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 Advanced Information Preliminary
OV6620/OV6120
OV6620 SINGLE-CHIP CMOS CIF COLOR DIGITAL CAMERA OV6120 SINGLE-CHIP CMOS CIF B&W DIGITAL CAMERA
Features
n n n n n n n n 101,376 pixels, 1/4" lens, CIF/QCIF format Progressive scan read out Data format - YCrCb 4:2:2, GRB 4:2:2, RGB Raw Data 8/16 bit video data: CCIR601, CCIR656, ZV port Wide dynamic range, anti-blooming, zero smearing Electronic exposure / Gain / white balance control Image enhancement - brightness, contrast, gamma, saturation, sharpness, window, etc. Internal/external synchronization n n Frame exposure/line exposure option 5-Volt operation, low power dissipation - n n < 80 mW active power - < 10 A in power-save mode Gamma correction (0.45/0.55/1.00) I2C programmable (400 kb/s): - color saturation, brightness, contrast, white balance, exposure time, gain
General Description
The OV6620 (color) and OV6120 (black and white) CMOS Image sensors are single-chip video/imaging camera devices designed to provide a high level of functionality in a single, small-footprint package. Both devices incorporate a 352 x 288 image array capable of operating up to 60 frames per second image capture. Proprietary sensor technology utilizes advanced algorithms to cancel Fixed Pattern Noise (FPN), eliminate smearing, and drastically reduce blooming. All needed camera functions including exposure control, gamma, gain, white balance, color matrix, windowing, and more, are programmable through an I2C interface. Both devices can be programmed to provide image output in either 8-bit or 16-bit digital formats. Applications include: Video Conferencing, Video Phone, Video Mail, Still Image, and PC Multimedia.
Array Elements (CIF) (QCIF) ASUB VRCAP2 FREX AGCEN RESET SVDD SGND MULT SDA SCL DEVDD DEGND Pixel Size Image Area Max Frames/Sec Electronic Exposure Scan Mode Gamma Correction Min. Illumination (3000K) S/N Ratio (Digital Camera Out) FPN Dark Current Dynamic Range Power Supply Power Requirements Package
356 x 292 (176 x 144) 9.0 x 8.2 m 3.1 x 2.5 mm Up to 60 FPS Up to 500 : 1 (for selected FPS) progressive 0.45/.55/1.0 OV6620 - < 3 lux @ f1.2 OV6120 - < 0.5 lux @ f1.2 > 48 dB (AGC = Off, Gamma = 1) < 0.03% VP-P < 0.2 nA/cm2 > 72 dB 5VDC, 5% (Anal.) 5VDC or 3.3VDC (DIO) < 80mW Active < 30W Standby 48 pin LCC
AGND AVDD PWDN VRCAP1 VRCAP3 IICB VTO ADVDD ADGND VSYNC/CSYS FODD/CLK HREF/VSFRAM
7 8 9 10 11 12 13 14 15 16 17 18
6 5 4 3 2 1 48 47 46 45 44 43
OV6620/OV6120
42 41 40 39 38 37 36 35 34 33 32 31
BW/CHSYNC CBAR/Y0 Y1 G2X/Y2 RGB/Y3 CS1/Y4 SHARP/Y5 CS2/Y6 CS0/Y7 PWDB/PCLK DOVDD DGND
OV6620/OV6120 PIN ASSIGNMENTS
OmniVision Technologies, Inc. 930 Thompson Place Sunnyvale, CA 94086 U.S.A. Tel: (408) 733-3030 Fax: (408) 733-3061 e-mail: info@ovt.com Website: http://www.ovt.com
UV7/B8 UV6ABKEN UV5/MIR UV4 UV3 UV2/QCIF UV1/CCIR656 UV0/GAMMA XCLK1 XCLK2 DVDD DGND
19 20 21 22 23 24 25 26 27 28 29 30
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OMNIVISION TECHNOLOGIES, Inc. OV6620/OV6120 SINGLE IC CMOS COLOR AND B/W DIGITAL CAMERAS
Table 1. Pin Description
Pin No. 01 02 03 SVDD RESET AGCEN Name Pin Type Vin Function (Default = 0) Function (Default = 0) Array power (+5VDC) Chip Reset, active high Automatic Gain Control (AGC) selection "0" - Disable AGC "1" - Enable AGC NOTE: This function is disabled when OV6620/OV6120 sensor is configured in I2C mode. 04 FREX Function (Default = 0) Vref (2.5V) Vin Vin Vin Function (Default = 0) N/C Frame Exposure Control "0" - Disable Frame Exposure Control "1" - Enable Frame Exposure Control Array reference. Connect to ground through 0.1 uF capacitor. Analog substrate voltage Analog ground Analog power supply (+5VDC) Power down mode selection "0" - normal mode "1" - power down mode Internal voltage reference. Connect to ground through 0.1 F capacitor. Internal voltage reference. Connect to ground through 1 F capacitor. Function (Default = 0) I2C enable selection "0" - Enable I2C "1" - Enable autocontrol mode Luminance Composite Signal Output Analog power supply (+5VDC) Analog signal ground Vertical sync output. At power up, read as CSYS. Field ID FODD output or main clock output HREF output. At power up, read as VSFRAM Bit 7 of U video component output. At power up, sampled as B8. Bit 6 of U video component output. At power up, sampled as ABKEN. Bit 5 of U video component output. At power up, sampled as MIR. Bit 4of U video component output. Bit 3 of U video component output. Function/Description
05 06 07 08 09
VRCAP2 ASUB AGND AVDD PWDN
10 11 12
VrCAP1 VrCAP3 IICB
13 14 15 16 17 18 19 20 21 22 23
VTO ADVDD ADGND VSYNC/CSYS FODD/CLK HREF/VSFRAM UV7/B8 UV6/ABKEN UV5/MIR UV4 UV3
O Vin Vin I/O I/O I/O I/O I/O I/O I/O I/O
OMNIVISION TECHNOLOGIES, Inc. OV6620/OV6120
