© Semiconductor Components Industries, LLC, 2012
February, 2017 − Rev. 4 1Publication Order Number:
AR0835HS/D
AR0835HS
AR0835HS 1/3.2‐inch 8 Mp
CMOS Digital Image Sensor
Table 1. KEY PERFORMANCE PARAMETERS
Parameter Value
Array Format 8 Mp: 3264 × 2448
6 Mp: 3264 × 1836
Primary Modes 4:3 − 8 Mp 46 fps Max (HiSPi) and
42 fps Max (MIPI)
16:9 − 6 Mp at 60 fps Max
1080p 60 fps / 720p 120 fps Max
Pixel Size 1.4 mm Back Side Illuminated (BSI)
Optical Format 1/3.2
Die Size 6.86 mm × 6.44 mm (Area: 44.17 mm2)
Input Clock Frequency 6−27 MHz
Interface HiSPi Mode: 4 lanes at 1 Gbps Max.
MIPI Mode: CSI−2 (2, 3, 4 lanes) at
896 Mbps max.
Subsampling Modes X − Bin2, Sum2 Skip: 2×, 4×
Y − Sum2, Skip: 2×, 4×, 8×
Output Data Depth 10-bit Raw, 10-to-8 bit A-Law , 8/6-bit DPCM
Analog Gain 1×, 2×, 3×, 4×, 6×, 8×
High Quality Bayer Scalar Adjustable Scaling Up to 1/6× Scaling
Temperature Sensor 10-bit, Single Instance on Chip,
Controlled by Two-wire Serial I/F
VCM AF Driver 8-bit Resolution with Slew Rate Control
3−D Support Frame Rate and Exposure Synchronization
Supply Voltage
Analog
Digital
Pixel
I/O
HiSPi/MIPI
2.5−3.1 V (2.8 V Nominal)
1.14−1.3 V (1.2 V Nominal)
2.5−3.1 V (2.8 V Nominal)
1.7−1.9 V (1.8 V Nominal) or
2.5−3.1 V (2.8 V Nominal)
1.14−1.3 V (1.2 V Nominal)
OTPM Program Voltage 6.5 V
Power Consumption Typical 420 mW at 25°C for 8 Mp/46 fps and
6 Mp/60 fps
Responsivity 0.6 V/lux−sec
SNRMAX 36 dB
Dynamic Range 64 dB
Operating Temperature
Range (at Junction) −TJ−30°C to +70°C
Features
High Speed Sensor Supporting 8 Mp (4:3) and 6 Mp (16:9) Up to
60 fps
1.4m Pixel with ON Semiconductor A−PixHSt Technology
Providing Best-in-class Low-light Performance
Optional On-chip High-quality Bayer Scaler to Resize Image to
Desired Size
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F
eatures (Continued)
Data Output Serial Interface: Four-lane
High-speed Serial Pixel Interface (HiSPi) o
r
Mobile Industry Processor Interface (MIPI)
Bit-depth Compression Available for Seria
l
Interface: 10-to-8 and 10-6 Bit Compressio
n
to Enable Lower Bandwidth Receivers for
Full Frame Rate Applications
On-chip Temperature Sensor
On-die Phase-locked Loop (PLL) Oscillato
r
5.6 kbits One-time Programmable Memory
(OTPM) for Storing Module Information
and Calibration Data
On-chip 8-bit VCM Driver
3D Synchronization Controls to Enable
Stereo Video Capture
Interlaced Multi-exposure Readout Enablin
g
High Dynamic Range (HDR) Still and Vide
o
Applications
Programmable Controls: Gain, Horizontal
and Vertical Blanking, Auto Black Level
Offset Correction, Frame Size/Rate,
Exposure, Left-right and Top-bottom Imag
e
Reversal, Window Size, and Panning
Support for External Mechanical Shutter
Support for External LED or Xenon Flash
A
pplications
Sports Cameras
Digital Still Cameras
Digital Video Cameras
See detailed ordering and shipping information on page 2 o
f
this data sheet.
ORDERING INFORMATION
CLCC48 10 y 10
CASE 848AJ
AR0835HS
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2
Table 2. MODE OF OPERATION AND POWER CONSUMPTION
Mode Active Readout
Window (Col y Row) Sensor Output Resolution
(Col y Row) Mode FPS
Typical Power
Consumption
(Note 2)
FULL RESOLUTION 4:3
8Mp 3264 × 2448 3264 × 2448 Full Mode 46/42 420 mW
8Mp 3264 × 2448 3264 × 2448 Full Mode 30 370 mW
FULL RESOLUTION 16:9
6Mp 3264 × 1836 3264 × 1836 Full Mode 60 420 mW
6Mp 3264 × 1836 3264 × 1836 Full Mode 30 370 mW
4:3 VIDEO MODE
VGA 3264 × 2448 640 × 480 Skip4 180 370 mW
QVGA 3264 × 2448 320 × 240 Skip4 240 370 mW
16:9 VIDEO MODE
1080p 3264 × 1836 1920 × 1080 Scaling 30 360 mW
1080p 3264 × 1836 1920 × 1080 Scaling 60 420 mW
720p 3264 × 1836 1280 × 720 Bin2−Sum2 120 390 mW
720p 3264 × 1836 1280 × 720 Scaling 60 420 mW
720p 3264 × 1836 1280 × 720 Bin2 + Scaling 60 250 mW
1. Gbps/Lane HiSPi and 896 Mbps/Lane MIPI data transfer rate.
2. Values measured at T = 25°C and nominal voltages.
ORDERING INFORMATION
Table 3. AVAILABLE PART NUMBERS
Part Number Product Description Orderable Product Attribute Description
AR0835HS3C12SUAA0−DP 8 MP 1/3 CIS Dry Pack with Protective Film
AR0835HS3C12SUAA0−DR 8 MP 1/3 CIS Dry Pack without Protective Film
See the ON Semiconductor Device Nomenclature
document (TND310/D) for a full description of the naming
convention used for image sensors. For reference
documentation, including information on evaluation kits,
please visit our web site at www.onsemi.com.
GENERAL DESCRIPTION
The AR0835HS from ON Semiconductor is a 1/3.2-inch
BSI (back side illuminated) CMOS active-pixel digital
image sensor with a pixel array of 3264 (H) × 2448 (V)
(3280 (H) × 2464 (V) including border pixels). It
incorporates sophisticated on-chip camera functions such as
mirroring, column and row skip modes, and context
switching for zero shutter lag snapshot mode. It is
programmable through a simple two-wire serial interface
and has very low power consumption.
The AR0835HS digital image sensor features
ON Semiconductor’s breakthrough low-noise 1.4 mm pixel
CMOS imaging technology that achieves near-CCD image
quality (based on signal-to-noise ratio and low-light
sensitivity) while maintaining the inherent size, cost, and
integration advantages of CMOS.
AR0835HS
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3
FUNCTIONAL OVER VIEW
In order to meet higher frame rates in AR0835HS sensor ,
the architecture has been re-designed. The analog core has
a column parallel architecture with 4 data paths. Digital
block has been re-architected to have 4 data paths.
Figure 1 shows the block diagram of the AR0835HS.
Figure 1. Top Level Block Diagram
PLL Timing Control
Register Control
Two-wire
Serial Interface
Row
Driver
Pixel
Array ADCGain
Imaging Sensor Core Digital Processing Image Output
10-bit
Temperature
Sensor
Gain
Control
Test Pattern
Generator
Data Calibration
Digital Gain
Scaler
HiSPi
FIFO&Optional
Compression
VAA,
VAA_PIX
VDD_IO,
DVDD_1V8,
DVDD_1V2
HiSPi/MIPI
Serial Data
Output [3:0]
External
Clock
XSHUTDOWN
GPIO[1:0]
GPI[3:2]
SCLK
SDATA
VCM
VCM
Control
DVDD_1V2_
PHY
AR0835HS
The core of the sensor is an 8 Mp active-pixel array.
The timing and control circuitry sequences through the rows
of the array, resetting and then reading each row in turn. In
the time interval between resetting a row and reading that
row, the pixels in the row integrate incident light.
The exposure is controlled by varying the time interval
between reset and readout. Once a row has been read, the
data from the columns is sequenced through an analog signal
chain (providing gain), and then through an ADC.
The output from the ADC is a 10-bit value for each pixel in
the array. The ADC output passes through a digital
processing signal chain (which provides further data path
corrections and applies digital gain).
The pixel array contains optically active and
light-shielded (“dark”) pixels. The dark pixels are used to
provide data for on-chip offset-correction algorithms
(“black level” control).
The sensor contains a set of control and status registers
that can be used to control many aspects of the sensor
behavior including the frame size, exposure, and gain
setting. These registers can be accessed through a two-wire
serial interface.
The output from the sensor is a Bayer pattern; alternate
rows are a sequence of either green and red pixels or blue and
green pixels. The offset and gain stages of the analog signal
chain provide per-color control of the pixel data.
A flash output signal is provided to allow an external
xenon or LED light source to synchronize with the sensor
exposure time. Additional I/O signals support the provision
of an external mechanical shutter.
Pixel Array
The sensor core uses a Bayer color pattern, as shown in
Figure 2. The even-numbered rows contain green and red
pixels; odd-numbered rows contain blue and green pixels.
Even-numbered columns contain red and green pixels;
odd-numbered columns contain blue and green pixels.
Figure 2. Pixel Color Pattern Detail
(Top Right Corner)
Gr
B
Gr
B
R
Gb
R
Gb
R
Gb
R
Gb
Gr
B
Gr
B
Column Readout Direction
Row Readout Direction
First Pixel
(Col. 0, Row 60)
Black Pixels
R
Gb
R
Gb
NOTE: By default the mirror bit is set, so the
read-out direction is from right to left.
AR0835HS
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TYPICAL CONNECTIONS
The chip supports HiSPi/MIPI output protocol. HiSPi and
MIPI are configured to work in 4-lane mode. There are no
parallel data output ports.
Figure 3. Typical Application Circuit − HiSPi Connection
1. All power supplies should be adequately decoupled; recommended cap values are:
− 2.8 V: 1.0 mF, 0.1 mF, and then 0.01 mF
− 1.2 V: 10 mF, 1 mF, and then 0.1 mF
− 1.8 V: 1 mF and 0.1 mF
2. Resistor value 1.5 kW is recommended, but may be greater for slower two-wire speed.
3. This pull-up resistor is not required if the controller drives a valid logic level on SCLK at all times.
4. VAA and V AA_PIX can be tied together. However, for noise immunity it is recommended to have them separate (i.e. two sets of 2.8 V decou
-
pling caps).
5. VPP, 6.5 V, is used for programming OTPM. This pad is left unconnected if OTPM is not being programmed.
6. VDD_1V8 can be combined with VDD_IO, if VDD_IO = 1.8 V.
7. VDD_1V2 and VDD_PHY can be tied together.
8. HiSPi mode only: VDDSLVS_PHY is set to 0.4 V externally. Alternatively, VDDSLVS_PHY may be tied to 1.2 V if the user chooses to have
the HiSPi SLVS PHY TX voltage supplied using the AR0835HS’s internal 1.2 V-to-0.4 V regulator.
9. Register 31BE[2:3] can be used to program the option of internal of external regulator, ON Semiconductor recommends using externa
l
regulator.
10.ATEST can be left floating.
11.TEST pin must be tied to DGND.
12.VDD_1V8 is the OTPM read voltage.
Notes:
DATA_P
DATA_N
DATA2_P
DATA2_N
DATA3_P
DATA3_N
VAA, VAA_PIX 2.8 V
AGND
VAA_PIX4
VAA4
(Analog)
VDD_IO
(IO) VDD_1V2
(Digital)
SDATA
SCLK
EXTCLK
(6−27 MHz)
1.5 kW2
1.5 kW2, 3
TEST8, 11
To
HiSPi/
MIPI
Host
Interfac
e
Two-wire
Serial
Interface
2.8 V or 1.8 V
XSHUTDOWN
DATA4_N
DATA4_P
CLK_P
CLK_N
DGND VPP5
(OTPM Write)
(Only Connected while
Programming OTPM)
ATEST8, 10
GPI[3:2]
GPIO[1:0]
General
Purpose
Input/Output
VDD_1V8
(OTPM
Read)6, 12
1.2 V 2.8 V 1.2 V
VDD_PHY7
0.1 mF1 mF10 mF
VDD 1.2 V
0.1 mF1.0 mF
VDD_IO
10 mF0.1 mF
1
1.8 V
VDDSLVS_PHY
(HiSPi Only)
1.2 V/0.4 V
ISINK
GND
VCM
VCM
VCM
GND_IO
GNDPHY
VDD_1V8
1 mF0.1 mF
AR0835HS
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SIGNAL DESCRIPTIONS
AR0835HS has 66 pads placed in a two sided pad frame.
It has only serial outputs. The part may be configured as HiSPi with different bit depths. The pad description is
tabulated in Table 4.
