© Semiconductor Components Industries, LLC, 2016
March, 2020 − Rev. 6
1Publication Order Number:
AR0238/D
AR0238
AR0238: 1/2.7-Inch
2.1 Mp/Full HD Digital
Image Sensor
General Description
ON Semiconductor’s AR0238 is a 1/2.7-inch CMOS digital image
sensor with an active−pixel array of 1928Hx1088V. It captures images
in either linear or high dynamic range modes, with a rolling−shutter
readout. It includes sophisticated camera functions such as in−pixel
binning, windowing and both video and single frame modes. It is
designed for both low light and high dynamic range scene
performance. It is programmable through a simple two−wire serial
interface. The AR0238 produces extraordinarily clear, sharp digital
pictures, and its ability to capture both continuous video and single
frames makes it the perfect choice for a wide range of applications,
including surveillance and HD video.
Table 1. KEY PARAMETERS
Parameter Typical Value
Optical format 1/2.7−inch (6.6 mm)
Active pixels 1928(H) x 1088(V) (16:9 mode)
Pixel size 3.0 mm x 3.0 mm
Color filter array RGB Bayer, RGB−IR
Shutter type Electronic rolling shutter and GRR
Input clock range 6 – 48 MHz
Output clock maxi-
mum
148.5 Mp/s (4−lane HiSPi)
74.25 Mp/s (Parallel)
Output Serial HiSPi 10−, or 12−bit
Parallel 10−, or 12−bit
Frame
rate
1080p 60 fps Linear HiSPi
30 fps Linear Parallel
30 fps Line Interleaved HiSPi
15 fps Line Interleaved Parallel
Responsivity 4.0 V/lux−sec
SNRMAX 41 dB
Max Dynamic range Up to 96 dB
Supply
voltage
I/O 1.8 or 2.8 V
Digital 1.8 V
Analog 2.8 V
HiSPi 0.3 V − 0.6 V (SLVS), 1.7 V − 1.9 V (HiVcm)
Power consumption
(typical)
< 300mW Line interleaved 1080p30
<190mW 1080p30 Linear Mode
Operating temperature −30°C to + 85°C Ambient
Package options 11.43x11.43 mm 48−pin mPLCC
Recon Die
www.onsemi.com
Features
•Superior Low−light Performance
•Latest 3.0 mm Pixel with
ON Semiconductor DR−Pix™ Technology
with Dual Conversion Gain
•Full HD Support at up to 1080P 60 fps for
Superior Video Performance
•Linear or High Dynamic Range Capture
•Supports Line Interleaved T1/T2 readout to
Enable HDR Processing in ISP Chip
•Support for External Mechanical Shutter
•On−chip Phase−locked Loop (PLL) Oscil-
lator
•Integrated Position−based Color and Lens
Shading Correction
•Slave Mode for Precise Frame−rate
Control
•Stereo/3D Camera Support
•Statistics Engine
•Data Interfaces: Four−lane Serial High−
speed Pixel Interface (HiSPi) Differential
Signaling (SLVS and HiVCM), or Parallel
•Auto Black Level Calibration
•High−speed Configurable Context
Switching
•Temperature Sensor
Applications
•Video Recording and Streaming
•1080p60 (monitoring) Video Applications
•High Dynamic Range Imaging
AR0238
www.onsemi.com
2
PLCC48 11.43x11.43 (HiSPi)
CASE 776AQ
PLCC48 11.43x11.43 (Parallel)
CASE 776AS
Table 2. ORDERING INFORMATION
Part Number Product Description Orderable Product Attribute Description
AR0238CSSC12SHRA0−DR1 RGB Color, 12 Degree CRA, mPLCC, HiSPi Dry Pack, No Protective film, Low MOQ
AR0238CSSC12SHRA0−DP1 RGB Color, 12 Degree CRA, mPLCC, HiSPi Dry Pack, with Protective film, Low MOQ
AR0238CSSC12SHRA0−DR RGB Color, 12 Degree CRA, mPLCC, HiSPi Without protective film
AR0238CSSC12SHRA0−DP RGB Color, 12 Degree CRA, mPLCC, HiSPi With protective film
AR0238CSSC12SPRA0−DR RGB Color, 12 Degree CRA, mPLCC, Parallel Without Protective Film
AR0238CSSC12SPRA0−DR1 RGB Color, 12 Degree CRA, mPLCC, Parallel Dry Pack, No Protective film, Low MOQ
AR0238CSSC12SUD20 RGB Color, 12 Degree CRA, Recon die RGB Recon die
AR0238IRSH12SUD20 RGB−IR, 12 Degree CRA, Recon die RGB−IR Recon die
AR0238CSSC12SHRAH3−GEVB RGB Color, 12 Degree CRA, HiSPi Evaluation Board
NOTE: 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 ON Semiconductor AR0238 can be operated in its
default mode or programmed for frame size, exposure, gain,
and other parameters. The default mode output is a 1080p−
resolution image at 60 frames per second (fps) through the
HiSPi port. In linear mode, it outputs 12−bit or 10−bit
A−Law compressed raw data, using the parallel or serial
(HiSPi) output port. In high dynamic range mode, it outputs
two exposure values that the ISP will combine into an HDR
image. The device may be operated in video (master) mode
or in single frame trigger mode.
FRAME_VALID and LINE_VALID signals are output on
dedicated pins, along with a synchronized pixel clock in
parallel mode.
The AR0238 includes additional features to allow
application−specific tuning: windowing and offset, auto
black level correction, and on−board temperature sensor.
Optional register information and histogram statistic
information can be embedded in the first and last 2 lines of
the image frame.
The AR0238 is designed to operate over a wide
temperature range of −30°C to +85°C ambient.
FUNCTIONAL OVERVIEW
The AR0238 is a progressive−scan sensor that generates
a stream of pixel data at a constant frame rate. It uses an
on−chip, phase−locked loop (PLL) that can be optionally
enabled to generate all internal clocks from a single master
input clock running between 6 and 48 MHz. The maximum
output pixel rate is 148.5 Mp/s, corresponding to a clock rate
of 74.25 MHz. Figure 1 shows a block diagram of the sensor
configured in linear mode, and in HDR mode.
AR0238
www.onsemi.com
3
Row Noise Correction
Black Level Correction
Test Pattern Generator
Pixel Defect Correction
Digital Gain and Pedestal
A−Law Compression
Parallel
HiSPi
12 bits
10 bits
12
12
ADC Data
Figure 1. Block Diagram of AR0238
User interaction with the sensor is through the two−wire
serial bus, which communicates with the array control,
analog signal chain, and digital signal chain. The core of the
sensor is a 2.1 Mp Active− Pixel Sensor 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 offset correction and gain), and then through an
analog− to−digital converter (ADC). The output from the
ADC is a 12−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 sensor also offers a high dynamic range
mode of operation where two images and taken using
different exposures. These images are output in from the
sensor and the ISP must combine them into one high
dynamic range image.