Table 1. Pin Description
Pin No. 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 Name UV2/QCIF UV1/CC656 UV0/GAMMA XCLK1 XCLK2 DVDD DGND DOGND DOVDD PCLK/PWDB Y7/CS0 Y6/CS2 Y5/SHARP Y4/CS1 Y3/RGB Y2/G2X Y1 Y0/CBAR CHSYNC/BW DEGND DEVDD SCL SDA MULT Pin Type I/O I/O I/O I O Vin Vin Vin Vin I/O I/O I/O I/O I/O I/O I/O I/O I/O I/O Vin Vin I I/O Function (Default = 0)
Advanced Information Preliminary
SINGLE IC CMOS COLOR AND B/W DIGITAL CAMERAS
Function/Description Bit 2 of U video component output. At power up, sampled as QCIF. Bit 1 of U video component output. At power up, sampled as CC656. Bit 0 of U video component output. At power up, sampled as GAMMA. Crystal clock input Crystal clock output Digital power supply (+5VDC) Digital ground Digital interface output buffer ground Digital interface output buffer power supply (+5VDC) PCLK output. At power up sampled as PWDB. Bit 7 of Y video component output. At power up, sampled as CS0. Bit 6 of Y video component output. At power up, sampled as CS2. Bit 5 of Y video component. At power up, sampled as SHARP. Bit 4 of Y video component. At power up, sampled as CS1 Bit 3 of Y video component output. At power up, sampled as RGB. Bit 2 of Y video component output. At power up, sampled as G2X. Bit 1 of Y video component output. Bit 0 of Y video component output. At power up, sampled as CBAR. CHSYNC output. At power up, sampled as BW. Decoder ground. Decoder power supply (+5VDC) I2C serial interface clock input I2C serial interface data input and output. I2C slave selection "0" - Select single slave ID "1" - Enable multiple (8) slaves Array ground
48
SGND
Vin
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SINGLE IC CMOS COLOR AND B/W DIGITAL CAMERAS
1. Functional Description
(Note: References to color features do not apply to the OV6120 B&W Digital Image Sensor.)
1.1
Overview
The OV6620/OV6120 sensor is a 1/4-inch CMOS imaging device. The sensor contains approximately 101,376 pixels. Its design is based on a field integration read-out system with line-by-line transfer and an electronic shutter with a synchronous pixel read out scheme. The color filter of the sensor consists of a primary color RG/GB array arranged in line-alternating fashion.
Referring to Figure 1, OV6620/OV6120 CMOS Image Sensor Block Diagram below, the OV6620 sensor includes a 356 x 292 resolution image array, an analog signal processor, dual 8-bit Analog-to-Digital converters, analog video multiplexer, digital data formatter and video port, I2C interface and registers, digital controls including timing block, exposure, and black and white balance.
VTO GAMMA DENB
analog processing
Y Cb Cr
formatter
mx
ADC
video port
r g b
Y(7:0)
mx
UV(7:0)
ADC
column sense amp row select
(356x292) image array
exposure detect
white balance detect
registers WB control
AWB AWBTH/ AWBTM
sys-clk
video timing generator
PCLK HREF FODD CHSYNC MIR
exposure control
AGCEN PROG FZEX
I2 C interface
SCL SDA IICB
1/2
XVCLK1
VSYNC
FREZ
FSIN
Figure 1. OV6620/OV6120 CMOS Image Sensor Block Diagram
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Advanced Information Preliminary
SINGLE IC CMOS COLOR AND B/W DIGITAL CAMERAS 1.2.2 Image Processing
The image is captured by the 356 x 592 pixel image array and routed to the analog processing section where the majority of signal processing occurs. This block contains the circuitry which performs color separation, matrixing, Automatic Gain Control (AGC), gamma correction, color correction, color balance, black level calibration, "knee" smoothing, aperture correction, and controls for picture luminance, chrominance, and antialias filtering. The analog video signals are based on the following formula:
Y = 0.59G + 0.31R + 0.11B U = R-Y V = B-Y where R,G,B are the equivalent color components in each pixel.
The algorithm used for the electronic exposure control is based on the brightness of the full image. The exposure is optimized for a "normal" scene which assumes the subject is well lit relative to the background. In situations where the image is not well lit, the Automatic Exposure Control (AEC) White/Black ratio may be adjusted to suit the needs of the application. Additional on-chip functions include Automatic Gain Control (AGC) which provides a gain boost of up to 24dB. White balance control enables setting of proper color temperature and can be programmed for automatic or manual operation. Separate saturation, brightness, contrast, and sharpness adjustments allow for further fine tuning of the picture quality and characteristics. The OV6620 image sensor also provides control over the White Balance ratio for increasing/decreasing the image field Red/Blue component ratio. The sensor provides a default setting which may be sufficient for many applications.