Figure 4. CLCC Package Pinout Diagram (Top Side View)
42 EXTCLKGPIO1 7
41 VDD_IOXSHUTDOWN 8
40 TESTVCM_GND 9
39 VDD_SWVCM_ISINK 10
38 DGND
PIXGND 11
37 DATA_PVAA_PIX 12
36 DATA_NATEST1 13
35 VDD_SLVSAGND 14
34 DATA2_NVAA 15
33 DATA2_PVAA 16
32 VDD_PHYAGND 17
31 CLK_PDGND_ANA 18
6 GPIO0DGND_ANA 19
5V
DD_SWVDD_ANA 20
4 GPI3VDD_ANA 21
3 GPI2VPP 22
2D
GND
VDD_1V8 23
1V
DD_SWVDD_SW 24
48 DGND
DATA4_P 25
47 VDD_PLLDATA4_N 26
46 DGND
VDD_1V8 27
45 SDATA
DATA3_N 28
44 SCLK
DATA3_P 29
43 DGND
CLK_N 30
Table 4. PAD DESCRIPTIONS
Pad Name Pad Type Description
SENSOR CONTROL
EXTCLK Input Master clock input; PLL input clock. 6−27 MHz. This is a SMIA-compliant pad.
GPIO0 Input/Output General Input and one Output function include:
a. (Default Output) Flash
b. (Input) all options in GPI2
High−Z before XSHUTDOWN going high; default value is ‘0’ after all three voltages in place
and XSHUTDOWN being high.
After reset, this pad is not powered down since its default use is as Flash pin.
If not used, can be left floating.
GPIO0 Input/Output General Input and one Output function include:
a. (Default Output) Flash
b. (Input) all options in GPI2
High−Z before XSHUTDOWN going high; default value is ‘0’ after all three voltages in place
and XSHUTDOWN being high.
After reset, this pad is not powered down since its default use is as Flash pin.
If not used, can be left floating.
AR0835HS
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Table 4. PAD DESCRIPTIONS (continued)
Pad Name DescriptionPad Type
SENSOR CONTROL
GPIO1 Input/Output General Input and 2 Output functions include:
a. (Default Output) Shutter
b. (Output) 3-D daisy chain communication output
c. (Input) all options in GPI2
High−Z before XSHUTDOWN going high; default value is ‘0’ after all three voltages in place
and XSHUTDOWN being high.
After reset, this pad is not powered down since its default use is as Shutter pin.
If not used, can be left floating.
GPI2 Input General Input; After reset, these pads are powered down by default; this means that it is not
necessary to bond to these pads. Functions include:
a. SADDR, switch to the second two-wire serial interface device address
(see “Slave Address/Data Direction Byte”)
b. Trigger signal for Slave Mode
c. Standby
If not used, can be left floating.
GPI3 Input General Input; After reset, these pads are powered-down by default; this means that it is not
necessary to bond to these pads. Functions include:
a. 3-D daisy chain communication input
b. All options in GPI2
If not used, can be left floating.
TWO-WIRE SERIAL INTERFACE
SCLK Input Serial clock for access to control and status registers
SDATA I/O Serial data for reads from and writes to control and status registers
SERIAL OUTPUT
DATA[4:1]P Output Differential serial data (positive)
DATA[4:1]N Output Differential serial data (negative)
CLK_P Output Differential serial clock/strobe (positive)
CLK_N Output Differential serial clock/strobe (negative)
XSHUTDOWN Input Asynchronous active LOW reset. When asserted, data output stops and all internal registers
are restored to their factory default settings. This pin will turn off the digital power domain and
is the lowest power state of the sensor.
VCM DRIVER
VCM_ISINK Input/Output VCM Driver current sink output. If not used, it could be left floating.
VCM_GND Input/Output Ground connection to VCM Driver. If not used, needs to be connected to ground (DGND).
This ground must be separate from the other grounds.
POWER
VPP Supply High-voltage pin for programming OTPM, present on sensors with that capability. This pin
can be left floating during normal operation.
VAA, VAA_PIX,
VDD_1V2_[VDDSW,
VDD_ANA, VDD_PLL],
VDD_1V8, VDD_IO,
VDD_PHY,
VDDSLVS_PHY, AGND,
PIXGND, DGND
Supply Power supply. The domains are specified in the next table. The brackets indicate the number
of individual pins. VDDSLVS_PHY is for HiSPi mode only.
AR0835HS
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7
There are standard GPI and GPIO pads, 2 each. Chip can
also be communicated to through the two-wire serial
interface.
The chip has four unique power supply requirements:
1.2 V (digital), 1.8 V, 2.8 V, and an analog 1.2 V or 0.4 V.
These are further divided and in all there are seven power
domains and five independent ground domains from the
ESD perspective.
Table 5. INDEPENDENT POWER AND GROUND DOMAINS
Pad Name Power Supply Description
GROUNDS
DGND 0V Digital
VCM_GND 0V
AGND, PIXGND 0V Analog
POWER
VAA 2.8 V Analog
VAA_PIX 2.8 V Pixel
VDDSLVS_PHY 0.4 V or 1.2 V HiSPi PHY. (HiSPi Mode Only)
VDDSW, VDD_ANA, VDD_PLL 1.2 V Digital
VDD_IO 1.8 V/2.8 V IO
VDD_PHY 1.2 V HiSPi/MIPI
VDD_1V8 1.8 V OTPM
AR0835HS
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SYSTEM STATES
The system states of the AR0835HS are represented as
a state diagram in Figure 5 and described in subsequent
sections.
The sensor s operation is broken down into three separate
states: hardware standby, software standby, and streaming.
The transition between these states might take a certain
amount of clock cycles as outlined in Figure 5 and Figure 6.
Figure 5. System States
Powered OFF
Internal
Initialization
Software
Standby
PLL Lock
Streaming Wait for Frame End
Frame in Progress
PLL Locked
Two-wire Serial Interface
Write: mode_select = 1
Timeout
XSHUTDOWN = 1
Powered On
EXTCLK
Cycles
XSHUTDOWN = 0
PLL Not Locked
Streaming
Two-wire Serial Interface
Write: software_reset = 1
Power Supplies Turned Off
(Asynchronous from Any State)
Hardware
Standby
Two-wire Serial Interface
Write: mode_select = 0
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9
SENSOR INITIALIZATION
Power-Up Sequence
AR0835HS has four voltage supplies divided into several
domains. The four voltages are 1.2 V (digital), 1.8 V, 2.8 V,
and analog 1.2 V or 0.4 V. For proper operation of the chip,
a power-up sequence is recommended as shown in Figure 6.
The power sequence is governed by controlled vs
controlling behavior of a power supply and the inrush
current (ie current that exists when not all power supplies are
present).
Table 6. INRUSH CONSIDERATION
XSHUTDOWN 1.2 V 1.8 V (VDD_IO) 2.8 V Comment
x Present Absent Absent Not Supported
x Absent Present Absent Supported
x Absent Absent Present Supported
x Present Present Absent Supported
x Present Absent Present Not Supported
x Absent Present Present Supported
0 Present Present Present Powered Down State
1 Present Present Present Powered Up State
Since VDD_IO supply controls the XSHUTDOWN, it
should be turned on first. The sequence of powering up the
other two domains is not too critical. While turning on 2.8 V
supply before 1.2 V supply shouldn’t be an issue as shown
in Table 1, it is still not recommended since the 2.8 V
domain is controlled by 1.2 V signals. The dedicated 1.8 V
domain is used only for OTPM read function, so can turn on
along with 1.8 V supply.
Due to the above considerations, the suggested power-on
sequence is as shown in Figure 6:
Figure 6. Recommended Power-Up Sequence
VDD_IO,
VDD_SLVS
VDD_1V8
VDD_1V2,
VDD_1V2_PHY
VAA,
VAA_PIX
EXTCLK
XSHUTDOWN
SDATA
SCLK
t1
t2
t3
t4
t5t6
Soft Standby StreamingInternal InitHard Reset
First Serial Wire
PLL
Lock
AR0835HS
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10
Table 7. POWER-UP SEQUENCE
Symbol Definition Minimum Typical Maximum Unit
t1VDD_IO to VDD_1V8 500 ms
t2VDD_1V8 to VDD_1V2 0.2 500 ms
t3VDD_1V2 to VAA 0.2 500 ms
t4Active Hard Reset 1 500 ms
t5Internal Initialization 2400 EXTCLKs
t6PLL Lock Time 1 5 ms
Power-Down Sequence
The recommended power-down sequence for the
AR0835HS is shown in Figure 7. The three power supply
domains (1.2 V, 1.8 V, and 2.8 V) must have the separation
specified below.
1. Disable streaming if output is active by setting
standby R0x301a[2] = 0.
2. After disabling the internal clock EXTCLK,
disable XSHUTDOWN.
3. After XSHUTDOWN is LOW disable the
2.8 V/1.8 V supply.
4. After the 2.8 V/1.8 V supply is LOW disable the
1.2 V supply.
5. After the 1.2 V supply is LOW disable the
VDD_IO supply.
Figure 7. Recommended Power-Down Sequence
VDD_IO,
VDD_SLVS
VDD_1V8
VDD_1V2,
VDD_1V2_PHY
VAA,
VAA_PIX
EXTCLK
XSHUTDOWN
SDATA
SCLK
t1
Hard Reset
t2
t3
t0
Soft StandbyStreaming Turn Off Power Supplies
Focal Planes
Deactivation
Table 8. POWER-DOWN SEQUENCE
Symbol Definition Minimum Typical Maximum Unit
EXTCLK Inactive to XSHUTDOWN Active 100 ms
t0XSHUTDOWN to VAA 200 ms
t1VAA to VDD_1V2 0 ms
t2VDD_1V2 to VDD_1V8 0 ms
t3VDD_1V8 to VDD_IO 0 ms
AR0835HS
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Hard Standby and Hard Reset
The hard standby state is reached by the assertion of the
XSHUTDOWN pad (hard reset). Register values are not
retained by this action, and will be returned to their default
values once hard reset is completed. The minimum power
consumption is achieved by the hard standby state.
The details of the sequence are described below and shown
in Figure 8.
1. Disable streaming if output is active by setting
mode_select 0x301A[2] = 0.
2. The soft standby state is reached after the current
row or frame, depending on configuration, has
ended.
3. Assert XSHUTDOWN (active LOW) to reset the
sensor.
4. The sensor remains in hard standby state if
XSHUTDOWN remains in the logic “0” state.
Figure 8. Hard Standby and Hard Reset
EXTCLK
XSHUTDOWN
mode_select
R0x0100 Logic “1” Logic “0”
New Row/Frame
Streaming Soft Standby Hard Standby Hard Reset
Soft Standby and Soft Reset
The AR0835HS can reduce power consumption by
switching to the soft standby state when the output is not
needed. R egister values are retained in the soft standby state.
The details of the sequence are described below and shown
in Figure 9.
Soft Standby
1. Disable streaming if output is active by setting
mode_select 0x301A[2] = 0.
2. The soft standby state is reached after the current
row or frame, depending on configuration, has
ended.
Soft Reset
1. Follow the soft standby sequence list above.
2. Set software_reset = 1 (R0x3021) to start the
internal initialization sequence.
3. After 2400 EXTCLKs , the internal initialization
sequence is completed and the current state returns
to soft standby automatically.
Figure 9. Soft Standby and Soft Reset
EXTCLK
mode_select
R0x0100 Logic “1”
New
Row/Frame
Streaming
software_reset
R0x0103
Logic “0”
Logic “0” Logic “1” Logic “0”
Soft Standby Soft Standby
Soft Reset
480
EXTCLKs
2400
EXTCLKs
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12
TWO-WIRE SERIAL REGISTER INTERFACE
A two-wire serial interface bus enables read/write access
to control and status registers within the AR0835HS.
The two-wire serial interface is fully compatible with the
I2C standard.
The interface protocol uses a master/slave model in which
a master controls one or more slave devices. The sensor acts
as a slave device. The master generates a clock (SCLK) that
is an input to the sensor and is used to synchronize transfers.
Data is transferred between the master and the slave on
a bidirectional signal (SDATA). SDATA is pulled up to VDD
off-chip by a 1.5 kW resistor. Either the slave or master
device can drive SDATA LOW − the interface protocol
determines which device is allowed to drive SDATA at any
given time.
The protocols described in the two-wire serial interface
specification allow the slave device to drive SCLK LOW ; the
AR0835HS uses SCLK as an input only and therefore never
drives it LOW. The electrical and timing specifications are
further detailed on “Two-Wire Serial Register Interface”.
Protocol
Data transfers on the two-wire serial interface bus are
performed by a sequence of low-level protocol elements:
1. a (repeated) start condition
2. a slave address/data direction byte
3. an (a no) acknowledge bit
4. a message byte
5. a stop condition
The bus is idle when both SCLK and SDATA are HIGH.
Control of the bus is initiated with a start condition, and the
bus is released with a stop condition. Only the master can
generate the start and stop conditions.
Start Condition
A start condition is defined as a HIGH-to-LOW transition
on SDATA while SCLK is HIGH. At the end of a transfer , the
master can generate a start condition without previously
generating a stop condition; this is known as a “repeated
start” or “restart” condition.
Stop Condition
A stop condition is defined as a LOW-to-HIGH transition
on SDATA while SCLK is HIGH.