AR0238
www.onsemi.com
4
1. All power supplies must be adequately decoupled.
2. ON Semiconductor recommends a resistor value of 1.5 kW, but a greater value may be used for slower two−wire speed.
3. The parallel interface output pads can be left unconnected if the serial output interface is used.
4. ON Semiconductor recommends that 0.1 mF and 10 mF decoupling capacitors for each power supply are mounted as close as possible
to the pad. Actual values and results may vary depending on the layout and design considerations. Refer to the AR0237AT demo
headboard schematics for circuit recommendations.
5. ON Semiconductor recommends that analog power planes are placed in a manner such that coupling with the digital power planes is
minimized.
6. I/O signals voltage must be configured to match VDD_IO voltage to minimize any leakage currents.
Notes:
FLASH
SLVS0_P
SLVS0_N
SLVS1_P
SLVS1_N
SLVS2_P
SLVS2_N
VDD_PLLVDD_IO VAA VAA_PIX
AGND
DGND
VAA_PIXVAA
VDD_IO VDD
SDATA
SCLK
EXTCLK
1.5 kW2
1.5 kW2
TRIGGER
OE_BAR
RESET_BAR
TEST
To Controller
From
Controller
Master Clock
(6−48 MHz)
Digital
I/O
Power1
Digital
Core
Power1Analog
Power1Analog
Power1
Analog
Ground
Digital
Ground
SADDR
VDD_SLVS
HiSPi Power
either 0.4 V
(SLVS) or
1.8 V (HiVCM)1
VDD_PLL
PLL
Power1
SLVS3_P
SLVS3_N
SLVSC_P
SLVSC_N
VDD VDD_SLVS
SHUTTER
Figure 2. Typical Configuration: Serial Four−Lane
HiSPi Interface
AR0238
www.onsemi.com
5
1. All power supplies must be adequately decoupled.
2. ON Semiconductor recommends a resistor value of 1.5 kW, but a greater value may be used for slower two−wire speed.
3. The serial interface output pads can be left unconnected if the parallel output interface is used.
4. ON Semiconductor recommends that 0.1 mF and 10 mF decoupling capacitors for each power supply are mounted as close as possible
to the pad. Actual values and results may vary depending on the layout and design considerations. Refer to the AR0237AT demo
headboard schematics for circuit recommendations.
5. ON Semiconductor recommends that analog power planes are placed in a manner such that coupling with the digital power planes is
minimized.
6. I/O signals voltage must be configured to match VDD_IO voltage to minimize any leakage currents.
7. The EXTCLK input is limited to 6−48 MHz.
Notes:
FRAME_VALID
LINE_VALID
PIXCLK
FLASH
VDD_IO VDD VAA VAA_PIX
AGND
DGND
VAA_PIXVAA
VDD_IO VDD
EXTCLK
SDATA
SCLK
1.5 kW2
1.5 kW2
TRIGGER
OE_BAR
RESET_BAR
TEST
To Controller
From
Controller
Master Clock
(6−48 MHz)
Digital
I/O
Power1
Digital
Core
Power1Analog
Power1Analog
Power1
Analog
Ground
Digital
Ground
DOUT[11:0]
SADDR
PLL
Power1
VDD_PLL
VDD_PLL
SHUTTER
Figure 3. Typical Configuration: Parallel Pixel Data Interface
AR0238
www.onsemi.com
6
6
7
8
9
10
11
12
13
14
15
16
17
18
444546474812345
42
41
40
39
38
37
36
35
34
33
32
31
19 3029282726252423222120
SLVSC_N
SLVS1_P
SLVS1_N
SLVS0_P
SLVS0_N
VDD_SLVS
VDD
SLVS3_P
SLVS3_N
SLVS2_P
SLVS2_N
SLVSC_P
DGND
VDD_PLL
EXTCLK
VAA
AGND
VDD_IO
VDD
DGND
Reserved
VAA
AGND
DGND
SADDR
SDATA
TEST
FLASH
VDD_IO
VDD
VDD_IO
SHUTTER
TRIGGER
OE_BAR
RESET_BAR
SCLK
VDD_IO
VDD
DGND
AGND
VAA_PIX
VAA
ATEST
VAA
VAA_PIX
AGND
DGND
VDD
(Top View − Lead Down)
Figure 4. HiSPi 48−Lead mPLCC Package
43
AR0238
www.onsemi.com
7
Table 3. PIN DESCRIPTIONS, HiSPi 48−Lead mPLCC
DS Name mPLCC Pin Type Description
SLVSC_N 1 Output HiSPi serial DDR clock differential N
SLVS1_P 2 Output HiSPi serial data, lane 1, differential P
SLVS1_N 3 Output HiSPi serial data, lane 1, differential N
SLVS0_P 4 Output HiSPi serial data, lane 0, differential P
SLVS0_N 5 Output HiSPi serial data, lane 0, differential N
VDD_SLVS 6 Power 0.3 V−0.6 V or 1.7 V − 1.9 V port to HiSPi Output Driver. Set the High_VCM
(R0x306E[9]) bit to 1 when configuring VDD_SLVS to 1.7 V – 1.9 V.
DGND 7, 14, 18, 32, 40 Power Digital ground
VDD_PLL 8 Power PLL power, 2.8 V nominal
EXTCLK 9 Input External input clock
VAA 10, 16, 35, 37 Power Analog power, 2.8 V nominal
AGND 11, 17, 33, 39 Power Analog ground.
VDD_IO 12, 20, 30, 42 Power I/O supply power, 1.8/2.8 V nominal
VDD 13, 19, 31, 41, 43 Power Digital power, 1.8 V nominal
Reserved 15 −Reserved, NC
FLASH 21 Output Flash control output
TEST 22 Input Manufacturing test enable pin (connect to Dgnd)
SDATA 23 I/O Two−Wire Serial data I/O
SADDR 24 Input Two−Wire Serial address select. 0: 0x20. 1: 0x30
SCLK 25 Input Two−Wire Serial clock input
RESET_BAR 26 Input Asynchronous reset (active LOW). All settings are restored to factory default.
OE_BAR 27 Input Output enable (active LOW)
TRIGGER 28 Input Exposure synchronization input
SHUTTER 29 Output Control for external mechanical shutter. Can be left floating if not used.
VAA_PIX 34, 38 Power Pixel power, 2.8 V nominal
ATEST 36 −Reserved, NC
SLVS3_P 44 Output HiSPi serial data, lane 3, differential P
SLVS3_N 45 Output HiSPi serial data, lane 3, differential N
SLVS2_P 46 Output HiSPi serial data, lane 2, differential P
SLVS2_N 47 Output HiSPi serial data, lane 2, differential N
SLVSC_P 48 Output HiSPi serial DDR clock differential P
NOTE: The 36 thermal connection pads should be all soldered to DGND plane for better thermal conductivity. Refer to PACKAGE
DIMENSIONS for details..