A YCrCb format is also supported, based on the formula below:
Y = 0.59G + 0.31R + 0.11B Cr = 0.713 x (R - Y) Cb = 0.564 x (B - Y)
1.2.3
Windowing
The YCrCb/RGB Raw Data signal from the analog processing section is fed to two on-chip 8-bit Analog-toDigital (A-to-D) converters: one for the Y/RG channel and one shared by the CrCb/BG channels. The A-to-D converted data stream is further conditioned in the digital formatter. The processed signal is delivered to the digital video port through the video multiplexer which routes the user-selected 16-, 8-, or 4-bit video data the correct output pins. The on-chip 8-bit A-to-D converters operate at up to 9 MHz, fully synchronous to the pixel rate. Actual conversion rate is set as a function of the frame rate. A-to-D black-level calibration circuitry ensures the following:
- the black level of Y/RGB is normalized to a value of 16 - the peak white level is limited to 240 - CrCb black level is 128 - Peak/Bottom is 240/16 - RGB raw data output range is 16/240 (Note: Values 0 and 255 are reserved for sync flag)
The windowing feature of the OV6620/OV6120 image sensors allows user-definable window sizing as required by the application. Window size setting (in pixels) ranges from 2 x 2 to 356 x 292, and can be positioned anywhere inside the 356 x 292 boundary. Note that modifying window size and/or position does not change frame or data rate. The OV6620/OV6120 imager alters the assertion of the HREF signal to be consistent with the programmed horizontal and vertical region. The default output window is 352 x 288.
1.2.4
Zoom Video Port (ZV)
The OV6620/OV6120 image sensor includes a Zoom Video (ZV) function that supports standard ZV Port interface timing. Signals available include VSYNC, CHSYNC, PCLK and 16-bit data bus: Y[7:0] and UV[7:0]. The rising edge of PCLK clocks data into the ZV port. See Figure 2, Zoom Video Port Timing below.
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SINGLE IC CMOS COLOR AND B/W DIGITAL CAMERAS
VSYNC t8 HREF t8
Even Field 1(FODD=0) Odd Field(FODD=1)
t6 PCLK t1 Y[7:0] / UV[7:0] t2 t4 t3 1 2
t5
t7
351 352
Valid Data Horizontal Timing
VSYNC Tvs Y[7:0]/ UV[7:0] 1 Line Tline
Figure 2. Zoom Video Port Timing
Notes: 1. Zoom Video Port format output signal includes: VSYNC: Vertical sync pulse. HREF: Horizontal valid data output window. PCLK: Pixel clock used to clock valid data and CHSYNC into Zoom V Port. Default frequency is 8.86MHz when use 17.73MHz as system clock. Rising edge of PCLK is used to clock the 16 Bit data. Y[7:0]: 8 Bit luminance data bus. UV[7:0]: 8 Bit chrominance data bus. 2. All timing parameters are provided in Table 13. Zoom Video Port AC Parameters
Tve
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Advanced Information Preliminary
SINGLE IC CMOS COLOR AND B/W DIGITAL CAMERAS
A QCIF mode is available for applications where high resolution image capture is not required. When programmed in this mode, the pixel rate is reduced by onehalf. Default resolution is 176 x 144 pixels and can be user-programmed for other resolutions. Refer to Table 7. QCIF Digital Output Format (YUV, beginning of line) and Table 8. QCIF Digital Output Format (RGB Raw Data, Beginning of Line) for further information.
The OV6620/OV6120 image sensor can also be programmed to provide video output in RGB Raw Data 16bit/8-bit/4-bit format. The output sequence is matched to the OV6620 Color Filter Pattern (See Section Figure 4. Pixel Data Bus (RGB Output), below): - Y channel output sequence is G R G R - UV channel output sequence is B G B G For 8-bit RGB Raw Data video output appears on the Y channel (with an output sequence of B G R G) and the UV channel is disabled. In RGB Raw Data CCIR656 modes, the OV6620/ OV6120 imager asserts SAV (Start of Active Video) and EAV (End of Active Video) to indicate the beginning and the ending of HREF window. As a result, SAV and EAV change with the active pixel window. The 8-bit RGB raw data is also accessible without SAV and EAV information. The OV6620/OV6120 imagers offer flexibility in YUV output format. The devices may be programmed as standard YUV 4:2:2. These devices may be configured to "swap" the U V sequence. When swapped, the UV channel output format for 16-bit configurations becomes: - V U V U...etc. and for 8-bit configurations becomes: - V Y U Y ...etc. A third format is available for the 8-bit configurations and OV6620/OV6120 enables the Y/UV sequence swap: - Y U Y V ...etc. The OV6620 color single-IC camera can be configured for use as a black and white imaging device. In this mode, vertical resolution is greater than in color. Video data output is provided at the Y port (pins 34:41) and the UV port is tri-stated. The data (Y/RGB) output rate is equivalent to operating in 16-bit mode. The Y/UV or RGB output byte MSB and LSB can be reverse-ordered on the OV6620/OV6120 device. The Y7 - Y0 default sequence sets Y7 as MSB and Y0 as LSB. Programming a reverse order configuration sets Y7 as LSB and Y0 is MSB, with bits Y2-Y6 reversed-ordered appropriately.