Data Transfer
Data is transferred serially, 8 bits at a time, with the MSB
transmitted first. Each byte of data is followed by an
acknowledge bit or a no-acknowledge bit. This data transfer
mechanism is used for the slave address/data direction byte
and for message bytes.
One data bit is transferred during each SCLK clock period.
SDATA can change when SCLK is LOW and must be stable
while SCLK is HIGH.
Slave Address/Data Direction Byte
Bits [7:1] of this byte represent the device slave address
and bit [0] indicates the data transfer direction. A “0” in bit
[0] indicates a WRITE, and a “1” indicates a READ.
Alternate slave addresses of 0x6E(write address) and
0x6F(read address) can be selected by enabling and
asserting the SADDR signal through the GPI pad.
The alternate slave addresses can also be programmed
through R0x31FC.
Message Byte
Message bytes are used for sending register addresses and
register write data to the slave device and for retrieving
register read data.
Acknowledge Bit
Each 8-bit data transfer is followed by an acknowledge bit
or a no-acknowledge bit in the SCLK clock period following
the data transfer. The transmitter (which is the master when
writing, or the slave when reading) releases SDATA. The
receiver indicates an acknowledge bit by driving SDATA
LOW.
No-Acknowledge Bit
The no-acknowledge bit is generated when the receiver
does not drive SDATA LOW during the SCLK clock period
following a data transfer. A no-acknowledge bit is used to
terminate a read sequence.
Typical Sequence
A typical READ or WRITE sequence begins by the
master generating a start condition on the bus. After the start
condition, the master sends the 8-bit slave address/data
direction byte. The last bit indicates whether the request is
for a read or a write, where a “0” indicates a write and a “1”
indicates a read. If the address matches the address of the
slave device, the slave device acknowledges receipt of the
address by generating an acknowledge bit on the bus.
If the request was a WRITE, the master then transfers the
16-bit register address to which the WRITE should take
place. This transfer takes place as two 8-bit sequences and
the slave sends an acknowledge bit after each sequence to
indicate that the byte has been received. The master then
transfers the data as an 8-bit sequence; the slave sends an
acknowledge bit at the end of the sequence. The master stops
writing by generating a (re)start or stop condition.
If the request was a READ, the master sends the 8-bit write
slave address/data direction byte and 16-bit register address,
the same way as with a WRITE request. The master then
generates a (re)start condition and the 8-bit read slave
address/data direction byte, and clocks out the register data,
eight bits at a time. The master generates an acknowledge bit
after each 8-bit transfer. The slave’s internal register address
is automatically incremented after every 8 bits are
transferred. The data transfer is stopped when the master
sends a no-acknowledge bit.
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Single READ from Random Location
This sequence (Figure 10) starts with a dummy WRITE to
the 16-bit address that is to be used for the READ. The
master terminates the WRITE by generating a restart
condition. The master then sends the 8-bit read slave
address/data direction byte and clocks out one byte of
register data. The master terminates the READ by
generating a no-acknowledge bit followed by a stop
condition. Figure 10 shows how the internal register address
maintained by the AR0835HS is loaded and incremented as
the sequence proceeds.
Figure 10. Single READ from Random Location
Previous Reg Address, N Reg Address, M M+1
S0 1 PASr
Slave Ad-
dress Reg
Address[15:8] Reg
Address[7:0] Slave Address
S = Start Condition
P = Stop Condition
Sr = Restart Condition
A = Acknowledge
A = No-acknowledge Slave to Master
Master to Slave
A A A A Read Data
Single READ from Current Location
This sequence (Figure 11) performs a read using the
current value of the AR0835HS internal register address.
The master terminates the READ by generating
a no-acknowledge bit followed by a stop condition.
The figure shows two independent READ sequences.
Figure 11. Single READ from Current Location
Previous Reg Address, N Reg Address, N+1 N+2
S1 PSlave Address AARead Data S1 PSlave Address AARead Data
Sequential READ, Start from Random Location
This sequence (Figure 12) starts in the same way as the
single READ from random location (Figure 10). Instead of
generating a no-acknowledge bit after the first byte of data
has been transferred, the master generates an acknowledge
bit and continues to perform byte READs until “L” bytes
have been read.
Figure 12. Sequential READ, Start from Random Location
Previous Reg Address, N Reg Address, M
S0Slave Address A AReg Address[15:8]
PA
M+1
A A A1SrReg Address[7:0] Read DataSlave Address
M+LM+L−1M+L−2M+1 M+2 M+3
ARead Data A Read Data ARead Data Read Data
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Sequential READ, Start from Current Location
This sequence (Figure 13) starts in the same way as the
single READ from current location (Figure 11). Instead of
generating a no-acknowledge bit after the first byte of data
has been transferred, the master generates an acknowledge
bit and continues to perform byte READs until “L” bytes
have been read.
Figure 13. Sequential READ, Start from Current Location
N+LN+L−1N+2N+1Previous Reg Address, N
PAS 1 Read DataASlave Address Read DataRead Data Read DataAAA
Single WRITE to Random Location
This sequence (Figure 14) begins with the master
generating a start condition. The slave address/data
direction byte signals a WRITE and is followed by the HIGH
then LOW bytes of the register address that is to be written.
The master follows this with the byte of write data. The
WRITE is terminated by the master generating a stop
condition.
Figure 14. Single WRITE to Random Location
Previous Reg Address, N Reg Address, M M+1
S0 PSlave Address Reg Address[15:8] Reg Address[7:0] A
A
A
AA Write Data
Sequential WRITE, Start at Random Location
This sequence (Figure 15) starts in the same way as the
single WRITE to random location (Figure 14). Instead of
generating a no-acknowledge bit after the first byte of data
has been transferred, the master generates an acknowledge
bit and continues to perform byte WRITEs until “L” bytes
have been written. The WRITE is terminated by the master
generating a stop condition.
Figure 15. Sequential WRITE, Start at Random Location
Previous Reg Address, N Reg Address, M M+1
S0Slave Address A Reg Address[15:8] A A AReg Address[7:0] Write Data
M+LM+L−1M+L−2M+1 M+2 M+3
Write Data AA A
AP
A
Write Data Write Data Write Data
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REGISTERS
The AR0835HS provides a 16-bit register address space
accessed through a serial interface (“Two-Wire Serial
Register Interface”). Each register location is 8 or 16 bits in
size.
The address space is divided into the five major regions
shown in Table 9. The remainder of this section describes
these registers in detail.
Table 9. ADDRESS SPACE REGIONS
Address Range Description
0x0000–0x0FFF Configuration registers (read-only and read-write dynamic registers)
0x1000–0x1FFF Parameter limit registers (read-only static registers)
0x2000–0x2FFF Image statistics registers (none currently defined)
0x3000–0x3FFF Manufacturer-specific registers (read-only and read-write dynamic registers)
Register Notation
The underlying mechanism for reading and writing
registers provides byte write capability. However, it is
convenient to consider some registers as multiple adjacent
bytes. The AR0835HS uses 8-bit, 16-bit, and 32-bit
registers, all implemented as 1 or more bytes at naturally
aligned, contiguous locations in the address space.
In this document, registers are described either by address
or by name. When registers are described by address, the
size of the registers is explicit. For example, R0x3024 is
a 2-bit register at address 0x3024, and R0x3000–1 is a 16-bit
register at address 0x3000–0x3001. When registers are
described by name, the size of the register is implicit. It is
necessary to refer to the register table to determine that
model_id is a 16-bit register.
Register Aliases
A consequence of the internal architecture of the
AR0835HS is that some registers are decoded at multiple
addresses. Some registers in “configuration space” are also
decoded in “manufacturer-specific space”. To provide
unique names for all registers, the name of the register
within manufacturer-specific register space has a trailing
underscore. For example, R0x0202 is coarse_integration_
time and R0x3012 is coarse_integration_time_. The effect
of reading or writing a register through any of its aliases is
identical.
Bit Fields
Some registers provide control of several different pieces
of related functionality, and this makes it necessary to refer
to bit fields within registers. As an example of the notation
used for this, the least significant 4 bits of the chip_version_
reg register are referred to as chip_version_reg[3:0] or
R0x0000–1[3:0].
Bit Field Aliases
In addition to the register aliases described above, some
register fields are aliased in multiple places. For example,
R0x0100 (mode_select) has only one operational bit,
R0x0100[0]. This bit is aliased to R0x301A–B[2].
The effect o f reading or writing a bit field through any of its
aliases is identical.
Byte Ordering
Registers that occupy more than one byte of address space
are shown with the lowest address in the highest-order byte
lane to match the byte-ordering on the data bus. For
example, the chip_version_reg register is R0x00001. In the
register table the default value is shown as 0x4B00. This
means tha t a r e a d f r o m a d d r e s s 0 x 0 0 0 0 w o u l d r e t u r n 0 x 4 B ,
and a read from address 0x0001 would return 0x00. When
reading this register as two 8-bit transfers on the serial
interface, the 0x4B will appear on the serial interface first,
followed by the 0x00.
Address Alignment
All register addresses are aligned naturally. Registers that
occupy 2 bytes of address space are aligned to even 16-bit
addresses, and registers that occupy 4 bytes of address space
are aligned to 16-bit addresses that are an integer multiple of
4.
Bit Representation
For clarity, 32-bit hex numbers are shown with an
underscore between the upper and lower 16 bits. For
example: 0x3000_01AB.
Data Format
Most registers represent an unsigned binary value or set of
bit fields. For all other register formats, the format is stated
explicitly at the start of the register description. The notation
for these formats is shown in Table 10.
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Table 10. DATA FORMATS
Name Description
FIX16 Signed fixed-point, 16-bit number: two’s complement number, 8 fractional bits.
Examples:
0x0100 = 1.0
0x8000 = –128
0xFFFF = –0.0039065
UFIX16 Unsigned fixed-point, 16-bit number: 8.8 format.
Examples:
0x0100 = 1.0
0x280 = 2.5
FLP32 Signed floating-point, 32-bit number: IEEE 754 format.
Example:
0x4280_0000 = 64.0
Register Behavior
Registers vary from “read-only”, “read/write”, and “read,
write-1-to-clear”.
Double-Buffered Registers
Some sensor settings cannot be changed during frame
readout. For example, changing R0x3004–5 (x_addr_start)
partway through frame readout would result in inconsistent
row lengths within a frame. To avoid this, the AR0835HS
double-buffers many registers by implementing a “pending”
and a “live” version. Reads and writes access the pending
register. The live register controls the sensor operation.
The value in the pending register is transferred to a live
register at a fixed point in the frame timing, called frame
start. Frame start is defined as the point at which the first
dark row is read out internally to the sensor. In the register
tables the “Frame Sync’d” column shows which registers or
register fields are double-buffered in this way.
Using grouped_parameter_hold
Register grouped_parameter_hold (R0x301A[15]) can be
used to inhibit transfers from the pending to the live
registers. When the AR0835HS is in streaming mode, this
register should be written to “1” before making changes to
any group of registers where a set of changes is required to
take effect simultaneously. When this register is written to
“0”, all transfers from pending to live registers take place on
the next frame start.
An example of the consequences of failing to set this bit
follows:
An external auto exposure algorithm might want to
change both gain and integration time between two
frames. If the next frame starts between these
operations, it will have the new gain, but not the new
integration time, which would return a frame with the
wrong brightness that might lead to a feedback loop
with the AE algorithm resulting in flickering.
Bad Frames
A bad frame is a frame where all rows do not have the
same integration time or where offsets to the pixel values
have changed during the frame.
Many changes to the sensor register settings can cause
a bad frame. For example, when line_length_pck
(R0x300C) i s changed, the new register value does not af fect
sensor behavior until the next frame start. However,
the frame that would be read out at that frame start will have
been integrated using the old row width, so reading it out
using the new row width would result in a frame with an
incorrect integration time.
By default, bad frames are masked. If the masked bad
frame option is enabled, both LV and FV are inhibited for
these frames so that the vertical blanking time between
frames is extended by the frame time.
In the register tables, the “Bad Frame” column shows
where changing a register or register field will cause a bad
frame. This notation is used:
N − No. Changing the register value will not produce
a bad frame.
Y Yes. Changing the register value might produce
a bad frame.
YM Yes; but the bad frame will be masked out when
mask_corrupted_frames (R0x301A[9]) is set to “1”.
Changes to Integration Time
If the integration time is changed while FV is asserted for
frame n, the first frame output using the new integration time
is frame (n + 2). The sequence is as follows:
1. During frame n, the new integration time is held in
the pending register.
2. At the start of frame (n + 1), the new integration
time is transferred to the live register. Integration
for each row of frame (n + 1) has been completed
using the old integration time.
3. The earliest time that a row can start integrating
using the new integration time is immediately after
that row has been read for frame (n + 1).
The actual time that rows start integrating using
the new integration time is dependent upon the
new value of the integration time.
4. When frame (n + 2) is read out, it will have been
integrated using the new integration time.
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If the integration time is changed on successive frames,
each value written will be applied for a single frame; the
latency between writing a value and it affecting the frame
readout remains at two frames.
Changes to Gain Settings
Usually, when the gain settings are changed, the gain is
updated on the next frame start. When the integration time
and the gain are changed at the same time, the gain update
is held off by one frame so that the first frame output with the
new integration time also has the new gain applied. In this
case, a new gain should not be set during the extra frame
delay. There is an option to turn off the extra frame delay by
setting extra_delay (R0x3018).