AR0238
www.onsemi.com
8
346
7
8
9
10
11
12
13
14
15
16
17
18
444546474812345
42
41
40
39
38
37
36
35
34
33
32
31
0319 282726252423222120
DOUT6
DOUT7
DOUT8
DOUT9
DOUT10
DOUT11
DOUT0
DOUT1
DOUT2
DOUT3
DOUT4
DOUT5
DGND
VDD_PLL
EXTCLK
VAA
AGND
VDD_IO
VDD
DGND
Reserved
VAA
AGND
VDD
DGND
TEST
FRAME_VALID
PIXCLK
FLASH
VDD_IO
VDD
VDD_IO
SCLK
SADDR
LINE_VALID
SDATA
VDD_IO
(Top View − Lead Down)
VDD
DGND
AGND
VAA_PIX
VAA
AGND
ATEST
SHUTTER
TRIGGER
OE_BAR
REST_BAR
Figure 5. 48−Lead Parallel mPLCC
29
AR0238
www.onsemi.com
9
Table 4. 48−Lead PARALLEL mPLCC
Name mPLCC Pin Type Description
DOUT6 1 Output Data output 6
DOUT7 2 Output Data output 7
DOUT8 3 Output Data output 8
DOUT9 4 Output Data output 9
DOUT10 5 Output Data output 10
DOUT11 6 Power Data output 11
DGND 7, 14, 24, 40 Power Digital ground
VDD_PLL 8 Power PLL power, 2.8 V nominal
EXTCLK 9 Input External input clock
VAA 10, 16, 37 Power Analog power, 2.8 V nominal
AGND 11, 17, 36, 39 Power Analog Ground
VDD_IO 12, 19, 29, 42 Power I/O supply power, 1.8/2.8 V nominal
VDD 13, 18, 30, 41 Power Digital power, 1.8 V nominal
Reserved 15 −Reserved, NC
FLASH 20 Power Flash control output
PIXCLK 21 Output Pixel Clock
FRAME_VALID 22 Output Frame Valid
TEST 23 Input Manufacturing test enable pin (connect to DGNG)
SDATA 25 I/O Two−Wire Serial data I/O
LINE_VALID 26 Output Line Valid
SADDR 27 Input Two−Wire Serial address select. 0: 0x20, 1: 0x30
SCLK 28 Input Two−Wire Serial clock input
RESET_BAR 31 Input Asynchronous reset (active LOW). All settings are restored to factory default
OE_BAR 32 Input Output enable (active LOW)
TRIGGER 33 Input Exposure synchronization input
SHUTTER 34 Output Control for external mechanical shutter. Can be left floating if not used.
ATEST 35 −Reserved, NC
VAA_PIX 38 Power Pixel power, 2.8 V nominal
DOUT0 43 Output Data Output 0
DOUT1 44 Output Data Output 1
DOUT2 45 Output Data Output 2
DOUT3 46 Output Data Output 3
DOUT4 47 Output Data Output 4
DOUT5 48 Output Data Output 5
NOTE: The 29 thermal connection pads should be all soldered to DGND plane for better thermal conductivity. Refer to PACKAGE
DIMENSIONS for details.
AR0238
www.onsemi.com
10
PIXEL DATA FORMAT
PIXEL ARRAY STRUCTURE
While the sensor’s format is 1928 x1088, additional active
columns and active rows are included for use when
horizontal or vertical mirrored readout is enabled, to allow
readout to start on the same pixel. The pixel adjustment is
always performed for mono−chrome or color versions. The
active area is surrounded with optically transparent dummy
pixels to improve image uniformity within the active area.
Not all dummy pixels or barrier pixels can be read out.
1944
1116
Light Dummy Pixel Active Pixel
10 Barrier + 4 Border Pixels
1928 × 1088
5.78 × 3.26 mm
2 Barrier + 6 Border Pixels
10 Barrier + 4 Border Pixels
2 Barrier + 6 Border Pixels
Figure 6. Pixel Array Description
AR0238
www.onsemi.com
11
Active Pixel (0,0)
Array Pixel (0, 0)
RowReadout Direction
G
B
G
B
G
B
R
G
R
G
R
G
R
G
R
G
R
G
R
G
R
G
R
G
R
G
R
G
R
G
G
B
G
B
G
B
G
B
G
B
G
B
G
B
G
B
G
B
Column Readout Direction
Figure 7. Pixel Color Pattern Detail (RGB) (Top Right Corner)
Figure 8. Pixel Color Pattern Detail (RGB−IR) (Top Right Corner)
GB
G
R
Column Readout Direction
Row Readout Direction
Active Pixel (0, 0)
Array Pixel (0, 0)
…
…
GBRGG
IR GIR GIR GIR
G
RGBRGG
IR GIR GIR GIR
GB
DEFAULT READOUT ORDER
By convention, the sensor core pixel array is shown with
pixel (0,0) in the top right corner (see Figure 7). This reflects
the actual layout of the array on the die. Also, the first pixel
data read out of the sensor in default condition is that of pixel
(10, 14).
When the sensor is imaging, the active surface of the
sensor faces the scene as shown in Figure 9. When the image
is read out of the sensor, it is read one row at a time, with the
rows and columns sequenced as shown in Figure 9.
AR0238
www.onsemi.com
12
Lens
Pixel (0,0)
Row
Readout
Order
Column Readout Order
Scene
Sensor (Rear View)
Figure 9. Imaging a Scene
FEATURES OVERVIEW
For a complete description, recommendations, and usage
guidelines for product features, refer to the AR0238
Developer Guide.
3.0 mm Dual Conversion Gain Pixel
To improve the low light performance and keep the high
dynamic range, a large (3.0 um) dual conversion gain pixel
is implemented for better image optimization. With a dual
conversion gain pixel, the conversion gain of the pixel may
be dynamically changed to better adapt the pixel response
based on dynamic range of the scene. This gain can be
switched manually or automatically by an auto exposure
control module.
HDR
By default, the sensor powers up in Linear Mode. One can
change to HDR Mode. The HDR scheme used is
multi−exposure HDR. This allows the sensor to handle up to
96 dB of dynamic range. In HDR mode, the sensor
sequentially captures two exposures by maintaining two
separate read and reset pointers that are interleaved within
the rolling shutter readout. The exposure ratio may be set to
4x, 8x, 16x, or 32x. Sensor also provides flexibility to
choose any exposure ratio by setting number of t2 exposure
rows indepen− dent of the t1 exposure. The data will be
output as line interleaved data as described in the T1/T2 Line
Interleaved Mode section. There is also an option to output
either T1 only or T2 only.
RESOLUTION
The active array supports a maximum of 1928x1088
pixels to support 1080p resolution. Utilizing a 3.0 um pixel
will result in an optical format of 1/2.7−inch (approximately
6.6 mm diagonal).
FRAME RATE
At full (1080p) resolution, the AR0238 is capable of
running up to 60 fps in linear mode and 30 fps in line
interleaved mode.
IMAGE ACQUISITION MODE
The AR0238 supports two image acquisition modes:
•Electronic rolling shutter (ERS) mode
This is the normal mode of operation. When the AR0238
is streaming, it generates frames at a fixed rate, and each
frame is integrated (exposed) using the ERS. When ERS
mode 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 reset−
ting 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 the same, 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 AR0238 switches
cleanly from the old integration time to the new while only
generating frames with uniform integration. See “Changes
to Integration Time” in the AR0238 Register Reference.