1.2.6
Video Output
The video output port of the OV6620/OV6120 image sensors provides a number of output format/standard options to suit many different application requirements. Table 2. Digital Output Formats, below, indicates the output formats available. These formats are user programmable through the I2C interface (See Section 3.1 I2C Bus Protocol Format). The OV6620/OV6120 imager supports both CCIR601 and CCIR656 output formats in the following configurations (See Table 3. 4:2:2 16-bit Format for further details):
- 16-bit, 4:2:2 format
(This mode complies with the 60/50 Hz CCIR601 timing standard. See Table 3. 4:2:2 16-bit Format below)
- 8-bit data mode
(In this mode, video information is output in Cb Y Cr Y order using the Y port only and running at twice the pixel rate during which the UV port is inactive. See Table 4. 4:2:2 8-bit Format below)
- 4-bit nibble mode
(In the nibble mode, video output data appears at bits Y4-Y7. The clock rate for the output runs at twice the normal output speed when in B/W mode, and 4 times the normal output speed in when in color mode.)
- 704 x 288 format
(When programmed for this mode, the OV6620/ OV6120 pixel clock is doubled and the video output sequence is Y0Y0Y1Y1 ... and U0U0V0V0 ... See Figure 3, Pixel Data Bus (YUV Output), below.)
The OV6620/OV6120 imaging devices provide VSYNC, HREF, PCLK, FODD, CHSYNC as standard output video timing signals.
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SINGLE IC CMOS COLOR AND B/W DIGITAL CAMERAS
Table 2. Digital Output Formats Resolution
YUV 4:2:2
Pixel Clock
16-bit 8-bit CCIR656 Nibble
352 x 288
Y Y Y Y Y Y Y Y
704 x 288
Y Y Y Y Y Y Y Y
176 x 144
Y Y Y Y Y Y Y Y
RGB
16-bit 8-bit CCIR6561 Nibble
Y/UV swap2 U/V swap YG
16-bit 8-bit YUV3 RGB4 16-bit 8-bit Y Y Y Y Y Y Y Y Y Y Y Y
One Line MSB/LSB swap5 Notes:
16-bit 8-bit
Y
Y
Y
Y
("Y" indicates mode/combination is supported by OV6620/OV6120.) 1. When in RGB CCIR656 format, output is 8 bits. SAV and EAV are inserted at the beginning and ending of HREF, which synchronize the acquisition of Vsync and Hsync. In this format, an 8-bit data bus configuration (without VSYNC and CHSYNC) may be used. 2. Y/UV swap is valid only in 8-bit mode. Y channel output sequence is Y U Y V... 3. In YUV format, U/V swap means UV channel output sequence swap. V U V U... for 16 bit; V Y U Y ... for 8-bit. 4. In RGB format, U/V swap means neighbor row B R output sequence swap. Refer to RGB raw data output format for further details
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Advanced Information Preliminary
SINGLE IC CMOS COLOR AND B/W DIGITAL CAMERAS
Table 3. 4:2:2 16-bit Format Data Bus
Y7 Y6 Y5 Y4 Y3 Y2 Y1 Y0 Y7 Y6 Y5 Y4 Y3 Y2 Y1 Y0
Pixel Byte Sequence
Y7 Y6 Y5 Y4 Y3 Y2 Y1 Y0 Y7 Y6 Y5 Y4 Y3 Y2 Y1 Y0 Y7 Y6 Y5 Y4 Y3 Y2 Y1 Y0 Y7 Y6 Y5 Y4 Y3 Y2 Y1 Y0 Y7 Y6 Y5 Y4 Y3 Y2 Y1 Y0
UV7 UV6 UV5 UV4 UV3 UV2 UV1 UV0 Y FRAME UV FRAME
U7 U6 U5 U4 U3 U2 U1 U0 0 0
V7 V6 V5 V4 V3 V2 V1 V0 1
U7 U6 U5 U4 U3 U2 U1 U0 2 2
V7 V6 V5 V4 V3 V2 V1 V0 3
U7 U6 U5 U4 U3 U2 U1 U0 4 4
V7 V6 V5 V4 V3 V2 V1 V0 5
Table 4. 4:2:2 8-bit Format Data Bus
Y7 Y6 Y5 Y4 Y3 Y2 Y1 Y0 Y FRAME UV FRAME U7 U6 U5 U4 U3 U2 U1 U0 0 01 Y7 Y6 Y5 Y4 Y3 Y2 Y1 Y0
Pixel Byte Sequence
V7 V6 V5 V4 V3 V2 V1 V0 1 Y7 Y6 Y5 Y4 Y3 Y2 Y1 Y0 U7 U6 U5 U4 U3 U2 U1 U0 2 23 Y7 Y6 Y5 Y4 Y3 Y2 Y1 Y0 V7 V6 V5 V4 V3 V2 V1 V0 3 Y7 Y6 Y5 Y4 Y3 Y2 Y1 Y0
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Advanced Information Preliminary
SINGLE IC CMOS COLOR AND B/W DIGITAL CAMERAS
Tclk
PCLK
Tsu Thd
HREF
10 Y Y 10
Y[7:0] UV[7:0]
80
U
V
80
repeat for all data bytes
Pixel Data 16-bit Timing (PCLK rising edge latches data bus) Tclk
PCLK
Tsu Thd
HREF
Y[7:0]
10
80
10
U
Y
V
Y
80
10
repeat for all data bytes Pixel Data 8-bit Timing (PCLK rising edge latches data bus)
Note: Tclk is pixel clock period. When the OV6620 system clock is 17.73 MHz, Tclk = 112 ns for 16-bit output; Tclk = 56 ns for 8-bit output. Tsu is HREF set-up time, maximum is 15 ns; Thd is HREF hold time, maximum is 15 ns.