CLOCKING
Default setup gives a physical 73.2 MHz internal clock for
an external input clock of 24 MHz.
The sensor contains a phase-locked loop (PLL) for timing
generation and control. The PLL contains a prescaler to
divide the input clock applied on EXTCLK, a VCO to
multiply the prescaler output, and a set of dividers to
generate the output clocks. The PLL structure is shown in
Figure 16.
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Figure 16. Clocking Configuration (PLL)
pll _multiplier (R0x306)
(even number of 32−255
max vco freq is 1000 MHz)
PLL
Multiplier
(m)
PLL internal VCO
frequency
op_sys_clk
op sys clk
Divider
op pix
clk
Divider
op_pix_clk
clk _op
Divider clk_op
row_speed (R0x3016[10:8])
(1, 2, 4)
op_pix_clk_div (R0x308)
(8, 10)
op_sys_clk_div (R0x30A)
(1, 2, 4, 6, 8, 10, 12, 14, 16)
EXTCLK
(6 to 27 MHz)
Pre PLL
Divider
(n +1)
External input clock
PLL input clock
pll_ip_clk_freq
(4−24 MHz)
pre_pll_clk_div (R0x304)
(1 to 64)
(1 must only be used
with even pll_multiplier values)
clk_pixel
Divider
vt_pix_clk
row_speed (R0x3016[2:0])
(1,2,4)
vt_sys_clk
vt sys clk Divider
(max freq
(450 MHz))
vt pix
clk
Divider
clk_pixel
vt_pix_clk_div (R0x300)
(4 to 16, 3 with 3064[13]=0)
vt_sys_clk_div (R0x302)
(1, 2, 4, 6, 8, 10, 12, 14, 16)
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Figure 16 shows the dif ferent clocks and the names of the
registers that contain or are used to control their values. The
vt_pix_clk is divided by two to compensate for the fact that
the design has 2 digital data paths. This divider should
always remain turned on.
AR0835HS has 10-to-8 compression.
The usage of the output clocks is shown below:
clk_pixel (vt_pix_clk/row_speed[2:0]) is used by the
sensor core to readout and control the timing of the
pixel array. The sensor core produces one 10-bit pixel
each vt_pix_clk period. The line length
(line_length_pck) is controlled in increments of the
clk_pixel period
clk_op (op_pix_clk/row_speed[10:8]) is used to load
parallel pixel data from the output FIFO (see Figure 41)
to the serializer. The output FIFO generates one pixel
each op_pix_clk period
op_sys_clk is used to generate the serial data stream on
the output. The relationship between this clock
frequency and the op_pix_clk frequency is dependent
upon the output data format
The pixel frequency can be calculated in general as:
pixel_clock_mhz +ext_clk_freq_mhz pll_multiplier
pre_pll_clk_div vt_sys_clk_div 2 vt_pix_clk_div row_speed[2:0] (eq. 1)
The output clock frequency can be calculated as:
clk_op_freq_mhz +ext_clk_freq_mhz pll_multiplier
pre_pll_clk_div op_sys_clk_div op_pix_clk_div row_speed[10:8] (eq. 2)
op_sys_clk_freq_mhz +ext_clk_freq_mhz pll_multiplier
pre_pll_clk_div op_sys_clk_div (eq. 3)
PLL Clocking
The PLL divisors should be programmed while the
AR0835HS is in the software standby state. After
programming the divisors, it is necessary to wait for the
VCO lock time before enabling the PLL. The PLL is enabled
by entering the streaming state.
An external timer will need to delay the entrance of the
streaming mode by 1 millisecond so that the PLL can lock.
The effect of programming the PLL divisors while the
AR0835HS is in the streaming state is undefined.
Clock Control
The AR0835HS uses an aggressive clock-gating
methodology to reduce power consumption. The clocked
logic is divided into a number of separate domains, each of
which is only clocked when required.
When the AR0835HS enters a soft standby state, almost
all of the internal clocks are stopped. The only exception is
that a small amount of logic is clocked so that the two-wire
serial interface continues to respond to read and write
requests.
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FEATURES
Interlaced HDR Readout
The sensor enables HDR by outputting frames where even
and odd row pairs within a single frame are captured at
different integration times. This output is then matched with
an algorithm designed to reconstruct this output into an
HDR still image or video.
The sensor HDR is controlled by two shutter pointers
(Shutter pointer1, Shutter pointer2) that control the
integration of the odd (Shutter pointer1) and even (Shutter
pointer2) row pairs.
Figure 17. HDR Integration Time
Tint 1
Tint 2
I−FRAME 1
I−FRAME 2
Output Frame from Sensor
EXPOSURE
I−FRAME 1
EXPOSURE
I−FRAME 1
Shutter Pointer 1
Shutter Pointer 2
Sample Pointer
Output
I−FRAME 1
and 2
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INTEGRATION TIME FOR INTERLACED HDR READOUT
Tint1 (Integration Time 1) and Tint2 (Integration Time 2)
The limits for the coarse integration time are defined by:
coarse_integration_time_min vcoarse_integration_time v(frame_length_lines *coarse_integration_time_max_margin) (eq. 4)
coarse_integration_time2_min vcoarse_integration_time2 v(frame_length_lines *coarse_integration_time2_max_margin) (eq. 5)
The actual integration time is given by:
integration_time +coarse_integration_time line_length_pck
vt_pix_clk_freq_mhz 106(eq. 6)
integration_time2 +coarse_integration_time2 line_length_pck
vt_pix_clk_freq_mhz 106(eq. 7)
If this limit is broken, the frame time will automatically be
extended to (coarse_integration_time + coarse_
integration_time_max_margin) to accommodate the larger
integration time.
The ratio between even and odd rows is typically adjusted
to 1×, 2×, 4×, and 8×.
Bayer Resampler
The imaging artifacts found from a 2 ×2 binning or
summing will show image artifacts from aliasing. These can
be corrected by resampling the sampled pixels in order to
filter these artifacts. Figure 18 shows the pixel location
resulting from 2 ×2 summing or binning located in the
middle and the resulting pixel locations after the Bayer
re-sampling function has been applied.
Figure 18. Bayer Resampling
The improvements from using the Bayer resampling
feature can be seen in Figure 19. In this example, image
edges seen on a diagonal have smoother edges when the
Bayer re-sampling feature is applied. This feature is only
designed to be used with modes configured with 2 ×2
binning or summing. The feature will not remove aliasing
artifacts that are caused skipping pixels.
Figure 19. Results of Resampling
2 × 2 Binned − Before 2 × 2 Binned − After
Resampling
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To enable the Bayer resampling feature:
1. Set R0x400 = 2 // Enable the on-chip scalar.
2. Set R0x306E to 0x90B0 // Configure the on-chip
scalar to resample Bayer data.
To disable the Bayer resampling feature:
1. Set R0x400 = 0 // Disable the on-chip scalar.
2. Set R0x306E to 0x9080 // Configure the on-chip
scalar to resample Bayer data.
NOTE: The image readout (rows and columns) has to
have two extra rows and two extra columns
when using the resample feature.
Figure 20. Illustration of Resampling Operation
Image Array Readout
3264 × 2448 Image Size Output
1632 × 1224 Resampled Image Output
1632 × 1224
Resampling2 × 2 Binning
One-Time Programmable Memory (OTPM)
The AR0835HS features 5.6 kbits of one-time
programmable memory (OTPM) for storing shading
correction coefficients, individual module, and
customer-specific information. The user may program the
data before shipping. OTPM can be accessed through
two-wire serial interface. The AR0835HS uses the auto
mode for fast OTPM programming and read operations.
To read out the OTPM, 1.8 V supply is required. As
a result, a dedicated DVDD_1V8 pad has been implemented.
During the programming process, a dedicated pin for high
voltage needs to be provided to perform the anti-fusing
operation. This voltage (VPP) would need to be 6.5 V.
The completion of the programming process will be
communicated by a register through the two-wire serial
interface.
If the VPP pin does not need to be bonded out as a pin on
the module, it should be left floating inside the module.
The programming of the OTPM requires the sensor to be
fully powered and remain in software standby with its clock
input applied. The information will be programmed through
the use of the two-wire serial interface, and once the data is
written to an internal register, the programming host
machine will apply a high voltage to the programming pin,
and send a program command to initiate the anti-fusing
process. After the sensor has finished programming the
OTPM, a status bit will be set to indicate the end of the
programming cycle, and the host machine can poll the
setting o f the status bit through the two-wire serial interface.
Only one programming cycle for the 16-bit word can be
performed.
Reading the OTPM data requires the sensor to be fully
powered and operational with its clock input applied. The
data can be read through a register from the two-wire serial
interface.
Programming and Verifying the OTPM
The procedure for programming and verifying the
AR0835HS OTPM follows:
1. Apply power to all the power rails of the sensor.
2. Provide a 12-MHz EXTCLK clock input.
3. Set R0x301A = 0x18, to put sensor in the soft
standby mode.
4. Set R0x3130 = 0xFF01 (Timing configuration).
5. Set R0x304C[15:8] = Record type (e.g. 0x30).
6. Set R0x304C[7:0] = Length of the record which is
the number of OTPM data registers that are filled
in.
7. Set R0x3054[9] = 0 to ensure that the error
checking and correction is enabled.
8. Write data into all the OTPM data registers:
R0x3800−R0x39FE.
9. Ramp up VPP to 6.5 V.
10. Set the otpm_control_auto_wr_start bit in the
otpm_control register R0x304A[0] = 1, to initiate
the auto program sequence. The sensor will now
program the data into the OTPM.
11. Poll otpm_control_auto_wr_end (R0x304A [1]) to
determine when the sensor is finished
programming the word.
12. Verify that the otpm_control_auto_wr_success
(0x304A[2]) bit is set.
13. If the above bits are not set to 1, then examine
otpm_status register R0x304E[9] to verify if the
OTPM memory is full and 0x304E[10] to verify if
OTPM memory is insufficient.
14. Remove the high voltage (VPP) and float VPP pin.
Reading the OTPM
1. Apply power to all the power rails of the sensor
(VDD_IO, VAA, VAA_PIX, DVDD_1V2,
DVDD_1V2_PHY, and DVDD_1V8) at their
nominal voltage.
2. Set EXTCLK to normal operating frequency.
3. Perform proper reset sequence to the sensor.
4. Set R0x3134 = 0xCD95 (Timing Configuration)
5. Set R0x304C[15:8] = Record Type
(for example, 0x30)
6. Set R0x304C[7:0] = Length of the record which is
the number of data registers to be read back. This
could be set to 0 during OTPM auto read if length
is unknown.
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7. Set R0x3054 = 0x0400.
8. Initiate the auto read sequence by setting the
otpm_control_auto_read_start bit
(R0x304A[4]) = 1.
9. Poll the otpm_control_auto_rd_end bit
(R0x304A[5]) to determine when the sensor is
finished reading the word(s). When this bit
becomes 1, the otpm_control_auto_rd_success bit
(R0x304A[6]) will indicate whether the memory
was read successfully or not.
10. Data can now be read back from the otpm_data
registers (R0x3800−R0x39FE).
Image Acquisition Modes
The AR0835HS supports two image acquisition modes:
1. Electronic Rolling Shutter (ERS) Mode:
This is the normal mode of operation. When the
AR0835HS is streaming, it generates frames at
a fixed rate, and each frame is integrated (exposed)
using the ERS. When the ERS is in use, timing
and control logic within the sensor sequences
through the rows of the array, resetting and then
reading each row in turn. In the time interval
between resetting a row and subsequently reading
that row, the pixels in the row integrate incident
light. The integration (exposure) time is controlled
by varying the time between row reset and row
readout. For each row in a frame, the time between
row reset and row readout is fixed, leading to a
uniform integration time across the frame. When
the integration time is changed (by using the
two-wire serial interface to change register
settings), the timing and control logic controls the
transition from old to new integration time in such
a way that the stream of output frames from the
AR0835HS switches cleanly from the old
integration time to the new while only generating
frames with uniform integration. See “Changes to
Integration Time”.
2. Global Reset Release (GRR) Mode:
This mode can be used to acquire a single image at
the current resolution. In this mode, the end point
of the pixel integration time is controlled by an
external electromechanical shutter, and the
AR0835HS provides control signals to interface to
that shutter. The operation of this mode is
described in detail in “Global Reset Release
(GRR)”.
The benefit for the use of an external electromechanical
shutter is that it eliminates the visual artifacts associated
with ERS operation. Visual artifacts arise in ERS operation,
particularly at low frame rates, because an ERS image
effectively integrates each row of the pixel array at
a different point in time.
Window Control
The sequencing of the pixel array is controlled by the
x_addr_start, y_addr_start, x_addr_end, and y_addr_end
registers. The output image size is controlled by the
x_output_size and y_output_size registers.
Pixel Border
The default settings of the sensor provide
a 3264 (H) ×2448 (V) image. A border of up to 8 pixels (4
in binning) on each edge can be enabled by reprogramming
the x_addr_start, y_addr_start, x_addr_end, y_addr_end,
x_output_size, and y_output_size registers accordingly.