•Global reset 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 AR0238 provides control
signals to interface to that shutter. The benefit of using 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.
EMBEDDED DATA AND STATISTICS
The AR0238 has the capability to output image data and
statistics embedded within the frame timing. There are two
types of information embedded within the frame readout.
AR0238
www.onsemi.com
13
•Embedded Data:
If enabled, these are displayed on the two rows
immediately before the first active pixel row is
displayed.
•Embedded Statistics:
If enabled, these are displayed on the two rows
immediately after the last active pixel row is displayed.
MULTI−CAMERA SYNCHRONIZATION
SLAVE MODE
The slave mode feature of the AR0238 supports triggering
the start of a frame readout from an input signal that is
supplied from an external ASIC. The slave mode signal
allows for precise control of frame rate and register change
updates.
Context Switching and Register Updates
The user has the option of using the highly configurable
context memory, or a simplified implementation in which
only a subset of registers is available for switching. The
AR0238 supports a highly configurable context switching
RAM of size 256 x 16. Within this Context Memory,
changes to any register may be stored. The register set for
each context must be the same, but the number of contexts
and registers per context are limited only by the size of the
context memory.
Alternatively, the user may switch between two
predefined register sets A and B by writing to a context
switch change bit. When the context switch is configured to
context A the sensor will reference the context A registers.
If the context switch is changed from A to B during the
readout of frame n, the sensor will then reference the context
B coarse_integration_time registers in frame n+1 and all
other context B registers at the beginning of reading frame
n+2. The sensor will show the same behavior when changing
from context B to context A. The registers listed in Table 5
are context−switchable:
Table 5. LIST OF CONFIGURABLE REGISTERS FOR CONTEXT A AND CONTEXT B
Context A Context B
Register Description Register Description
coarse_integration_time coarse_integration_time_cb
line_length_pck line_length_pck_cb
frame_length_lines frame_length_lines_cb
row_bin row_bin_cb
col_bin col_bin_cb
fine_gain fine_gain_cb
coarse_gain coarse_gain_cb
coarse_integration_time2 coarse_integration_time2_cb
dcg_manual_set dcg_manual_set_cb
dcg_manual_set_t1 dcg_manual_set_t1_cb
bypass_pix_comb bypass_pix_cb
coarse_gain_t1 coarse_gain_t1_cb
fine_gain_t1 fine_gain_t1_cb
x_addr_start x_addr_start_cb
y_addr_start y_addr_start_cb
x_addr_end x_addr_end_cb
y_addr_end y_addr_end_cb
y_odd_inc y_odd_inc_cb
x_odd_inc x_odd_inc_cb
green1_gain green1_gain_cb
blue_gain blue_gain_cb
red_gain red_gain_cb
green2_gain green2_gain_cb
global_gain global_gain_cb
operation_mode_ctrl operation_mode_ctrl_cb
bypass_pix_comb bypass_pix_comb_cb
AR0238
www.onsemi.com
14
ANALOG/DIGITAL GAINS
A programmable analog gain of 1.0x to 16x (linear and
HDR) applied simultaneously to all color channels will be
featured along with a digital gain of 1x to 16x that may be
configured on a per color channel basis. Analog gain can be
applied per exposure in line interleaved mode.
SKIPPING/BINNING MODES
The AR0238 supports subsampling. Subsampling allows
the sensor to read out a smaller set of active pixels by either
skipping, binning, or summing pixels within the readout
window. Horizontal binning is achieved in the digital
readout. The sensor will sample the combined 2x adjacent
pixels within the same color plane. Vertical row binning is
applied in the pixel readout. Row binning can be configured
as 2x rows within the same color plane. Pixel skipping can
be configured up to 2x in both the x−direction and
y−direction. Skipping pixels in the x−direction will not
reduce the row time. Skipping pixels in the y direction will
reduce the number of rows from the sensor effectively
reducing the frame time. Skipping will introduce image
artifacts from aliasing.
The AR0238 supports row wise vertical binning. Row
wise vertical summing is only supported in monochrome
sensors.
CLOCKING OPTIONS
The sensor contains a phase−locked loop (PLL) that is
used for timing generation and control. The required VCO
clock frequency is attained through the use of a pre−PLL
clock divider followed by a multiplier. The PLL multiplier
should be an even integer. If an odd integer (M) is
programmed, the PLL will default to the lower (M−1) value
to maintain an even multiplier value. The multiplier is
followed by a set of dividers used to generate the output
clocks required for the sensor array, the pixel analog and
digital readout paths, and the output parallel and serial
interfaces. Use of the PLL is required when using the HiSPi
interface.
TEMPERATURE SENSOR
The AR0238 sensor has a built-in PTAT-based
temperature sensor, accessible through registers, that is
capable of measuring die junction temperature. The value
read out from the temperature sensor register is an ADC
output value that needs to be converted downstream to a
final temperature value in degrees Celsius. Since the PTAT
device characteristic response is quite linear in the
temperature range of operation required, a simple linear
function can be used to convert the ADC output value to the
final temperature in degrees Celsius.
A single reference point will be made available via
register read as well as a slope for back−calculating the
junction temperature value. An error of +/-5% or better over
the full specified operating range of the sensor is to be
expected.
SILICON / FIRMWARE / SEQUENCER REVISION
INFORMATION
A revision register will be provided to read out (via I2C)
silicon and sequencer/OTPM revision information. This
will be helpful to distinguish among different lots of material
if there are future OTPM or sequencer revisions.
LENS SHADING CORRECTION
The latest lens shading correction algorithm will be
included for potential low Z height applications.
COMPRESSION
When the AR0238 is configured for linear mode
operation, the sensor can optionally compress 12−bit data to
10−bit using A−law compression. The A−law compression
is disabled by default.
PACKAGING
The AR0238 will be offered in a 11.43 x 11.43 48−Lead
mPLCC package.
PARALLEL INTERFACE
The parallel pixel data interface uses these output−only
signals:
•FRAME_VALID
•LINE_VALID
•PIXCLK
•DOUT[11:0]
HIGH SPEED SERIAL PIXEL (HISPI) INTERFACE
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.
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. The AR0238 supports serial data widths of 10 or 12
bits on one, two, or four lanes. The specification includes a
DLL to compensate for differences in group delay for each
data lane. The DLL is connected to 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. Delay compensation may be set for clock
and/or data lines in the hispi_timing register R0x31C0. If the
DLL timing adjustment is not required, the data and clock
lane delay settings should be set to a default code of 0x0000
to reduce jitter, skew, and power dissipation.
AR0238
www.onsemi.com
15
SENSOR CONTROL INTERFACE
The two−wire serial interface bus enables read/write
access to control and status registers within the AR0238.
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_IO
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 two−wire serial interface can run at 100 kHz
or 400 kHz.
T1/T2 LINE INTERLEAVED MODE
The AR0238 outputs the T1 and T2 exposures separately,
in a line interleaved format. The purpose of this is to enable
off chip HDR linear combination and processing. See the
AR0238 Developer Guide for more information.