Figure 3. Pixel Data Bus (YUV Output)
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Advanced Information Preliminary
SINGLE IC CMOS COLOR AND B/W DIGITAL CAMERAS
Tclk
PCLK
Tsu Thd
HREF
10 G R 10
Y[7:0] UV[7:0]
10
B
G
10
repeat for all data bytes
Pixel Data 16-bit Timing PCLK rising edge latches data bus Tclk
PCLK
Tsu Thd
HREF
Y[7:0]
10
10
B
G
B
G
10
10
repeat for all data bytes Pixel Data 8-bit Timing PCLK rising edge latches data bus
Note: Tclk is pixel clock period. When the OV6620 system clock is 17.73MHz, Tclk = 112ns for 16-bit output; Tclk = 56ns for 8-bit output. Tsu is HREF set-up time, maximum is 15 ns; Thd is HREF hold time, maximum is 15 ns.
Figure 4. Pixel Data Bus (RGB Output)
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SINGLE IC CMOS COLOR AND B/W DIGITAL CAMERAS
MSB/LSB swap means: Default Y/UV channel output port relationship is: Table 5. Default Output Sequence
MSB
Output Port Internal Output data Y7 Y7 Y6 Y6 Y5 Y5 Y4 Y4 Y3 Y3 Y2 Y2 Y1 Y1
LSB
Y0 Y0
If the device is programmed for data swap, the sequence is changed to: Table 6. Swapped MSB/LSB Output Sequence
MSB
Output Port Internal Output data Y7 Y0 Y6 Y1 Y5 Y2 Y4 Y3 Y3 Y4 Y2 Y5 Y1 Y6
LSB
Y0 Y7
Table 7. QCIF Digital Output Format (YUV, beginning of line)
Pixel #
Y UV Y0
1
Y1
2
Y2
3
Y3
4
Y4
5
Y5
6
Y6
7
Y7
8
U0,V0
U1,V1
U2,V2
U3,V3
U4,V4
U5,V5
U6,V6
U7,V7
Y channel output Y2 Y3 Y6 Y7 Y10 Y11 ... - UV channel output U2 V3 U6 V7 U10 V11 ... - Every line output data number is half(176 pixels) and only one half line data (every other line, total 144 line) in one frame will be output. Table 8. QCIF Digital Output Format (RGB Raw Data, Beginning of Line)
Pixel #
Line 1 Line 2 B0 G0
1
G1 R1
2
B2 G2
3
G3 R3
4
B4 G4
5
G5 R5
6
B6 G6
7
G7 R7
8
1. Default RGB two line output mode: - Y channel output G0 R1 G4 R5 G8 R9 ... - UV channel output B0 G1 B4 G5 B8 G9 ... - Every line output half data(176 pixels) and all line(144 line) data in one frame will be output. 2. YG two line output mode: - Y channel output G0 R1 G4 R5 G8 R9 ... - UV channel output B0 G1 B4 G5 B8 G9 ... - Every line outputs half data (176 pixels) and all line (144 line) data in one frame will be output. 12
3. QCIF Resolution Digital Output Format - Y channel output Y2 Y3 Y6 Y7 Y10 Y11 ... - UV channel output U2 V3 U6 V7 U10 V11 ... - Every line output data number is half (176 pixels) and only one half line data (every other line, total 144 line) in one frame will be output.
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Table 9. RGB Raw Data Format
Advanced Information Preliminary
SINGLE IC CMOS COLOR AND B/W DIGITAL CAMERAS
R\C
1 2 3 4 5 . 289 290 291 292
Notes:
1
B11 G21 B31 G41 B51
2
G12 R22 G32 R42 G52
3
B13 G23 B33 G43 B53
4
G14 R24 G34 R44 G54
.
353
B G B G B
354
G R G R G
355
B G B G B
356
G R G R G
B G B G
G R G R
B G B G
G R G R
B G B G
G R G R
B G B G
G R G R
A. Y port output data sequence: G R G R G R ... or G G G G ... ; UV port output data sequence: B G B G B G ... or B R B R ... ; Array Color Filter Patter is Bayer-Pattern B. Output Modes 16-bit Format (HREF total 292) Default mode: - 1st HREF Y channel output unstable data, UV output B11 G12 B13 G14 .... - 2nd HREF Y channel output G21 R22 G23 R24 ..., UV output B11 G12 B13 G14 ... - 3rd HREF Y channel output G21 R22 G23 R24 ..., UV output B31 G23 B33 G34 .... - Every line of data is output twice. YG mode: - 1st HREF Y and UV output unstable data. - 2nd HREF Y channel output G21 G12 G23 G14 ..., UV output B11 R22 B13 R24 ... - 3rd HREF Y is G21 G32 G23 G34 ..., UV channel is B31 R 22 B33 R24 ... - Every line data output twice. One line mode: - 1st HREF Y channel output B11 G12 B13 G14 ..., - 2nd HREF Y channel output G21 R22 G23 R24 ..., - UV channel tri-state. 8-bit Format (HREF total 292) - 1st HREF Y channel output unstable data. - 2nd HREF Y channel output B11 G21 R22 G12 ... - 3rd HREF Y channel output B31 G21 R22 G32 ..., etc. - PCLK timing is double and PCLK rising edge latch data bus. UV channel tri-state. Every line data output twice. 4-bit Nibble Mode Output Format - Uses higher 4 bits of Y port (Y[7:4]) as output port. - Supports YCrCb/RGB data, CCIR601/CCIR656 timing, Color/B&W. - Output sequence: High order 4 bits followed by lower order 4 bits Y0h Y0l Y1h Y1l ... U0h U0l V0h V0l ... For B/W or one-line RGB raw data, the output data clock speed is doubled. For color YUV, output clock is four times that of the 16-bit output data. In color mode, sensor must be set to 8-bit mode, and the nibble timing, clock divided by 2. - Output sequence: U0h U0l Y0h Y0l V0h V0l Y1h Y1l ...