These border pixels can be used but are disabled by default.
Readout Modes
Horizontal Mirror
The horizontal_mirror bit in the image_orientation
register is set by default. The result of this is that the order
of pixel readout within a row is reversed, so that readout
starts from x_addr_end and ends at x_addr_start. Figure 21
shows a sequence of 6 pixels being read out with
horizontal_mirror = 0 and horizontal_mirror = 1. Changing
horizontal_mirror causes the Bayer order of the output
image to change; the new Bayer order is reflected in the
value of the pixel_order register.
Figure 21. Effect of horizontal_mirror on Readout Order
G0[9:0] R0[9:0] G1[9:0] R1[9:0] G2[9:0] R2[9:0]
R2[9:0] G2[9:0] R1[9:0] G1[9:0] R0[9:0] G0[9:0]
LINE_VALID
horizontal_mirror = 0
horizontal_mirror = 1
DOUT[9:0]
DOUT[9:0]
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Vertical Flip
When the vertical_flip bit is set in the image_orientation
register, the order in which pixel rows are read out is
reversed, so that row readout starts from y_addr_end and
ends at y_addr_start. Figure 22 shows a sequence of 6 rows
being read out with vertical_flip = 0 and vertical_flip = 1.
Changing vertical_flip causes the Bayer order of the output
image to change; the new Bayer order is reflected in the
value of the pixel_order register.
Figure 22. Effect of vertical_flip on Readout Order
Row0[9:0] Row1[9:0] Row2[9:0] Row3[9:0] Row4[9:0] Row5[9:0]
Row5[9:0] Row4[9:0] Row3[9:0] Row2[9:0] Row0[9:0]
FRAME_VALID
vertical_flip = 0
vertical_flip = 1 Row1[9:0]
DOUT[9:0]
DOUT[9:0]
Subsampling
The AR0835HS supports subsampling to reduce the
amount of data processed by the signal chains in the
AR0835HS, thereby allowing the frame rate to be increased
and power consumption reduced. Subsampling is enabled
by setting x_odd_inc and/or y_odd_inc. Values of 1, 3, and
7 can be supported. Setting both of these variables to 3
reduces the amount of row and column data processed and
is equivalent to the 2 ×2 skipping readout mode provided b y
the AR0835HS. Setting x_odd_inc = 3 and y_odd_inc = 3
results in a quarter reduction in output image size. Figure23
shows a sequence of 8 columns being read out with
x_odd_inc = 3 and y_odd_inc = 1.
Figure 23. Effect of x_odd_inc = 3 on Readout Sequence
G0[9:0] R0[9:0] G1[9:0] R1[9:0] G2[9:0] R2[9:0] G3[9:0] R3[9:0]
G0[9:0] R0[9:0] G2[9:0] R2[9:0]
LINE_VALID
x_odd_inc = 1
LINE_VALID
x_odd_inc = 3
DOUT[9:0]
DOUT[9:0]
A 1/16 reduction in resolution is achieved by setting both
x_odd_inc and y_odd_inc to 7. This is equivalent to 4 ×4
skipping readout mode provided by the AR0835HS.
Figure 24 shows a sequence of 16 columns being read out
with x_odd_inc = 7 and y_odd_inc = 1.
Figure 24. Effect of x_odd_inc = 7 on Readout Sequence
G0[9:0] R0[9:0] G1[9:0] R1[9:0] G2[9:0] G7[9:0] R7[9:0]
G0[9:0] R0[9:0] G4[9:0] R4[9:0]
LINE_VALID
x_odd_inc = 1
LINE_VALID
x_odd_inc = 7
...
DOUT[9:0]
DOUT[9:0]
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The effect of the different subsampling settings on the
pixel array readout is shown in Figure 25 through Figure 27.
Figure 25. Pixel Readout (No Subsampling)
X incrementing
Y incrementing
Figure 26. Skip2 Pixel Readout
(x_odd_inc = 3, y_odd_inc = 3)
X incrementing
Y incrementing
Figure 27. Skip4 Pixel Readout (x_odd_inc = 7, y_odd_inc = 7)
X incrementing
Y incrementing
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Programming Restrictions when Subsampling
When subsampling is enabled and the sensor is switched
back and forth between full resolution and subsampling,
ON Semiconductor recommends that line_length_pck be
kept constant between the two modes. This allows the same
integration times to be used in each mode.
When subsampling is enabled, it may be necessary to
adjust the x_addr_start, x_addr_end, y_addr_start, and
y_addr_end settings: the values for these registers are
required to correspond with rows/columns that form part of
the subsampling sequence. The adjustment should be made
in accordance with these rules:
x_skip_factor = (x_odd_inc + 1) / 2
y_skip_factor = (y_odd_inc + 1) / 2
x_addr_start should be a multiple of x_skip_factor × 4
(x_addr_end − x_addr_start + x_odd_inc) should be
a multiple of x_skip_factor × 4
(y_addr_end − y_addr_start + y_odd_inc) should be
a multiple of y_skip_factor × 4
The number of columns/rows read out with subsampling
can be found from the equation below:
columns/rows = (addr_end − addr_start + odd_inc) /
skip_factor
Table 11 shows the row or column address sequencing for
normal and subsampled readout. In the 2× skip case, there
are two possible subsampling sequences (because the
subsampling sequence only reads half of the pixels)
depending upon the alignment of the start address. Similarly,
there will be four possible subsampling sequences in the 4 ×
skip case (though only the first two are shown in Table 11).
Table 11. ROW ADDRESS SEQUENCING DURING SUBSAMPLING
odd_inc = 1 (Normal) odd_inc = 3 (2y Skip) odd_inc = 7 (4y Skip)
Start = 0 Start = 0 Start = 0
0 0 0
1 1 1
2
3
4 4
5 5
6
7
8 8 8
9 9 9
10
11
12 12
13 13
14
15
Binning
The AR0835HS supports 2 ×1 (column binning, also
called x-binning). Binning has many of the same
characteristics a s skipping, but because it gathers image data
from all pixels in the active window (rather than a subset of
them), it achieves superior image quality and avoids the
aliasing artifacts that can be a characteristic side effect of
skipping.
Binning is enabled by selecting the appropriate
subsampling settings (in read_mode, the sub-register
x_odd_inc = 3 and y_odd_inc = 1 for x-binning and setting
the appropriate binning bit in read_mode R0x3040[11] = 1
for x_bin_enable). As with skipping, x_addr_end and
y_addr_end may require adjustment when binning is
enabled. It is the first of the two columns/rows binned
together that should be the end column/row in binning, so
the requirements to the end address are exactly the same as
in skipping mode. The effect of the different binning is
shown in Figure 28 below and Figure 29.
Binning can also be enabled when the 4× subsampling
mode is enabled (x_odd_inc = 7 and y_odd_inc = 1 for
x-binning, x_odd_inc = 7 and y_odd_inc = 7 for 4×
xy-binning). In this mode, however, not all pixels will be
used so this is not a 4× binning implementation. An
implementation providing a combination of skip2 and bin2
is used to achieve 4× subsampling with better image quality.
The effect of this subsampling mode is shown in Figure 29.
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Figure 28. Bin2 Pixel Readout (x_odd_inc = 3, y_odd_inc = 1, x_bin = 1)
X Incrementing
Y Incrementing
Figure 29. Bin2 Pixel Readout (x_odd_inc = 3, y_odd_inc = 3, x_bin = 1)
X Incrementing
Y Incrementing
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Binning address sequencing is a bit more complicated
than during subsampling only, because of the
implementation of the binning itself.
For a given column n, there is only one other column,
n_bin, that can be binned with, because of physical
limitations in the column readout circuitry. The possible
address sequences are shown in Table 12.
Table 12. COLUMN ADDRESS SEQUENCING DURING BINNING
odd_inc = 1 (Normal) odd_inc = 3 (2y Bin) odd_inc = 7 (2y Skip + 2y Bin)
x_addr_start = 0 x_addr_start = 0 x_addr_start = 0
0 0/2 0/4
1 1/3 1/5
2
3
4 4/6
5 5/7
6
7
8 8/10 8/12
9 9/11 9/13
10
11
12 12/14
13 13/15
14
15
There are no physical limitations on what can be binned
together in the row direction. A given row n will always be
binned with row n + 2 in 2 × subsampling mode and with row
n + 4 in 4× subsampling mode. Therefore, which rows get
binned together depends upon the alignment of
y_addr_start. The possible sequences are shown in Table 13.
Table 13. ROW ADDRESS SEQUENCING DURING BINNING
odd_inc = 1 (Normal) odd_inc = 3 (2y Bin) odd_inc = 7 (2y Skip + 2y Bin)
y_addr_start = 0 y_addr_start = 0 y_addr_start = 0
0 0/2 0/4
1 1/3 1/5
2
3
4 4/6
5 5/7
6
7
8 8/10 8/12
9 9/11 9/13
10
11
12 12/14
13 13/15
14
15
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Programming Restrictions When Binning and Summing
Binning and summing require different sequencing of the
pixel array and impose different timing limits on the
operation of the sensor.
As a result, when xy-subsampling is enabled, some of the
programming limits declared in the parameter limit registers
are no longer valid. In addition, the default values for some
of the manufacturer-specific registers need to be
reprogrammed. See “Minimum Frame Time” and
“Minimum Row Time”.
Subsampling/Binning Options:
1. XskipYskip
R0x3040[11], x_bin_en: 0
R0x3040[13], row_sum: 0
R0x0382: x_odd_inc = 3 (xskip2) or
7 (xskip4)
R0x0386: y_odd_inc = 3 (yskip2), 7 (yskip4)
or 15 (yskip8)
2. XbinYskip
R0x3040[11], x_bin_en: 1
R0x3040[13], row_sum: 0
R0x0382: x_odd_inc = 3 (xbin2)
R0x0386: y_odd_inc = 3 (yskip2), 7 (yskip4)
or 15 (yskip8)
3. XskipYsum
R0x3040[11], x_bin_en: 0
R0x3040[13], row_sum: 1
R0x0382: x_odd_inc = 3 (xskip2) or
7 (xskip4)
R0x0386: y_odd_inc = 3 (ysum2)
4. XbinYsum
R0x3040[11], x_bin_en: 1
R0x3040[13], row_sum: 1
R0x0382: x_odd_inc = 3 (xbin2)
R0x0386: y_odd_inc = 3 (ysum2)
5. XsumYsum
R0x3040[11], x_bin_en: 1
R0x3040[13], row_sum: 1
R0x3EE4[0], sreg_colamp_sum2: 1
(cannot write to this bit when streaming −
have to write to entire register)
R0x0382: x_odd_inc = 3 (xsum2)
R0x0386: y_odd_inc = 3 (ysum2)
Binning, Skipping, and Summing Mode
Summing, skipping, and binning can be combined in the
modes listed in Table 14. Unlike binning mode where the
values of adjacent same color pixels are averaged together,
summing adds the pixel values together resulting in better
sensor sensitivity. Summing is supposed to provide two
times the sensitivity compared to the binning only mode.
Table 14. AVAILABLE SKIP, BIN, AND SUM MODE
IN THE AR0835HS SENSOR
Subsampling
Method Horizontal Vertical
Skipping 2×, 4×2×, 4×, 8×
Binning 2×
Summing 2×2×
Figure 30. Pixel Binning and Summing
2 y 2 Binning or Summing X-binning Summing
Avg
Avg
Sh
Sh
SvSv
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Scaler
Scaling reduces the size of the output image while
maintaining the same field-of-view. The input and output of
the scaler is in Bayer format.
When compared to skipping, scaling is advantageous as it
avoids aliasing. The scaling factor, programmable in 1/16
steps, is used for horizontal and vertical scalers.
The AR0835HS sensor is capable of horizontal scaling
and full (horizontal and vertical) scaling.
The scale factor is determined by:
n, which is fixed at 16
m, which is adjustable with register R0x0404
Legal values for m are 16 through 96, giving the user
the ability to scale from 1:1 (m=16) to 1:6 (m=96)
Frame Rate Control
The formulas for calculating the frame rate of the
AR0835HS are shown below.
The line length is programmed directly in pixel clock
periods through register line_length_pck. For a specific
window size, the minimum line length can be found from
Equation 8:
minimum line_length_pck +ǒx_addr_end *x_addr_start )1
subsampling factor )min_line_blanking_pckǓ(eq. 8)
Note that line_length_pck also needs to meet the
minimum line length requirement set in register
min_line_length_pck. The row time can either be limited by
the time it takes to sample and reset the pixel array for each
row, or by the time it takes to sample and read out a row.
Values for min_line_blanking_pck are provided in
“Minimum Row Time”.
The frame length is programmed directly in number of
lines in the register frame_line_length. For a specific
window size, the minimum frame length can be found in
Equation 9:
minimum frame_length_lines +ǒy_addr_end *y_addr_start )1
subsampling factor )min_frame_blanking_linesǓ(eq. 9)
The frame rate can be calculated from these variables and
the pixel clock speed as shown in Equation 10:
frame rate +vt_pixel_clock_mhz 1 106
line_length_pck frame_length_lines (eq. 10)
If coarse_integration_time is set larger than
frame_length_lines the frame size will be expanded to
coarse_integration_time + 1.