Wavelength (nm)
350
Quantum Efficiency (%)
450 550 650 750 850 950 1050 1150
0
10
20
30
40
50
60
70
Red
Green (R)
Green (B)
Blue
Figure 10. Quantum Efficiency − RGB
AR0238
www.onsemi.com
16
Wavelength (nm)
350
Quantum Efficiency (%)
450 550 650 750 850 950 1050 1150
0
10
20
30
40
50
60
70
Red
Green (R)
Green (B)
Blue
IR
Figure 11. Quantum Efficiency − RGB−IR
CRA vs. Image Height Plot
Image Height CRA
(%) (mm) (deg)
Chief Ray Angle (Deg)
Image Height (%)
AR0237 CRA Characteristic
0 10 2030 40506070 8090100110
0
2
4
6
8
10
12
14
16
Figure 12. Chief Ray Angle Characteristics
0 0 0
5 0.166 0.62
10 0.332 1.24
15 0.498 1.86
20 0.664 2.48
25 0.830 3.10
30 0.996 3.72
35 1.162 4.34
40 1.328 4.96
45 1.494 5.58
50 1.660 6.20
55 1.826 6.82
60 1.992 7.44
65 2.158 8.06
70 2.324 8.68
75 2.491 9.30
80 2.657 9.92
85 2.823 10.54
90 2.989 11.16
95 3.155 11.78
100 3.321 12.40
AR0238
www.onsemi.com
17
ELECTRICAL SPECIFICATIONS
Unless otherwise stated, the following specifications
apply under the following conditions:
VDD = 1.8 V –0.10/+0.15;
VDD_IO = VDD_PLL = VAA = VAA_PIX = 2.8 V ± 0.3 V;
VDD_SLVS = 0.4 V – 0.1/+0.2;
TA = −30°C to +85°C;
Output load = 10 pF;
Frequency = 74.25 MHz;
HiSPi off.
TWO−WIRE SERIAL REGISTER INTERFACE
The electrical characteristics of the two−wire serial
register interface (SCLK, SDATA) are shown in Figure 13 and
Table 6.
SDATA
SCLK
S Sr P S
tftrtftr
tSU;DAT tHD;STA
tSU;STO
tSU;STA
tBUF
tHD;DAT tHIGH
tLOW
tHD;STA
NOTE: Read sequence: For an 8−bit READ, read waveforms start after WRITE command and register address are
issued. Figure 13. Two−Wire Serial Bus Timing Parameters
AR0238
www.onsemi.com
18
Table 6. Two−Wire Serial Bus Characteristics
fEXTCLK = 27 MHz; VDD = 1.8 V; VDD_IO = 2.8 V; VAA = 2.8 V; VAA_PIX = 2.8 V; VDD_PLL = 2.8 V; TA = 25°C
Parameter Symbol
Standard Mode Fast Mode
Unit
Min Max Min Max
SCLK Clock Frequency fSCL 0 100 0 400 KHz
Hold time (repeated) START condition. After this period, the first
clock pulse is generated
tHD;STA 4.0 −0.6 −ms
LOW period of the SCLK clock tLOW 4.7 −1.3 −ms
HIGH period of the SCLK clock tHIGH 4.0 −0.6 −ms
Set−up time for a repeated START
condition
tSU;STA 4.7 −0.6 −ms
Data hold time tHD;DAT 0
(Note 11)
3.45
(Note 12)
0 (Note 13) 0.9
(Note 12)
ms
Data set−up time tSU;DAT 250 −100 (Note 13) −ns
Rise time of both SDATA and SCLK signals tr −1000 20 + 0.1Cb
(Note 14)
300 ns
Fall time of both SDATA and SCLK signals tf −300 20 + 0.1Cb
(Note 14)
300 ns
Set−up time for STOP condition tSU;STO 4.0 −0.6 −ms
Bus free time between a STOP and START condition tBUF 4.7 −1.3 −ms
Capacitive load for each bus line Cb −400 −400 pF
Serial interface input pin capacitance CIN_SI −3.3 −3.3 pF
SDATA max load capacitance CLOAD_SD −30−30pF
SDATA pull−up resistor RSD 1.5 4.7 1.5 4.7 kW
8. This table is based on I2C standard (v2.1 January 2000). Philips Semiconductor.
9. Two−wire control is I2C−compatible.
10.All values referred to VIHmin = 0.9 VDD and VILmax = 0.1 VDD levels. Sensor EXCLK = 27 MHz.
11. A device must internally provide a hold time of at least 300 ns for the SDATA signal to bridge the undefined region of the falling edge of SCLK.
12.The maximum tHD;DAT has only to be met if the device does not stretch the LOW period (tLOW) of the SCLK signal.
13.A Fast−mode I2C−bus device can be used in a Standard−mode I2C−bus system, but the requirement tSU;DAT 250 ns must then be met.
This will automatically be the case if the device does not stretch the LOW period of the SCLK signal. If such a device does stretch the LOW
period of the SCLK signal, it must output the next data bit to the SDATA line tr max + tSU;DAT = 1000 + 250 = 1250 ns (according to the
Standard−mode I2C−bus specification) before the SCLK line is released.
14.Cb = total capacitance of one bus line in pF.
AR0238
www.onsemi.com
19
I/O TIMING
By default, the AR0238 launches pixel data, FV, and LV
with the falling edge of PIXCLK. The expectation is that the
user captures DOUT[11:0], FV, and LV using the rising edge
of PIXCLK.
See Figure 14 below and Table 7 on page 19 for I/O
timing (AC) characteristics.
EXTCLK
PIXCLK
Data[11:0]
LINE_VALID/
FRAME_VALID
Pxl_0 Pxl_1 Pxl_2 Pxl_n
tPFL
tPLL
tFP
tRP
tF
tR
90% 90% 90% 90%
10% 10% 10% 10%
tEXTCLK
tPD
tPLH
tPFH
FRAME_VALID Leads LINE_VALID
by 6 PIXCLKs
FRAME_VALID Trails LINE_VALID
by 6 PIXCLKs
Figure 14. I/O Timing Diagram
Table 7. I/O TIMING CHARACTERISTICS
Symbol Definition Condition Min Typ Max Unit
fEXTCLK1s Input Clock Frequency 6 – 48 MHz
tEXTCLK1 Input Clock Period 20.8 – 166 ns
tRInput Clock Rise Time – 3 – ns
tFInput Clock Fall Time – 3 – ns
tRP Pixclk Rise Time 2 3.5 5 ns
tFP Pixclk Fall Time 2 3.5 5 ns
Clock Duty Cycle 45 50 55 %
tCP EXTCLK to PIXCLK Propagation Delay Nominal Voltages,
PLL Disabled
10 14 18 ns
fPIXCLK PIXCLK Frequency Default, Nominal
Voltages
6 – 74.25 MHz
tPD PIXCLK to Data Valid Default, Nominal
Voltages
0 2.5 5 ns
tPFH PIXCLK to FV HIGH Default, Nominal
Voltages
−2 3 6 ns
tPLH PIXCLK to LV HIGH Default, Nominal
Voltages
−2 3 6 ns
tPFL PIXCLK to FV LOW Default, Nominal
Voltages
−2 2.5 6 ns
tPLL PIXCLK to LV LOW Default, Nominal
Voltages
−2 2.5 6 ns
CLOAD Output Load Capacitance –<10 – pF
CIN Input Pin Capacitance – 2.5 – pF
NOTE: I/O timing characteristics are measured under the following conditions:
− Temperature is 25°C ambient
− 10 pF load
− 1.8 V I/O supply voltage
AR0238
www.onsemi.com
20
DC ELECTRICAL CHARACTERISTICS
The DC electrical characteristics are shown in the tables
below.