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SINGLE IC CMOS COLOR AND B/W DIGITAL CAMERAS
The OV6620/OV6120 sensors can be programmable to operate in slave mode configuration (COMI[6] = 1, default is master mode). HSYNC and VSYNC output signals are provided. When used as a slave device, the external master must provide the OV6620/OV6120 imager with the following: 1. System clock CLK to XCLK1 pin; 2. Horizontal sync, Hsync, to CHSYNC pin, positive assertion; 3. Vertical frame sync, Vsync, to VSYNC pin, positive assertion When in slave mode, the OV6620/OV6120 tri-states CHSYNC (pin 42) and VSYNC (pin 16) output pins, which may then be used as input pins. To synchronize multiple devices, the OV6620/OV6120 image sensors use external system clock, CLK, to synchronize external horizontal sync, HSYNC, which is then used to synchronize external vertical frame sync, Vsync. See Figure 5, Slave Mode External Sync Timing for timing considerations.
pulled high (Vcc). When a hardware reset occurs, the OV6620/OV6120 sensor clears all registers or sets them to their default values. Reset may also be initiated through the I2C interface.
1.2.10 Power Down Mode
Two methods are available for placing the OV6620/ OV6120 devices into power-down mode: hardware power down and I2C/software power down. To initiate hardware power down the PWDN pin (pin 9) must be tied to high (+5VDC). When this occurs, the OV6620/OV6120 internal device clock is halted and all internal registers (except I2C registers) are reset. In this mode, current draw is less than 10uA. Executing a software power down through the I2C interface suspends internal circuit activity, but does halt the device clock. In this mode, current requirements drop to less than 1mA.
1.2.11 Configuring the OV6620/OV6120 Image Sensors
Two methods are provided for configuring the OV6620/ OV6120 IC for specific application requirements. At power up, the OV6620/OV6120 sensor reads the status of certain pins to determine what, if any, power up default settings are requested. Once the reading of the external pins is completed, the device configures its internal registers according to the specified pins. Not all device functions are available for configuration through external pin. A more flexible and comprehensive method for configuring the OV6620/OV6120 IC is to use its on-chip I2C register programming capability. The I2C interface provides access to all of the device's programmable internal registers. See Section 3.1 I2C Bus Protocol Format for further details about using the I2C interface on the OV6620/OV6120 camera device.
1.2.8
Frame Exposure Mode
The OV6620/OV6120 sensors support frame exposure mode when programmed for Progressive Scan. FREX (pin 4) is asserted by an external master device to set exposure time. When FREX = 1, the OV6620/OV6120 pixel array will be quickly precharged. Based on the external master's assertion of FREX, the OV6620/OV6120 devices capture the image. When the master de-asserts FREX (FREX = 0), the video output data stream is delivered to the OV6620/OV6120 output port in a line-by-line manner. It should be noted that FREX must active long enough to ensure the complete image array has been precharged. When data is being output from the OV6620/OV6120 image sensor, care must be taken so as not to expose the image array to light. This may affect the integrity of the image data captured. A mechanical shutter synchronized with the frame exposure rate can be used to minimize this situation. Frame exposure mode timing is shown in Section Figure 6. Frame Exposure Timing below.
1.2.9
Reset
The OV6620/OV6120 image sensor includes a RESET pin (pin 2) which forces a complete hardware reset when
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Tclk CLK Ths
Hsync
1 line=472 * Tclk Vsync Tvs 1 frame = 625 * 472 * Tclk
Notes: 1. Ths > 6 * Tclk (2) Ths < Tvs < 472 * Tclk 2. Hsync period is 472 * CLK 3. Vsync period is 625 * 472 * CLK 4. OV6620 will be stable after 1 frame. (2nd Vsync).
Figure 5. Slave Mode External Sync Timing
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Tset FREX Tin HSYNC
Mechanical shutter off Ths
Precharge begin at rising edge of HSYNC ARRAY PRECHARGE Array Exposure Period Tex Array Precharge period Tpr DATA OUTPUT Invalid Data Head of Valid data (8 line) Next Frame 1 Frame (292 line) Valid Data Black Data
Thd VSYNC
HREF
Note: Tpr = 292* 4 * Tclk, Tclk is internal pixel period. For default 17.73 MHz, Tclk=112 us. If CLK[5:0] set to divided number, Tclk will increase accordingly. Tex is array exposure time which is decided by external master device. Tin is uncertain time due to using HSYNC rising edge synchronize FREX, Tin < Ths After FREX=0, there are 8 line data output before valid data output. Thd = 4 * Ths. Valid data is output when HRE Tset = Tin + Tpr + Tex. Tset > Tpr + Tin. Because Tin is uncertain, so exposure time setting resolution is Ths (one line).