Minimum Row Time
Enough time must be given to the output FIFO so it can
output all data at the set frequency within one row time.
There are therefore two checks that must all be met when
programming line_length_pck:
line_length_pck min_line_length_pck in Table 15
The row time must allow the FIFO to output all data
during each row. That is, line_length_pck
(x_output_size × 2 + 0x005E) × “vt_pix_clk period” /
“op_pix_clk period”
Minimum Frame Time
The minimum number of rows in the image is 1, so
min_frame_length_lines will always equal
(min_frame_blanking_lines + 1).
Table 15. MINIMUM FRAME TIME
AND BLANKING NUMBERS
min_frame_blanking_lines 0x008F
min_frame_length_lines 0x0A1F
Integration Time
The integration (exposure) time of the AR0835HS is
controlled by the coarse_integration_time register.
The limits for the coarse integration time are defined by:
coarse_integration_time_min vcoarse_integration_time (eq. 11)
The actual integration time is given by:
integration_time +coarse_integration_time line_length_pck
vt_pix_clk_freq_mhz 106(eq. 12)
It is required that:
coarse_integration_time v(frame_length_lines *coarse_integration_time_max_margin) (eq. 13)
If this limit is broken, the frame time will automatically be
extended to (coarse_integration_time + coarse_integartion_
time_max_margin) to accommodate the larger integration
time.
In binning mode, frame_length_lines should be set larger
than coarse_integration_time by at least 3 to avoid column
imbalance artifact.
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Flash Timing Control
The AR0835HS supports both xenon and LED flash
timing through the FLASH output signal. The timing of the
FLASH signal with the default settings is shown in
Figure 31 (Xenon) and Figure 32 (LED). The flash and
flash_count registers allow the timing of the flash to be
changed. The flash can be programmed to fire only once,
delayed by a few frames when asserted, and (for xenon
flash) the flash duration can be programmed.
Enabling the LED flash will cause one bad frame, where
several of the rows only have the flash on for part of their
integration time. This can be avoided either by first enabling
mask bad frames (R0x301A[9] = 1) before the enabling the
flash or by forcing a restart (R0x301A[1] = 1) immediately
after enabling the flash; the first bad frame will then be
masked out, as shown in Figure 32. Read-only bit flash[14]
is set during frames that are correctly integrated; the state of
this bit is shown in Figure 31 and Figure 32.
Figure 31. Xenon Flash Enabled
FRAME_VALID
Flash STROBE
State of Triggered Bit
(R0x3046−7[14])
Figure 32. LED Flash Enabled
NOTE: An option to invert the flash output signal through R0x3046[7] is also available.
FRAME_VALID
Flash STROBE
State of Triggered Bit
(R0x3046−7[14])
Flash Enabled
during this Frame Bad Frame
is Masked Good Frame Good Frame
Bad Frame
is Masked
Flash Disabled
during this Frame
Global Reset Release (GRR)
Global reset release mode allows the integration time of
the AR0835HS to be controlled by an external
electromechanical shutter. GRR mode is generally used in
conjunction with ERS mode. The ERS mode is used to
provide viewfinder information, the sensor is switched into
GRR mode to capture a single frame, and the sensor is then
returned to ERS mode to restore viewfinder operation.
Overview of Global Reset Release Sequence
The basic elements of the GRR sequence are:
1. By default, the sensor operates in ERS mode and
the SHUTTER output signal is LOW. The
electromechanical shutter must be open to allow
light to fall on the pixel array. Integration time is
controlled by the coarse_integration_time register.
2. A global reset sequence is triggered.
3. All of the rows of the pixel array are placed in
reset.
4. All of the rows of the pixel array are taken out of
reset simultaneously. All rows start to integrate
incident light. The electromechanical shutter may
be open or closed at this time.
5. If the electromechanical shutter has been closed, it
is opened.
6. After the desired integration time (controlled
internally or externally to the AR0835HS), the
electromechanical shutter is closed.
7. A single output frame is generated by the sensor
with the usual LV, FV, PIXCLK, and DOUT timing.
As soon as the output frame has completed
(FV negates), the electromechanical shutter may
be opened again.
8. The sensor automatically resumes operation in
ERS mode.
This sequence is shown in Figure 33. The following
sections expand to show how the timing of this sequence is
controlled.
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Figure 33. Overview of Global Reset Sequence
ERS Row Reset Integration Readout ERS
Entering and Leaving the Global Reset Sequence
A global reset sequence can be triggered by a register
write to R0x315E global_seq_trigger[0] (global trigger, to
transition this bit from a 0 to a 1) or by a rising edge on
a suitably-configured GPI input).
When a global reset sequence is triggered, the sensor waits
for the end of the current row. When LV negates for that row,
FV is negated 6 PIXCLK periods later, potentially
truncating the frame that was in progress.
The global reset sequence completes with a frame
readout. At the end of this readout phase, the sensor
automatically resumes operation in ERS mode. The first
frame integrated with ERS will be generated after a delay of
approximately ((13 + coarse_integration_time) × line_
length_pck). This sequence is shown in Figure 34.
While operating in ERS mode, double-buffered registers
(“Double-Buffered Registers”) are updated at the start of
each frame in the usual way. During the global reset
sequence, double-buffered registers are updated just before
the start of the readout phase.
Figure 34. Entering and Leaving a Global Reset Sequence
ERS Row Reset Integration Readout ERS
Trigger
Wait for End of Current Row Automatic at End of Frame Readout
Programmable Settings
The registers global_rst_end and global_read_start allow
the duration of the row reset phase and the integration phase
to be controlled, as shown in Figure 35. The duration of the
readout phase is determined by the active image size.
The recommended setting for global_rst_end is 0x3160
(for example, 512 ms total reset time) with default
vt_pix_clk. This allows sufficient time for all rows of the
pixel array to be set to the correct reset voltage level.
The row reset phase takes a finite amount of time due to the
capacitance of the pixel array and the capability of the
internal voltage booster circuit that is used to generate the
reset voltage level.
As soon as the global_rst_end count has expired, all rows
in the pixel array are taken out of reset simultaneously and
the pixel array begins to integrate incident light.
Figure 35. Controlling the Reset and Integration Phases of the Global Reset Sequence
ERS Row Reset Integration Readout ERS
Trigger
Wait for End of Current Row Automatic at End of Frame Readout
global_rst_end
global_read_start
Control of the Electromechanical Shutter
Figure 36 shows two dif ferent ways i n which a shutter can
be controlled during the global reset sequence. In both cases,
the maximum integration time is set by the difference
between global_read_start and global_rst_end. In shutter
example 1, the shutter is open during the initial ERS
sequence and during the row reset phase. The shutter closes
during the integration phase. The pixel array is integrating
incident light from the start of the integration phase to the
point at which the shutter closes. Finally, the shutter opens
again after the end of the readout phase. In shutter
example 2, the shutter is open during the initial ERS
sequence and closes sometime during the row reset phase.
The shutter both opens and closes during the integration
phase. The pixel array is integrating incident light for the
part of the integration phase during which the shutter is
open. As for the previous example, the shutter opens again
after the end of the readout phase.
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Figure 36. Control of the Electromechanical Shutter
ERS Row Reset Integration Readout ERS
Trigger
Wait for End of Current Row Automatic at End of Frame Readout
global_rst_end
global_read_start
Maximum
Integration Time
Actual Integration Time
Closed Shutter ClosedShutter Open Shutter Open
Shutter Closed Shutter Open
Actual Integration Time
SHUTTER Example 1
Shutter Open (Physical)
SHUTTER Example 2
Shutter Open (Physical)
It is essential that the shutter remains closed during the
entire row readout phase (that is, until FV has negated for the
frame readout); otherwise, some rows of data will be
corrupted (over-integrated).
It is essential that the shutter closes before the end of the
integration phase. If the row readout phase is allowed to start
before the shutter closes, each row in turn will be integrated
for one row-time longer than the previous row.
After FV negates to signal the completion of the readout
phase, there is a time delay of approximately (10 ×
line_length_pck) before the sensor starts to integrate
light-sensitive rows for the next ERS frame. It is essential
that the shutter be opened at some point in this time window;
otherwise, the first ERS frame will not be uniformly
integrated.
The AR0835HS provides a SHUTTER output signal to
control (or help the host system control) the
electromechanical shutter. The timing of the SHUTTER
output is shown in Figure 37. SHUTTER is negated by
default. The point at which it asserts is controlled by the
programming of global_shutter_start. At the end of the
global reset readout phase, SHUTTER negates
approximately (2 × line_length_pck) after the negation of
FV.
This programming restriction must be met for correct
operation:
global_read_start > global_shutter_start
Figure 37. Controlling the SHUTTER Output
ERS Row Reset Integration Readout ERS
Trigger
Wait for End of Current Row Automatic at End of Frame Readout
global_rst_end
global_read_start
SHUTTER (Signal)
global_shutter_start
~2 × line_length_pck
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Using FLASH with Global Reset
If R0x315E global_seq_trigger[2] = 1 (global flash
enabled) when a global reset sequence is triggered, the
FLASH output signal will be pulsed during the integration
phase of the global reset sequence. The FLASH output will
assert a fixed number of cycles after the start of the
integration phase and will remain asserted for a time that is
controlled by the value of the flash_count register. When
flash_count is programmed for value N, (where N is
0–0x3FE) the resulting flash duration is given by
N×512 ×(1/vt_pix_clk_freq_mhz), as shown in
Figure 38.
Figure 38. Using FLASH with Global Reset
ERS Row Reset Integration Readout ERS
Trigger
Wait for End of Current Row Automatic at End of Frame Readout
global_rst_end
global_read_start
SHUTTER
global_shutter_start
~2 × line_length_pck
FLASH
(Fixed) flash_count
When the flash_count = 0x3FF, the flash signal will be
maximized and goes LOW when readout starts, as shown in
Figure 39. This would be preferred if the latency in closing
the shutter is longer than the latency for turning off the flash.
This guarantees that the flash stays on while the shutter is
open.
Figure 39. Extending FLASH Duration in Global Reset (Reference Readout Start)
ERS Row Reset Integration Readout ERS
Trigger
Wait for End of Current Row Automatic at End of Frame Readout
global_rst_end
global_read_start
SHUTTER
global_shutter_start
~2 × line_length_pck
FLASH
(Fixed)
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External Control of Integration Time
If global_seq_trigger[1] = 1 (global bulb enabled) when
a global reset sequence is triggered, the end of the
integration phase is controlled by the level of trigger
(global_seq_trigger[0] or the associated GPI input). This
allows the integration time to be controlled directly by an
input to the sensor.
This operation corresponds to the shutter “B” setting on a
traditional camera, where “B” originally stood for “Bulb”
(the shutter setting used for synchronization with
a magnesium foil flash bulb) and was later considered to
stand for “Brief” (an exposure that was longer than the
shutter could automatically accommodate).
When the trigger is de-asserted to end integration, the
integration phase is extended by a further time given by
global_read_start – global_shutter_start. Usually this
means that global_read_start should be set to
global_shutter_start + 1.
The operation of this mode is shown in Figure 40.
The figure shows the global reset sequence being triggered
by the GPI2 input, but it could be triggered by any of the GPI
inputs or by the setting and subsequence clearing of the
global_seq_trigger[0] under software control.
The integration time of the GRR sequence is defined as:
Integration Time +global_scale [global_read_start *global_shutter_start *global_rst_end]
vt_pix_clk_freq_mhz (eq. 14)
where:
global_read_start +ǒ216 global_read_start2[7:0] )global_read_start1[15:0]Ǔ(eq. 15)
global_shutter_start +ǒ216 global_shutter_start2[7:0] )global_shutter_start1[15:0]Ǔ(eq. 16)
The integration equation allows for 24-bit precision when
calculating both the shutter and readout of the image. The
global_rst_end has only 16-bit as the array reset function
and requires a short amount of time.
The integration time can also be scaled using
global_scale. The variable can be set to 0–512, 1–2048,
2–128, and 3–32.
These programming restrictions must be met for correct
operation of bulb exposures:
global_read_start > global_shutter_start
global_shutter_start > global_rst_end
global_shutter_start must be smaller than the exposure
time (that is, this counter must expire before the trigger
is de-asserted)
Figure 40. Global Reset Bulb
ERS Row Reset Integration Readout ERS
Trigger
Wait for End of Current Row Automatic at End of Frame Readout
global_rst_end
GPI2
global_read_start − global_shutter_start
Retriggering the Global Reset Sequence
The trigger for the global reset sequence is edge-sensitive;
the global reset sequence cannot be retriggered until the
global trigger bit (in the R0x315E global_seq_trigger
register) has been returned to “0”, and the GPI (if any)
associated with the trigger function has been negated.
The earliest time that the global reset sequence can be
retriggered is the point at which the SHUTTER output
negates; this occurs approximately (2 × line_length_pck)
after the negation of FV for the global reset readout phase.