Table 8. DC ELECTRICAL CHARACTERISTICS
Symbol Definition Condition Min Typ Max Unit
VDD Core digital voltage 1.7 1.8 1.95 V
VDD_IO I/O digital voltage 1.7/2.5 1.8/2.8 1.9/3.1 V
VAA Analog voltage 2.5 2.8 3.1 V
VAA_PIX Pixel supply voltage 2.5 2.8 3.1 V
VDD_PLL PLL supply voltage 2.5 2.8 3.1 V
VDD_SLVS HiSPi supply voltage 0.3 0.4 0.6 V
VIH Input HIGH voltage VDD_IO*0.7 – – V
VIL Input LOW voltage – – VDD_IO*0.3 V
IIN Input leakage current No pull−up resistor; VIN = VDD_IO or
DGND
20 – – mA
VOH Output HIGH voltage VDD_IO−0.3 – – V
VOL Output LOW voltage – – 0.4 V
IOH Output HIGH current At specified VOH −22 – – mA
IOL Output LOW current At specified VOL – – 22 mA
Table 9. ABSOLUTE MAXIMUM RATINGS
Symbol Definition Condition Min Max Unit
VDD_MAX Core digital voltage –0.3 2.4 V
VDD_IO_MAX I/O digital voltage –0.3 4 V
VAA_MAX Analog voltage –0.3 4 V
VAA_PIX Pixel supply voltage –0.3 4 V
VDD_PLL PLL supply voltage –0.3 4 V
VDD_SLVS_MAX HiSPi I/O digital voltage –0.3 2.4 V
tST Storage temperature –40 85 °C
Stresses exceeding those listed in the Maximum Ratings table may damage the device. If any of these limits are exceeded, device functionality
should not be assumed, damage may occur and reliability may be affected.
AR0238
www.onsemi.com
21
Table 10. 1080p30 LINEAR 74 MHZ PARALLEL 2.8 V
(Operating currents are measured in mA at the following conditions: VAA = VAA_PIX = VDD_PLL = VDD_IO = 2.8 V; VDD = 1.8 V; PLL
Enabled and PIXCLK = 74.25 MHz; Low power mode enabled; TA = 25°C)
Definition Condition Symbol Voltage Min Typ Max Unit
Digital Operating Current Streaming 1080p30 IDD 1.8 20 34 50 mA
I/O Digital Operating Current Streaming 1080p30 IDD_IO 2.8 15 28 50 mA
Analog Operating Current Streaming 1080p30 IAA 2.8 15 26 50 mA
Pixel Supply Current Streaming 1080p30 IAA_PIX 2.8 1 3 7 mA
PLL Supply Current Streaming 1080p30 IDD_PLL 2.8 5.5 6.4 7 mA
Power 138.2 238.72 409.2 mW
Table 11. 1080p30 LINEAR 74 MHZ PARALLEL 1.8 V
(Operating currents are measured in mA at the following conditions: VAA = VAA_PIX = VDD_PLL = 2.8 V; VDD = VDD_IO = 1.8 V; PLL
Enabled and PIXCLK = 74.25 MHz; Low power mode enabled; TA = 25°C Dark Image, 8× Analog Gain, HCG, 20 ms integration time)
Definition Condition Symbol Voltage Min Typ Max Unit
Digital Operating Current Streaming 1080p30 IDD 1.8 20 34 50 mA
I/O Digital Operating Current Streaming 1080p30 IDD_IO 1.8 10 14 30 mA
Analog Operating Current Streaming 1080p30 IAA 2.8 15 26 50 mA
Pixel Supply Current Streaming 1080p30 IAA_PIX 2.8 1 3 7 mA
PLL Supply Current Streaming 1080p30 IDD_PLL 2.8 5.5 6.4 7 mA
Power 114.2 185.52 323.2 mW
Table 12. 1080p30 LINEAR 74 MHZ HISPI SLVS
(Operating currents are measured in mA at the following conditions: VAA = VAA_PIX = VDD_PLL = 2.8 V; VDD = VDD_IO = 1.8 V;
VDD_SLVS = 0.4 V; PLL Enabled and PIXCLK = 74.25 MHz; 4−lane HiSPi mode; Low power mode enabled; TA = 25°C Dark Image,
8× Analog Gain, HCG, 20 ms integration time)
Definition Condition Symbol Voltage Min Typ Max Unit
Digital Operating Current Streaming 1080p30 IDD 1.8 25 44 65 mA
Analog Operating Current Streaming 1080p30 IAA 2.8 15 26 50 mA
Pixel Supply Current Streaming 1080p30 IAA_PIX 2.8 1 3 7 mA
PLL Supply Current Streaming 1080p30 IDD_PLL 2.8 6 7.5 8.5 mA
SLVS Supply Current Streaming 1080p30 IDD_SLVS 0.4 6 9.5 14 mA
Power 109 185.2 306 mW
Table 13. 1080p30 LINEAR 74 MHZ HISPI HIVCM
(Operating currents are measured in mA at the following conditions: VAA = VAA_PIX = VDD_PLL = 2.8 V; VDD = VDD_IO = VDD_SLVS =
1.8 V; PLL Enabled and PIXCLK = 74.25 MHz; 4−lane HiSPi mode; Low power mode enabled; TA = 25°C Dark Image, 8× Analog Gain,
HCG, 20 ms integration time)
Definition Condition Symbol Voltage Min Typ Max Unit
Digital Operating Current Streaming 1080p30 IDD 1.8 25 44 65 mA
Analog Operating Current Streaming 1080p30 IAA 2.8 15 26 50 mA
Pixel Supply Current Streaming 1080p30 IAA_PIX 2.8 1 3 7 mA
PLL Supply Current Streaming 1080p30 IDD_PLL 2.8 6 7.5 8.5 mA
SLVS Supply Current Streaming 1080p30 IDD_SLVS 1.8 12 20 35 mA
Power 128.2 217.4 363.4 mW
AR0238
www.onsemi.com
22
Table 14. 1080p60 LINEAR 74 MHZ HISPI SLVS
(Operating currents are measured in mA at the following conditions: VAA = VAA_PIX = VDD_PLL = 2.8 V; VDD = VDD_IO = 1.8 V;
VDD_SLVS = 0.4 V; PLL Enabled and PIXCLK = 74.25 MHz; 4−lane HiSPi mode; TA= 25°C Dark Image, 8× Analog Gain, HCG, 20 ms
integration time)
Definition Condition Symbol Voltage Min Typ Max Unit
Digital Operating Current Streaming 1080p60 IDD 1.8 50 88 130 mA
Analog Operating Current Streaming 1080p60 IAA 2.8 20 36 60 mA
Pixel Supply Current Streaming 1080p60 IAA_PIX 2.8 1 4 8 mA
PLL Supply Current Streaming 1080p60 IDD_PLL 2.8 7 8.5 9.5 mA