Figure 6. Frame Exposure Timing
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2. Electrical Characteristics
Table 10. DC Characteristics (0oC < TA < 85oC, Voltages referenced to GND)
Symbol
Supply VDD1 VDD2 IDD1 IDD2
Descriptions
Max
Typ
Min
Units
Supply voltage- internal analog (DEVDD,ADVDD,AVDD,SVDD,AOVDD,DVDD) Supply voltage - internal digital &output digital (DOVDD) Supply Current (@ 50Hz frame rate & 5 volt digital I/O,25pf + 1TTL load on 16 bit data bus) Standby supply current
5.25 5.5 3.6 40 10
5.0 5.0 3.3 5
4.75 4.5 3.0 -
V V V mA uA
Digital Inputs VIL VIH Cin input voltage LOW input voltage HIGH input capacitor 0.8 10 2.0 V V pF
Digital Outputs - standard load 25pf, 1.2k to 3.0volts VOH VOL output voltage HIGH output voltage LOW 0.6 2.4 V V
I2C Inputs - 5k pull up + 100pf VIL VIH VIL VIH SDA and SCL (VDD2=5V) SDA and SCL(VDD2=5V) SDA and SCL (VDD2=3V) SDA and SCL(VDD2=3V) 1.5 Vdd + .5 1 3.5 0 5 0 3 -0.5 3.0 -0.5 2.5 V V V
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Table 11. AC Characteristics (TA=25oC; Vdd=5V)
Symbol
RGB/YCrCb output
Descriptions
Max
Typ
Min
Units
Iso Vy
maximum sourcing current DC level at zero signal Y peak-peak 100% amplitude (without sync) sync amplitude
15 1.2 1 0.4
mA V V V
ADC parameters
B diff DLE ILE
analog bandwidth
MHz
DC differential linearity error DC integral linearity error
0.5 1
LSB LSB
Table 12. Timing Characteristics
Symbol
Oscillator & Clock in fosc tr , tf
Descriptions
Max
Typ
Min
Units
frequency (XCLK1,XCLK2) clock input rise/fall time clock input duty cycle
30 5 55
17.734
10
MHz ns
50
45
%
I2C timing(400kbit/s) tBUF tHD:SAT tLOW tHIGH tHD:DAT tSU:DAT tSU:STP Bus free time between STOP & START SCL change after START status SCL low period SCL high period Data hold time Data set-up time Set-up time for STOP status 1.3 0.6 1.3 0.6 0 0.1 0.6 ms s s s s s s
Digital timing tpclk PCLK cycle time 16 bit operation 8 bit operation Version 1.11 112 56 ns ns 19
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Table 12. Timing Characteristics
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SINGLE IC CMOS COLOR AND B/W DIGITAL CAMERAS
Symbol
tr,tf tpdd tphd
Descriptions
PCLK rise/fall time PCLK to data valid PCLK to HREF delay
Max
15 15 20
Typ
10
Min
5
Units
ns ns ns
Table 13. Zoom Video Port AC Parameters
Symbol
t1 t2 t3 t4 t5 t6 t7 t8
Notes:
Parameter
PCLK fall timing PCLK low time PCLK rise time PCLK high time PCLK period Y/UV/HREF setup time Y/UV/HREF hold time VSYNC setup/hold time to HREF 4 ns
Min.
Max.
8 ns
50 ns 4 ns 50 ns 106 ns 10 ns 20 ns 1 us 8 ns
1. In Interlaced Mode, there are Even/Odd field different (t8). When In Progressive Scan Mode, only frame timing same as Even field(t8). 2. After VSYNC falling edge, OV6620 will output black reference level, the line number is Tvs, which is the line number between the 1st HREF rising edge after VSYNC falling edge and 1st valid data CHSYNC rising edge. Then valid data, then black reference, line number is Tve, which is the line number between last valid data CHSYNC rising edge and 1st CHSYNC rising edge after VSYNC rising edge. The black reference output line number is dependent on vertical window setting. 3. When in default setting, Tvs = 14 * Tline, which is changed with register VS[7:0]. VS[7:0] step equal to 1 line. 4. When in default setting, Tve = 4 * Tline for Odd Field, Tve = 3 * Tline for Even Field, which is changed with register VE[7:0]. VE[7:0] step equal to 1 line.
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0.440 0.005 31 0.040 0.003 42
+0.010 0.060 -0.005 TYP. 0.040 0.007 TYP. 43
30
48
Bottom View
0.020 0.003 TYP. 19 6
R 0.0075 18 4 CORNERS
R 0.0075 48 PLCS
7
0.085 0.010 0.003 0.065 0.007 0.002 0.030 0.003 0.015 0.002 0.020 0.002
0.003 +0.012 0.560 SQ. -0.005 0.430 SQ. 0.005 0.350 SQ. 0.005
0.036 MIN.
42
31 31 30
43 43
42
30
Side View
48 1
6
6 7 7 0.006 MAX. 0.002 TYP. 18
19
19
Top View
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Array Center (10.9 mil, 13.2 mil) (276.9 m, 335.3 m) 1
DIE
Sensor Array
Package Center (0, 0)
Figure 7. OV6620/OV6120 Package Outline
Table 14. Ordering Information
Part Number OV6620 OV6120 COLOR Image Sensor, CIF, Digital, B/W Image Sensor, CIF, Digital, I2 C Description I2C Bus Control Bus Control Package 48 pin LCC 48 pin LCC
OmniVision Technologies, Inc. reserves the right to make changes without further notice to any product herein to improve reliability, function, or design. OmniVision Technologies, Inc. does not assume any liability arising out of the application or use of any product or circuit described herein; neither does it convey any license under its patent rights nor the rights of others. No part of this publication may be copied or reproduced, in any form, without the prior written consent of OmniVision Technologies, Inc.