Using Global Reset with SMIA Data Path
When a global reset sequence is triggered, it usually
results in the frame in progress being truncated (at the end
of the current output line). The SMIA data path limiter
function (see Figure 41) attempts to extend (pad) all frames
to the programmed value of y_output_size. If this padding
is still in progress when the global reset readout phase starts,
the SMIA data path will not detect the start of the frame
correctly. Therefore, to use global reset with the serial data
path, this timing scenario must be avoided. One possible
way of doing this would be to synchronize (under software
control) the assertion of trigger to an end-of-frame marker
on the serial data stream.
At the end of the readout phase of the global reset
sequence, the sensor automatically resumes operation in
ERS mode.
The frame that is read out of the sensor during the global
reset re adout phase has exactly the same format as any other
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frame out of the serial pixel data interface, including the
addition of two lines of embedded data. The value of the
coarse_integration_time register within the embedded data
matches the programmed values of those registers and does
not reflect the integration time used during the global reset
sequence.
Global Reset and Soft Standby
If the R0x301A[2] mode_select[stream] bit is cleared
while a global reset sequence is in progress, the AR0835HS
will remain in streaming state until the global reset sequence
(including frame readout) has completed, as shown in
Figure 41.
Figure 41. Entering Soft Standby During a Global Reset Sequence
ERS Row Reset Integration Readout ERS
Software
Standby
StreamingSystem Style
R0x0100
mode_select[streaming]
Slave Mode
Slave mode is to ensure having an ERS-GRR-ERS
transition without a broken ERS frame before GRR. It
requests to trigger/end the GRR sequence through the pin
which is similar to the GRR Bulb mode. The major
difference t o our existing sensor is to start the GRR sequence
after the end of the current frame instead of to start
immediately in the next following row.
Figure 42. Slave Mode Transition
Sensor Readout Sensor Readout Sensor Readout
GRR TRIG ON
Wait for VD,
then Global Reset Sequence Starts
Sensor Starts to Read Out
after VD is Inserted
VD
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GAIN
AR0835HS supports both analog and digital gain.
Analog Gain
Analog gain is provided by colamp and ADC reference
scaling (there is no ASC gain due to column parallel nature
of architecture). Only global (not per-color) coarse gain can
be set by analog gain. Global gain register (R0x305E) sets
the analog gain. Bits [1:0] set the colamp gain while
bits [4:2] ar e r e s e r ved for ADC gain. While the 2-bit colamp
gain provides up to 4× analog gain, only LSB (bit [2]) of
ADC gain bits is utilized to support 2× ADC gain. Table 16
is the recommended gain setting:
Table 16. RECOMMENDED ANALOG GAIN SETTING
Colamp Gain Codes
(R0x305E[1:0]) ADC Gain Codes
(R0x305E[4:2]) Colamp Gain ADC Gain Total Gain
00000111
01000212
10000313
11000414
10001326
11001428
Digital Gain
Digital gain provides both per-color and fine (sub 1×)
gain. The analog and digital gains are multiplicative to give
the total gain. Digital gain is set by setting bits
R0x305E[15:5] to set global gain or by individually setting
digital color gain R0x3056−C[15:5] where these 11 bits are
designed i n 4p7 format i.e. 4 MSB provide gain up to 15× in
step of 1 × while 7 LSB provide sub-1 × gain with a step size
of 1/128. This sub-1× gain provides the fine gain control for
the sensor.
Total Gain
Max. total gain required by design spec is 8× (analog) and
16× (digital) with min. step size of 1/8. The total gain
equation can be formulated as:
Total Gain +(1 )dec(R0x305D[1:0])) (1 )R0x305E[2]) dec(R0x305X[15:5])
128 (eq. 17)
where X is 6, 8, A, C, for Gr, B, R and Gb, respectively.
NOTE: ON Semiconductor recommends using the
registers mentioned above for gain settings.
Avoid R0x3028 to R0x3038 unless their
mapping to above registers is well understood
and taken into account.
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TEMPERATURE SENSOR
A standalone PTAT based temperature sensor has been
implemented. The block is controlled independent of sensor timing and all communication happens through the
two-wire serial interface.
INTERNAL VCM DRIVER
The AR0835HS utilizes an internal Voice Coil Motor
(VCM) driver. The VCM functions are register-controlled
through the serial interface.
There are two output ports, VCM_ISINK and
VCM_GND, which would connect directly to the AF
actuator.
Take precautions in the design of the power supply routing
to provide a low impedance path for the ground connection.
Appropriate filtering would also be required on the actuator
supply. Typical values would be a 0.1 mF and 10 mF in
parallel.
Figure 43. VCM Driver Typical Diagram
AR0835HS VCM
VVCM
DGND
10 mF0.1 mF
VCM_ISINK
VCM_GND
Table 17. VCM DRIVER TYPICAL
Characteristic Parameter Minimum Typical Maximum Unit
VCM_OUT Voltage at VCM Current Sink 2.5 2.8 3.3 V
WVCM Voltage at VCM Actuator 2.5 2.8 3.3 V
INL Relative Accuracy ±1.5 ±4LSB
RES Resolution 8 bits
DNL Differential Non-linearity –1 +1 LSB
IVCM Output Current 90 100 110 mA
Slew Rate (User Programmable) 13 mA/ms
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SPECTRAL CHARACTERISTICS
Figure 44. Quantum Efficiency
Wavelength (nm)
400
Quantum Efficiency (%)
500 600 700 800
0
10
20
30
40
50
60
70
Red
Green R
Green B
Blue
CRA vs. Image Height Plot
Image Height CRA
(%) (mm) (deg)
Chief Ray Angle (Deg)
Image Height (%)
AR0835HS CRA Characteristic
0 102030405060708090100110
0
2
4
6
8
10
12
14
16
18
20
Figure 45. Chief Ray Angle vs. Image Height
0 0 0
5 0.143 0.77
10 0.286 1.55
15 0.428 2.33
20 0.571 3.11
25 0.714 3.87
30 0.857 4.62
35 1.000 5.36
40 1.142 6.07
45 1.285 6.77
50 1.428 7.43
55 1.571 8.06
60 1.714 8.66
65 1.856 9.22
70 1.999 9.73
75 2.142 10.19
80 2.285 10.59
85 2.428 10.93
90 2.570 11.18
95 2.713 11.34
100 2.856 11.40
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ELECTRICAL CHARACTERISTICS
Two-Wire Serial Register Interface
The electrical characteristics of the two-wire serial
register interface (SCLK, SDATA) are shown in Figure 46 and Table 18. Table 19 shows the timing specification for the
two-wire serial interface.
ÈÈÈ
ÈÈÈ
ÈÈÈ
ÈÈÈ
ÈÈÈ
ËË
ËË
ËË
ËË
ËË
ÍÍÍ
ÍÍÍ
ÍÍÍ
ÍÍÍ
ÍÍÍ
ÍÍÍ
ÍÍÍ
ÍÍÍ
ÍÍÍ
ÍÍÍ
Figure 46. Two-Wire Serial Bus Timing Parameters
NOTE: Read sequence: For an 8-bit READ, read waveforms start after WRITE command and register address are issued.
70%
30% 70%
30% 30% 30% 70% 70%
70% 30% 30%
S
1st Clock 9th Clock
SDATA
SCLK
tSRTH
t
R
t
F
tSDS tSDH
t
ACV
t
SDV
SDATA
SCLK
9th Clock
70%
70% 70% 70% 30% 70%
70% 70%
30%
tHIGH
tSRTS
Sr tLOW
30% tSTPS SP
tBUF
Table 18. TWO-WIRE SERIAL REGISTER INTERFACE ELECTRICAL CHARACTERISTICS
(fEXTCLK = 25 MHz; VAA = 2.8 V; VAA_PIX = 2.8 V; VDD_IO = 1.8 V; VDD_1V2 = 1.2 V; VDD_PLL = 1.2 V; VDD_1V8 = 1.8 V;
Output load = 68.5 pF; TJ = 55°C)
Symbol Parameter Condition Min Typ Max Unit
VIL Input LOW Voltage −0.5 0.3 × VDD_IO V
VIH Input HIGH Voltage 0.7 × VDD_IO VDD_IO + 0.5 V
IIN Input Leakage Current No Pull Up Resistor;
VIN = VDD_IO or DGND 10 14 mA
VOL Output LOW Voltage At Specified 2 mA 0.11 0.3 V
IOL Output LOW Current At Specified VOL 0.1 V 6 mA
CIN Input Pad Capacitance 6 pF
CLOAD Load Capacitance N/A pF
Table 19. TWO-WIRE SERIAL INTERFACE TIMING SPECIFICATIONS
(VDD_IO = 1.7−1.9 V; VAA = 2.4 −3.1 V; Environment temperature = −30°C to 50°C)
Symbol Definition Min Max Unit
fSCLK SCLK Frequency 100 400 kHz
tHIGH SCLK High Period 0.6 ms
tLOW SCLK Low Period 1.3 ms
tSRTS START Setup Time 0.6 ms
tSRTH START Hold Time 0.6 ms
tSDS Data Setup Time 100 ns
tSDH Data Hold Time 0 ms
tSDV Data Valid Time 0.9 ms
tACV Data Valid Acknowledge Time 0.9 ms
tSTPS STOP Setup Time 0.6 ms
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Table 19. TWO-WIRE SERIAL INTERFACE TIMING SPECIFICATIONS (continued)
(VDD_IO = 1.7−1.9 V; VAA = 2.4 −3.1 V; Environment temperature = −30°C to 50°C)
Symbol UnitMaxMinDefinition
tBUF Bus Free Time between STOP and START 1.3 ms
trSCLK and SDATA Rise T ime 300 ns
tfSCLK and SDATA Fall T ime 300 ns
EXTCLK
The electrical characteristics of the EXTCLK input are
shown in Table 20. The EXTCLK input supports an
AC-coupled sine-wave input clock or a DC-coupled
square-wave input clock.
If EXTCLK is AC−coupled to the AR0835HS and the
clock is stopped, the EXTCLK input to the AR0835HS must
be driven to ground or to VDD_IO. Failure to do this will
result in excessive current consumption within the
EXTCLK input receiver.
Table 20. ELECTRICAL CHARACTERISTICS (EXTCLK)
(fEXTCLK = 24 MHz; VAA = 2.8 V; VAA_PIX = 2.8 V; VDD_IO = 1.8 V; VDD_1V2 = 1.2 V, Output load = 68.5 pF; TJ = 55°C)
Symbol Parameter Condition Min Typ Max Unit
fEXTCLK1 Input Clock Frequency PLL Enabled 6 24 27 MHz
tRInput Clock Rise Slew Rate CLOAD <20pF 2.883 ns
tFInput Clock Fall Slew Rate CLOAD <20pF 2.687 ns
VIN_AC Input Clock Minimum Voltage
Swing (AC Coupled) 0.5 V (p-p)
VIN_DC Input Clock Maximum Voltage
Swing (DC Coupled) VDD_IO + 0.5 V
fCLKMAX(AC) Input Clock Signaling Frequency
(Low Amplitude) VIN = VIN_AC (MIN) 25 MHz
fCLKMAX(DC) Input Clock Signaling Frequency
(Full Amplitude) VIN = VDD_IO 48 MHz
Clock Duty Cycle 45 50 55 %
tJITTER Input Clock Jitter Cycle-to-Cycle 545 600 ps
tLOCK PLL VCO Lock Time 0.2 2 ms
CIN Input Pad Capacitance 6 pF
IIH Input HIGH Leakage Current 0 10 mA
VIH Input HIGH Voltage 0.7 × VDD_IO VDD_IO + 0.5 V
VIL Input LOW Voltage −0.5 0.3 × VDD_IO V
Product parametric performance is indicated in the Electrical Characteristics for the listed test conditions, unless otherwise noted. Product
performance may not be indicated by the Electrical Characteristics if operated under different conditions.
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Figure 47. Fall Slew Rates (Cap Load = 25 pF)
Slew Setting
Fall Slew Rates (V/ns)
01234567
0
0.5
1.0
1.5
2.0
2.5
3.0 VDD_IO = 1.7 V
VDD_IO = 1.8 V
VDD_IO = 1.9 V
VDD_IO = 2.0 V
VDD_IO = 2.1 V
VDD_IO = 2.2 V
VDD_IO = 2.3 V
VDD_IO = 2.4 V
VDD_IO = 2.5 V
VDD_IO = 2.6 V
VDD_IO = 2.7 V
VDD_IO = 2.8 V
VDD_IO = 2.9 V
VDD_IO = 3.0 V
VDD_IO = 3.1 V
Figure 48. Rise Slew Rates (Cap Load = 25 pF)
Slew Setting
Rise Slew Rates (V/ns)
01234567
0
0.5
1.0
1.5
2.0
2.5
3.0 VDD_IO = 1.7 V
VDD_IO = 1.8 V
VDD_IO = 1.9 V
VDD_IO = 2.0 V
VDD_IO = 2.1 V
VDD_IO = 2.2 V
VDD_IO = 2.3 V
VDD_IO = 2.4 V
VDD_IO = 2.5 V
VDD_IO = 2.6 V
VDD_IO = 2.7 V
VDD_IO = 2.8 V
VDD_IO = 2.9 V
VDD_IO = 3.0 V
VDD_IO = 3.1 V
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High Speed Serial Pixel Data Interface
The High Speed Serial Pixel (HiSPi) interface uses four
data and one clock low voltage differential signaling
(LVDS) outputs.