SLVS Supply Current Streaming 1080p60 IDD_SLVS 0.4 6 9.5 14 mA
Power 170.8 298 442.6 mW
Table 15. 1080p60 LINEAR 74 MHZ HISPI HIVCM
(Operating currents are measured in mA at the following conditions: VAA = VAA_PIX = VDD_PLL = 2.8 V; VDD = VDD_IO = 1.8 V;
VDD_SLVS = 1.8 V; PLL Enabled and PIXCLK = 74.25 MHz; 4−lane HiSPi mode; TA= 25°C Dark Image, 8× Analog Gain, HCG, 20 ms
integration time)
Definition Condition Symbol Voltage Min Typ Max Unit
Digital Operating Current Streaming 1080p60 IDD 1.8 50 88 130 mA
Analog Operating Current Streaming 1080p60 IAA 2.8 20 36 60 mA
Pixel Supply Current Streaming 1080p60 IAA_PIX 2.8 1 4 8 mA
PLL Supply Current Streaming 1080p60 IDD_PLL 2.8 7 8.5 9.5 mA
SLVS Supply Current Streaming 1080p60 IDD_SLVS 1.8 12 20 35 mA
Power 190 330.2 500 mW
Table 16. 1080p30 LINE−INLEAVED 74MHZ HISPI SLVS
(Operating currents are measured in mA at the following conditions: VAA = VAA_PIX = VDD_PLL = 2.8 V; VDD = VDD_IO = 1.8 V;
VDD_SLVS = 0.4 V; PLL Enabled and PIXCLK = 74.25 MHz; 4−lane HiSPi mode; TA= 25°C Dark Image, 8× Analog Gain, HCG, 20 ms
integration time)
Definition Condition Symbol Voltage Min Typ Max Unit
Digital Operating Current Streaming 1080p30 IDD 1.8 50 88 130 mA
Analog Operating Current Streaming 1080p30 IAA 2.8 20 36 60 mA
Pixel Supply Current Streaming 1080p30 IAA_PIX 2.8 1 4 8 mA
PLL Supply Current Streaming 1080p30 IDD_PLL 2.8 7 8.5 9.5 mA
SLVS Supply Current Streaming 1080p30 IDD_SLVS 0.4 6 9.5 14 mA
Power 170.8 298 442.6 mW
Table 17. 1080p30 LINE−INLEAVED 74MHZ HISPI HIVCM
(Operating currents are measured in mA at the following conditions: VAA = VAA_PIX = VDD_PLL = 2.8 V; VDD = VDD_IO = 1.8 V;
VDD_SLVS = 1.8 V; PLL Enabled and PIXCLK = 74.25 MHz; 4−lane HiSPi mode; TA= 25°C Dark Image, 8× Analog Gain, HCG, 20 ms
integration time)
Definition Condition Symbol Voltage Min Typ Max Unit
Digital Operating Current Streaming 1080p30 IDD 1.8 50 88 130 mA
Analog Operating Current Streaming 1080p30 IAA 2.8 20 36 60 mA
Pixel Supply Current Streaming 1080p30 IAA_PIX 2.8 1 4 8 mA
PLL Supply Current Streaming 1080p30 IDD_PLL 2.8 7 8.5 9.5 mA
SLVS Supply Current Streaming 1080p30 IDD_SLVS 1.8 12 20 35 mA
Power 190 330.2 500 mW
AR0238
www.onsemi.com
23
HiSPi ELECTRICAL SPECIFICATIONS
The ON Semiconductor AR0238 sensor supports both
SLVS and HiVCM HiSPi modes. Refer to the High-Speed
Serial Pixel (HiSPi) Interface Physical Layer Specification
v2.00.00 for electrical definitions, specifications, and
timing information. The VDD_SLVS supply in this datasheet
corresponds to VDD_TX in the HiSPi Physical Layer
Specification. Similarly, VDD is equivalent to VDD_HiSPi
as referenced in the specification. The DLL as implemented
on AR0238 is limited in the number of available delay steps
and differs from the HiSPi specification as described in this
section.
Table 18. CHANNEL SKEW
Measurement Conditions: VDD_HiSPi = 1.8 V; VDD_HiSPi_TX = 0.4V; Data Rate = 480 Mbps;
DLL set to 0
Data Lane Skew in Reference to Clock tCHSKEW1PHY −150 ps
AR0238
www.onsemi.com
24
POWER−ON RESET AND STANDBY TIMING
POWER−UP SEQUENCE
The recommended power−up sequence for the AR0238 is
shown in Figure 15. The available power supplies
(VDD_IO, VDD, VDD_SLVS, VDD_PLL, VAA,
VAA_PIX) must have the separation specified below.
1. Turn on VDD_PLL power supply.
2. After 100 ms, turn on VAA and VAA_PIX power
supply.
3. 3. After 100 ms, turn on VDD_IO power supply.
4. After 100 ms, turn on VDD power supply.
5. After 100 ms, turn on VDD_SLVS power supply.
6. After the last power supply is stable, enable
EXTCLK.
7. Assert RESET_BAR for at least 1 ms. The parallel
interface will be tri−stated during this time.
8. Wait 150000 EXTCLKs (for internal initialization
into software standby.
9. Configure PLL, output, and image settings to
desired values.
10. Wait 1ms for the PLL to lock.
11. Set streaming mode (R0x301a[2] = 1).
EXTCLK
VDD_SLVS (0.4)
VAA_PIX
VAA (2.8)
VDD_IO (1.8/2.8)
VDD (1.8)
VDD_PLL (2.8) t0
t1
t2
t3
t4
t5t6
tXHard
Reset
Internal
Initialization
Software
Standby PLL Lock Streaming
RESET_BAR
Figure 15. Power Up
Table 19. POWER−UP SEQUENCE
Definition Symbol Min Typ Max Unit
VDD_PLL to VAA/VAA_PIX (Note 17) t0 0 100 – ms
VAA/VAA_PIX to VDD_IO t1 0 100 – ms
VDD_IO to VDD t2 0 100 – ms
VDD to VDD_SLVS t3 0 100 – ms
Xtal settle time tx – 30
(Note 15)
– ms
Hard Reset t4 1
(Note 16)
– – ms
Internal Initialization t5 150000 – – EXTCLK
s
PLL Lock Time t6 1 – – ms
15.Xtal settling time is component−dependent, usually taking about 10 – 100 ms.
16.Hard reset time is the minimum time required after power rails are settled. In a circuit where Hard reset is held down by RC circuit, then the
RC time must include the all power rail settle time and Xtal settle time.
