM2SM9600A
ACRONYMS
Acronym
Description
Acronym
Description
ADC
Analog-to-Digital Converter
IP
Intellectual Property
AFE
Analog Front End
LE
Line End
BL
Black pixel data
LS
Line Start
CDM
Charged Device Model
LSB
least significant bit
CDS
Correlated Double Sampling
LVDS
Low-Voltage Differential Signaling
CMOS
Complementary Metal Oxide Semiconductor
MSB
most significant bit
CRC
Cyclic Redundancy Check
PGA
Programmable Gain Amplifier
DAC
Digital-to-Analog Converter
PLS
Parasitic Light Sensitivity
DDR
Double Data Rate
PRBS
Pseudo-Random Binary Sequence
DNL
Differential Non-Llinearity
PRNU
Photo Response Non-Uniformity
DS
Double Sampling
QE
Quantum Efficiency
DSNU
Dark Signal Non-Uniformity
RGB
Red-Green-Blue
EIA
Electronic Industries Alliance
RMA
Return Material Authorization
ESD
Electrostatic Discharge
rms
Root Mean Square
FE
Frame End
ROI
Region of Interest
FF
Fill Factor
ROT
Row Overhead Time
FOT
Frame Overhead Time
S/H
Sample and Hold
FPGA
Field Programmable Gate Array
SNR
Signal-to-Noise Ratio
FPN
Fixed Pattern Noise
SPI
Serial Peripheral Interface
FPS
Frame per Second
TIA
Telecommunications Industry Association
FS
Frame Start
TJ
Junction temperature
HBM
Human Body Model
TR
Training pattern
IMG
Image data (regular pixel data)
% RH
Percent Relative Humidity
INL
Integral Non-Linearity
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NOIM1SM9600A, NOIM2SM9600A
GLOSSARY
conversion gain
A constant that converts the number of electrons collected by a pixel into the voltage swing of the pixel.
Conversion gain = q/C where q is the charge of an electron (1.602E 19 Coulomb) and C is the capacitance
of the photodiode or sense node.
CDS
Correlated double sampling. This is a method for sampling a pixel where the pixel voltage after reset is
sampled and subtracted from the voltage after exposure to light.
DNL
Differential non-linearity (for ADCs)
DSNU
Dark signal non-uniformity. This parameter characterizes the degree of non-uniformity in dark leakage
currents, which can be a major source of fixed pattern noise.
fill-factor
A parameter that characterizes the optically active percentage of a pixel. In theory, it is the ratio of the
actual QE of a pixel divided by the QE of a photodiode of equal area. In practice, it is never measured.
INL
Integral nonlinearity (for ADCs)
IR
Infrared. IR light has wavelengths in the approximate range 750 nm to 1 mm.
Lux
Photometric unit of luminance (at 550 nm, 1lux = 1 lumen/m2 = 1/683 W/m2)
pixel noise
Variation of pixel signals within a region of interest (ROI). The ROI typically is a rectangular portion of the
pixel array and may be limited to a single color plane.
photometric units
Units for light measurement that take into account human physiology.
PLS
Parasitic light sensitivity. Parasitic discharge of sampled information in pixels that have storage nodes.
PRNU
Photo-response non-uniformity. This parameter characterizes the spread in response of pixels, which is a
source of FPN under illumination.
QE
Quantum efficiency. This parameter characterizes the effectiveness of a pixel in capturing photons and
converting them into electrons. It is photon wavelength and pixel color dependent.
read noise
Noise associated with all circuitry that measures and converts the voltage on a sense node or photodiode
into an output signal.
reset
The process by which a pixel photodiode or sense node is cleared of electrons. ”Soft” reset occurs when
the reset transistor is operated below the threshold. ”Hard” reset occurs when the reset transistor is operated above threshold.
reset noise
Noise due to variation in the reset level of a pixel. In 3T pixel designs, this noise has a component (in units
of volts) proportionality constant depending on how the pixel is reset (such as hard and soft). In 4T pixel
designs, reset noise can be removed with CDS.
responsivity
The standard measure of photodiode performance (regardless of whether it is in an imager or not). Units
are typically A/W and are dependent on the incident light wavelength. Note that responsivity and sensitivity
are used interchangeably in image sensor characterization literature so it is best to check the units.
ROI
Region of interest. The area within a pixel array chosen to characterize noise, signal, crosstalk, and so on.
The ROI can be the entire array or a small subsection; it can be confined to a single color plane.
sense node
In 4T pixel designs, a capacitor used to convert charge into voltage. In 3T pixel designs it is the photodiode itself.
sensitivity
A measure of pixel performance that characterizes the rise of the photodiode or sense node signal in Volts
upon illumination with light. Units are typically V/(W/m2)/sec and are dependent on the incident light
wavelength. Sensitivity measurements are often taken with 550 nm incident light. At this wavelength, 1
683 lux is equal to 1 W/m2; the units of sensitivity are quoted in V/lux/sec. Note that responsivity and sensitivity are used interchangeably in image sensor characterization literature so it is best to check the units.
spectral response
The photon wavelength dependence of sensitivity or responsivity.
SNR
Signal-to-noise ratio. This number characterizes the ratio of the fundamental signal to the noise spectrum
up to half the Nyquist frequency.
temporal noise
Noise that varies from frame to frame. In a video stream, temporal noise is visible as twinkling pixels.
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NOIM1SM9600A, NOIM2SM9600A
ON Semiconductor and
are registered trademarks of Semiconductor Components Industries, LLC (SCILLC). SCILLC owns the rights to a number of patents, trademarks,
copyrights, trade secrets, and other intellectual property. A listing of SCILLC’s product/patent coverage may be accessed at www.onsemi.com/site/pdf/Patent−Marking.pdf. SCILLC
reserves the right to make changes without further notice to any products herein. SCILLC makes no warranty, representation or guarantee regarding the suitability of its products for any
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