SLVSC_P
SLVSC_N
SLVS0_P
SLVS0_N
SLVS1_P
SLVS1_N
SLVS2_P
SLVS2_N
SLVS3_P
SLVS3_N
The HiSPi interface supports three protocols, Streaming
S, Streaming SP, and Packetized SP. The streaming
protocols conform to a standard video application where
each line of active or intra-frame blanking provided by the
sensor is transmitted at the same length. The Packetized SP
protocol will transmit only the active data ignoring
line-to-line and frame-to-frame blanking data.
These protocols are further described in the High-Speed
Serial Pixel (HiSPi) Interface Protocol Specification
V1.50.00.
The HiSPi interface building block is a unidirectional
differential serial interface with four data and one double
data rate (DDR) clock lanes. One clock for every four serial
data lanes is provided for phase alignment across multiple
lanes. A collection of one clock lane plus four data lanes is
called a PHY .Figure 49 shows the configuration between
the HiSPi transmitter and the receiver.
Figure 49. HiSPi Transmitter and Receiver Interface Block Diagram (HiSPi Mode Only)
Tx
PHY0
Dp0 Dp0
Dn0 Dn0
Dp1 Dp1
Dn1 Dn1
Dp2 Dp2
Dn2 Dn2
Dp3 Dp3
Dn3 Dn3
Cp0 Cp0
Cn0 Cn0
Rx
PHY0
A Camera Containing
the HiSPi Transmitter A Host (DSP) Containing
the HiSPi Receiver
HiSPi Physical Layer
The AR0835HS PHY will serialize an 8- or 10-bit data
word and transmit each bit of data centered on a rising edge
of the clock, the second on the falling edge of clock.
Figure 50 shows bit transmission. In this example, the word
is transmitted in order of MSB to LSB. The receiver latches
data at the rising and falling edge of the clock.
Figure 50. Timing Diagram
LSB
TxPost
TxPre
1 UI
cp
cn
dp
dn
MSB
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DLL Timing Adjustment
The specification includes a DLL to compensate for
differences in group delay for each data lane. The DLL is
connected t o the clock lane and each data lane, which acts as
a control master for the output delay buffers. Once the DLL
has gained phase lock, each lane can be delayed in 1/8 unit
interval (UI) steps. This additional delay allows the user to
increase the setup or hold time at the receiver circuits and
can be used to compensate for skew introduced in PCB
design.
If the DLL timing adjustment is not required, the data and
clock lane delay settings should be set to a default code of
0x000 to reduce jitter, skew, and power dissipation.
Figure 51. Block Diagram of DLL Timing Adjustment
data_lane0 data_lane1 clock_lane0 data_lane2 data_lane3
Delay
DATA0_DEL[2:0]
Delay Delay Delay Delay
DATA1_DEL[2:0]
CLOCK_DEL[2:0]
DATA2_DEL[2:0]
DATA3_DEL[2:0]
Figure 52. Delaying the clock_lane with Respect to data_lane
1 UI
cp (CLOCK_DEL = 111)
cp (CLOCK_DEL = 110)
cp (CLOCK_DEL = 101)
cp (CLOCK_DEL = 100)
cp (CLOCK_DEL = 011)
cp (CLOCK_DEL = 010)
cp (CLOCK_DEL = 001)
cp (CLOCK_DEL = 000)
dataN (DATAN_DEL = 000)
Increasing CLOCK_DEL[2:0] Increases Clock Delay
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Figure 53. Delaying data_lane with Respect to the clock_lane
1 UI
dataN (DATAN_DEL = 111)
dataN (DATAN_DEL = 110)
dataN (DATAN_DEL = 101)
dataN (DATAN_DEL = 100)
dataN (DATAN_DEL = 011)
dataN (DATAN_DEL = 010)
dataN (DATAN_DEL = 001)
dataN (DATAN_DEL = 000)
cp (CLOCK_DEL = 000)
Increasing DATAN_DEL[2:0] Increases Data Delay
tDLLSTEP
HiSPi Streaming Mode Protocol Layer
The HiSPi protocol is described HiSPi Protocol V1.50.00.
Serial Pixel Data Interface (HiSPi Mode)
The electrical characteristics of the serial pixel data
interface (CLK_P, CLK_N, DATA[4:1]_P, and
DATA[4:1]_N) are shown in Table 21 and Table 22.
Table 21. SLVS ELECTRICAL TIMING SPECIFICATION
Symbol Parameter Min Max Unit
1/UI Data Rate (Note 1) 280 1000 Mbps
tPW Bitrate Period (Note 1) 1.00 3.57 ns
tPRE Max Setup Time from Transmitter (Notes 1, 2) 0.3 UI
tPOST Max Hold Time from Transmitter (Notes 1, 2) 0.3 UI
tEYE Eye Width (Notes 1, 2) 0.6 UI
tTOTALJIT Data Total Jitter (pk−pk) @1e−9 (Notes 1, 2) 0.2 UI
tCKJIT Clock Period Jitter (RMS) (Note 2) 50 ps
tCYCJIT Clock Cycle-to-Cycle Jitter (RMS) (Note 2) 100 ps
tRRise Time (20−80%) (Note 3) 150 ps 0.25 UI
tFFall Time (20−80%) (Note 3) 150 ps 0.25 UI
DCYC Clock Duty Cycle (Note 2) 45 55 %
tCHSKEW Total Clock to Data Skew(Notes 1, 4) −0.2 0.2 UI
tDIFFSKEW Mean Differential Skew (Note 5) −100 100 ps
1. One UI is defined as the normalized mean time between one edge and the following edge of the clock.
2. Taken from the 0 V crossing point with the DLL off.
3. Also defined with a maximum loading capacitance of 10 pF on any pin. The loading capacitance may also need to be less for higher bitrates
so the rise and fall times do not exceed the maximum 0.3 UI.
4. The total skew between the Clock lane and any Data Lane in the same PHY between any edges; it includes clock duty cycle, mean skew
and total peak jitter at BER of 1E−9.
5. Differential skew is defined as the skew between complementary outputs. It is measured as the absolute time between the two
complementary edges at mean VCM point. Note that differential skew also is related to the DVCM_AC spec which also must not be exceeded.
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Table 22. SLVS ELECTRICAL DC SPECIFICATION (TJ = 25°C)
Symbol Parameter Min Typ Max Unit
VCM SLVS DC Mean Common Mode Voltage 0.45 ×VDD_TX 0.5 ×VDD_TX 0.55 ×VDD_TX V
|VOD|SLVS DC Mean Differential Output Voltage 0.36 ×VDD_T 0.5 ×VDD_TX 0.64 ×VDD_TX V
DVCM Change in VCM between Logic 1 and 0 25 mV
D|VOD|Change in |VOD| between Logic 1 and 0 25 mV
NM VOD Noise Margin ±30 %
|DVCM|Difference in VCM between any Two Channels 30 mV
|DVOD|Difference in VOD between any Two Channels 50 mV
VCM_AC Common-mode AC Voltage (pk) without VCM Cap
Termination 50 mV
VCM_AC Common-mode AC Voltage (pk) with VCM Cap
Termination 30 mV
VOD_AC Maximum Overshoot Peak |VOD| 1.3 ×|VOD| V
Vdiff_pkpk Maximum Overshoot Vdiff pk-pk 2.6 ×VOD V
ROSingle-ended Output Impedance 35 50 70 Ù
DROOutput Impedance Mismatch 20 %
Control Interface
The electrical characteristics of the control interface
(RESET_BAR, TEST, GPIO0, GPIO1, GPI2, and GPI3) are
shown in Table 23.
Table 23. DC ELECTRICAL CHARACTERISTICS (CONTROL INTERFACE)
(fEXTCLK = 24 MHz; VAA = 2.8 V; VAA_PIX = 2.8 V; VDD_IO = 1.8 V; DVDD_1V2 = 1.2 V; Output load = 68.5 pF; TJ = 55°C)
Symbol Parameter Condition Min Typ Max Unit
VIH Input HIGH Voltage 0.7 ×VDD_IO VDD_IO + 0.5 V
VIL Input LOW Voltage –0.5 VDD_IO ×0.3 V
IIN Input Leakage Current No pull-up resistor;
VIN = VDD_IO or DGND 10 mA
CIN Input Pad Capacitance 6 pF
Operating Voltages
VAA and VAA_PIX must be at the same potential for
correct operation of the AR0835HS.
Table 24. DC ELECTRICAL DEFINITIONS AND CHARACTERISTICS
(fEXTCLK = 24 MHz; VAA = 2.8 V; VAA_PIX = 2.8 V; VDD_IO = 1.8 V; DVDD_1V2 = 1.2 V; Output load = 68.5 pF; TJ = 70°C; Mode = Full
Resolution (3264 ×2488); Frame rate = 30 fps)
Symbol Parameter Condition Min Typ Max Unit
VAA Analog Voltage 2.5 2.8 3.1 V
VAA_PIX Pixel Supply Voltage 2.5 2.8 3.1 V
VDD_1V2 Digital Voltage 1.14 1.2 1.3 V
VDD_1V8 PHY Digital Voltage 1.7 1.8 1.9 V
VDD_IO I/O Digital Voltage 1.7 1.8 1.9 V
2.5 2.8 3.1 V
VDDSLVS_PHY HiSPi Analog Supply Internal Regulator Disabled 0.35 0.4 0.45 V
Internal Regulator Enabled 1.14 1.2 1.3
VDD_PHY HiSPi Digital Supply 1.14 1.2 1.3 V
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Table 24. DC ELECTRICAL DEFINITIONS AND CHARACTERISTICS (continued)
(fEXTCLK = 24 MHz; VAA = 2.8 V; VAA_PIX = 2.8 V; VDD_IO = 1.8 V; DVDD_1V2 = 1.2 V; Output load = 68.5 pF; TJ = 70°C; Mode = Full
Resolution (3264 ×2488); Frame rate = 30 fps)
Symbol UnitMaxTypMinConditionParameter
H/W Standby Current
Consumption 30 mA
Output Driving Strength 10 mA
Slew Rate 0.7 mV/sec
Programming Voltage
for OTPM (VPP)6 6.5 7 V
Typical Operating Current Consumption
Table 25. TYPICAL OPERATING CURRENT CONSUMPTION
(Nominal Voltages: fEXTCLK = 24 MHz; VAA = 2.8 V; VAA_PIX = 2.8 V; VDD_1V8 = 1.8 V; VDD_IO = 1.8 V; VDD_1V2 = 1.2 V TJ = 25°C)
Symbol Parameter Min Typ Max Unit
I(VAA)Analog Supply Current 8 Mp, 46 fps 85 110 mA
6 Mp, 60 fps 85 110 mA
1080p, 60 fps 85 110 mA
720p, 120 fps 85 110 mA
I(VAA_PIX) Pixel Supply Current 8 Mp, 46 fps 16 20 mA
6 Mp, 60 fps 16 20 mA
1080p, 60 fps 16 20 mA
720p, 120 fps 16 20 mA
I(VDD_1V8) OTPM Read Supply
Current 8 Mp, 46 fps 0 1 mA
6 Mp, 60 fps 0 1 mA
1080p, 60 fps 0 1 mA
720p, 120 fps 0 1 mA
I(VDD_IO) I/O Supply Current 8 Mp, 46 fps 1 2 mA
6 Mp, 60 fps 1 2 mA
1080p, 60 fps 1 2 mA
720p, 120 fps 1 2 mA
I(VDD_1V2: VDDSW,
VDD_ANA, VDD_PLL) Core Supply Current 8 Mp, 46 fps 150 175 mA
6 Mp, 60 fps 150 175 mA
1080p, 60 fps 130 165 mA
720p, 120 fps 130 140 mA
I(VDD_PHY, VDDSLVS_PHY) PHY Supply Current 8 Mp, 46 fps 12 14 mA
6 Mp, 60 fps 12 14 mA
1080p, 60 fps 10 12 mA
720p, 120 fps 8 10 mA
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Absolute Minimum and Maximum Ratings
CAUTION: Stresses greater than those listed in Table 26 may cause permanent damage to the device. Exposure to absolute
maximum rating conditions for extended periods may af fect reliability. This is a stress rating only, and functional
operation of the device at these or any other conditions above those indicated in the operational sections of this
specification is not implied.
Table 26. ABSOLUTE MAXIMUM VOLTAGES
Symbol Parameter Min Max Unit
1.2V All1.2 V Supply −0.3 1.5 V
1.8V All1.8 V Supply −0.3 2.1 V
2.8V All 2.8 V Supply −0.3 3.5 V
HiSPi SPECIFICATION REFERENCE
The sensor design and this documentation is based on the
following HiSPi Specifications:
HiSPi Protocol Specification V1.50.00
HiSPi Physical Layer Specification V3.0
MIPI SPECIFICATION REFERENCE
The sensor design and this documentation is based on the
following MIPI Specifications:
MIPI Alliance Standard for CSI−2 version 1.0
MIPI Alliance Standard for D−PHY version 1.0
AR0835HS
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PACKAGE DIMENSIONS
CLCC48 10x10
CASE 848AJ
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