17.It is critical that VDD_PLL is not powered up after the other power supplies. It must be powered before or at least at the same time as the
others. If the case happens that VDD_PLL is powered after other supplies then sensor may have functionality issues and will experience
high current draw on this supply.
AR0238
www.onsemi.com
25
POWER−DOWN SEQUENCE
The recommended power−down sequence for the
AR0238 is shown in Figure 16. The available power
supplies (VDD_IO, VDD, VDD_SLVS, VDD_PLL, VAA,
VAA_PIX) must have the separation specified below.
1. Disable streaming if output is active by setting
standby R0x301a[2] = 0
2. The soft standby state is reached after the current
row or frame, depending on configuration, has
ended.
3. Turn off VDD_SLVS.
4. Turn off VDD.
5. Turn off VDD_IO.
6. Turn off VAA/VAA_PIX.
7. Turn off VDD_PLL.
EXTCLK
VDD_PLL (2.8)
VDD_IO (1.8/2.8)
VDD (1.8)
VDD_SLVS (0.4)
t0
Power Down until Next
Power Up Cycle
t1
t2
t3
t4
VAA_PIX
VAA (2.8)
Figure 16. Power Down
Table 20. POWER−DOWN SEQUENCE
Definition Symbol Min Typ Max Unit
VDD_SLVS to VDD t0 0 – – ms
VDD to VDD_IO t1 0 – – ms
VDD_IO to VAA/VAA_PIX t2 0 – – ms
VAA/VAA_PIX to VDD_PLL t3 0 – – ms
Power Down until Next Power Up Time t4 100 – – ms
NOTE: t4 is required between power down and next power up time; all decoupling caps from regulators must be completely discharged.
PLCC48 11.43x11.43 (HiSPi)
CASE 776AQ
ISSUE F
DATE 18 DEC 2019
XXXX = Specific Device Code
Y = Year
ZZZ = Lot Traceability
*This information is generic. Please refer to
device data sheet for actual part marking.
Pb−Free indicator, “G” or microdot “G”, may
or may not be present. Some products may
not follow the Generic Marking.
GENERIC
MARKING DIAGRAM*
MECHANICAL CASE OUTLINE
PACKAGE DIMENSIONS
ON Semiconductor and are trademarks of Semiconductor Components Industries, LLC dba ON Semiconductor or its subsidiaries in the United States and/or other countries.
ON Semiconductor reserves the right to make changes without further notice to any products herein. ON Semiconductor makes no warranty, representation or guarantee regarding
the suitability of its products for any particular purpose, nor does ON Semiconductor assume any liability arising out of the application or use of any product or circuit, and specifically
disclaims any and all liability, including without limitation special, consequential or incidental damages. ON Semiconductor does not convey any license under its patent rights nor the
rights of others.
98AON99907F
DOCUMENT NUMBER:
DESCRIPTION:
Electronic versions are uncontrolled except when accessed directly from the Document Repository.
Printed versions are uncontrolled except when stamped “CONTROLLED COPY” in red.
PAGE 1 OF 1
PLCC48 11.43x11.43 (HiSPi)
© Semiconductor Components Industries, LLC, 2018 www.onsemi.com
PLCC48 11.43x11.43 (Parallel)
CASE 776AS
ISSUE D
DATE 18 DEC 2019
XXXX = Specific Device Code
Y = Year
ZZZ = Lot Traceability
*This information is generic. Please refer to
device data sheet for actual part marking.
Pb−Free indicator, “G” or microdot “G”, may
or may not be present. Some products may
not follow the Generic Marking.
GENERIC
MARKING DIAGRAM*
MECHANICAL CASE OUTLINE
PACKAGE DIMENSIONS
ON Semiconductor and are trademarks of Semiconductor Components Industries, LLC dba ON Semiconductor or its subsidiaries in the United States and/or other countries.
ON Semiconductor reserves the right to make changes without further notice to any products herein. ON Semiconductor makes no warranty, representation or guarantee regarding
the suitability of its products for any particular purpose, nor does ON Semiconductor assume any liability arising out of the application or use of any product or circuit, and specifically
disclaims any and all liability, including without limitation special, consequential or incidental damages. ON Semiconductor does not convey any license under its patent rights nor the
rights of others.
98AON12147G
DOCUMENT NUMBER:
DESCRIPTION:
Electronic versions are uncontrolled except when accessed directly from the Document Repository.
Printed versions are uncontrolled except when stamped “CONTROLLED COPY” in red.
PAGE 1 OF 1
PLCC48 11.43x11.43 (Parallel)
© Semiconductor Components Industries, LLC, 2018 www.onsemi.com
www.onsemi.com
1
ON Semiconductor and are trademarks of Semiconductor Components Industries, LLC dba ON Semiconductor or its subsidiaries in the United States and/or other countries.
ON Semiconductor owns the rights to a number of patents, trademarks, copyrights, trade secrets, and other intellectual property. A listing of ON Semiconductor’s product/patent
coverage may be accessed at www.onsemi.com/site/pdf/Patent−Marking.pdf. ON Semiconductor reserves the right to make changes without further notice to any products herein.
ON Semiconductor makes no warranty, representation or guarantee regarding the suitability of its products for any particular purpose, nor does ON Semiconductor assume any liability
arising out of the application or use of any product or circuit, and specifically disclaims any and all liability, including without limitation special, consequential or incidental damages.
Buyer is responsible for its products and applications using ON Semiconductor products, including compliance with all laws, regulations and safety requirements or standards,
regardless of any support or applications information provided by ON Semiconductor. “Typical” parameters which may be provided in ON Semiconductor data sheets and/or
specifications can and do vary in different applications and actual performance may vary over time. All operating parameters, including “Typicals” must be validated for each customer
application by customer’s technical experts. ON Semiconductor does not convey any license under its patent rights nor the rights of others. ON Semiconductor products are not
designed, intended, or authorized for use as a critical component in life support systems or any FDA Class 3 medical devices or medical devices with a same or similar classification
in a foreign jurisdiction or any devices intended for implantation in the human body. Should Buyer purchase or use ON Semiconductor products for any such unintended or unauthorized
application, Buyer shall indemnify and hold ON Semiconductor and its officers, employees, subsidiaries, affiliates, and distributors harmless against all claims, costs, damages, and
expenses, and reasonable attorney fees arising out of, directly or indirectly, any claim of personal injury or death associated with such unintended or unauthorized use, even if such
claim alleges that ON Semiconductor was negligent regarding the design or manufacture of the part. ON Semiconductor is an Equal Opportunity/Affirmative Action Employer. This
literature is subject to all applicable copyright laws and is not for resale in any manner.
PUBLICATION ORDERING INFORMATION
TECHNICAL SUPPORT
North American Technical Support:
Voice Mail: 1 800−282−9855 Toll Free USA/Canada
Phone: 011 421 33 790 2910
LITERATURE FULFILLMENT:
Email Requests to: orderlit@onsemi.com
ON Semiconductor Website: www.onsemi.com
Europe, Middle East and Africa Technical Support:
Phone: 00421 33 790 2910
For additional information, please contact your local Sales Representative
◊