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3. I2C Bus Many of the functions and configuration registers in the OV6620/OV6120 image sensors are available through the I2C interface. The I2C port is enabled by asserting the I2CB line (pin 12) through a 10K ohm resistor to
Advanced Information Preliminary
SINGLE IC CMOS COLOR AND B/W DIGITAL CAMERAS
VDD. When the I2C capability is enabled (I2CB = 1), the OV6620/OV6120 imager operates as a slave device that supports up to 400 kbps serial transfer rate using a 7-bit address/data transfer protocol .
1ST BYTE
2ND BYTE
3RD BYTE
S
SLAVE ID (7 BITS) RW A
SUBADDRESS (8 BITS) A
DATA (8 BITS)
A
P
MSB START
LSB=0
ACK
ACK STOP
MASTER TRANSMIT, SLAVE RECEIVE (WRITE CYCLE)
1ST BYTE
2ND BYTE
S
SLAVE ID (7 BITS) RW A
SUBADDRESS (8 BITS) A
P
MSB START
LSB=0
ACK STOP
MASTER TRANSMIT, SLAVE RECEIVE (DUMMY WRITE CYCLE)
1ST BYTE
2ND BYTE
3RD BYTE
S
SLAVE ID (7 BITS) RW A
DATA (8 BITS)
A
DATA (8 BITS)
1
P
MSB START
LSB=1
ACK
STOP NO ACK IN LAST BYTE
MASTER RECEIVE, SLAVE TRANSMIT (READ CYCLE)
SLAVE ID - 110CCC0X CS2 (PIN 35) CS1 (PIN 37) CS0 (PIN 34) X - RW BIT, 1: READ, 0:WRITE
S - START CONDITION A - ACKNOWLEDGE BIT P - STOP CONDITION
- SLAVE TRANSMIT - MASTER TRANSMIT - MASTER INITIATE
Figure 8. I2C Bus Protocol Format
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3.1 I2C Bus Protocol Format
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In I2C operation, the master must perform the following operations:
n Generate the start/stop condition n Provide the serial clock on SCL n Place the 7-bit slave address, the RW bit, and the 8-bit subaddress on SDA
The receiver must pull down SDA during the acknowledge bit time. During the write cycle, the OV6620/ OV6120 device returns the acknowledgment and, during read cycle, the master returns the acknowledgment except when the read data is the last byte. If the read data is the last byte, the master does not perform an acknowledge, indicating to the slave that the read cycle can be terminated. Note that the restart feature is not supported here. Within each byte, MSB is always transferred first. Read/write control bit is the LSB of the first byte.
Standard I2C communications require only two pins: SCL and SDA. SDA is configured as open drain for bidirectional purpose. A HIGH to LOW transition on the SDA while SCL is HIGH indicates a START condition. A LOW to HIGH transition on the SDA while SCL is HIGH indicates a STOP condition. Only a master can generate START/STOP conditions. Except for these two special conditions, the protocol that SDA remain stable during the HIGH period of the clock, SCL. Each bit is allowed to change state only when SCL is LOW (See Figure 9. Bit Transfer on the I2C Bus and Figure 10. Data Transfer on the I2C Bus below). The OV6620/OV6120 I2C supports multi-byte write and multi-byte read. The master must supply the subaddress. in the write cycle, but not in the read cycle.
SDA DATA STABLE SCL DATA CHANGE ALLOWED
Figure 9. Bit Transfer on the I2C Bus I
RW SDA SLAVE ID SUB ADD A DATA A
A
SCL S P
Figure 10. Data Transfer on the I2C Bus
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byte cycle, you must insert a single byte write cycle that provides a new subaddress. The OV6620/OV6120 imager can be programmed to one-of-eight slave ID addresses. Function pins CS[2:0] pins 35, 37, 34, respectively).
Therefore, the OV6620/OV6120 sensor takes the read subaddress from the previous write cycle. In multi-byte write or multi-byte read cycles, the subaddress is automatically increment after the first data byte so that continuous locations can be accessed in one bus cycle. A multi-byte cycle overwrites its original subaddress; therefore, if a read cycle immediately follows a multiTable 15. Slave ID Addresses
CS[2:0]
WRITE ID (hex) READ ID (hex)
000
C0 C1
001
C4 C5
010
C8 C9
011
CC CD
100
D0 D1
101
D4 D5
110
D8 D9
111
DC DD
The OV6620/OV6120 sensors support both single chip and multiple chip configurations. By asserting MULT (pin 47) high, the sensor can be programmed for up to 8 slave ID addresses. Asserting MULT low configures the OV6620/OV6120 imagers for single ID slave address with address C0 for writes and address C1 for reads. MULT is internally defaulted to a low condition. In the write cycle, the second byte in I2C bus is the subaddress for selecting the individual on-chip registers, Table 16. I2C Registers
Subaddress (hex) Register Default (hex) Read/ Write Descriptions
and the third byte is the data associated with this register. Writing to unimplemented subaddress is ignored. In the read cycle, the second byte is the data associated with the previous stored subaddress. Reading of unimplemented subaddress returns unknown. 3.2 Register Set
The table below provides a list and description of available I2C registers contained in the OV6620/OV6120 image sensor.
00
Gain[6:0]
00
RW
AGC Gain Control GC[7:6] - unimplemented bit, returns `X' when read. GC[5:0] - Storage for the current AGC Gain setting. This register is updated automatically. If AGC is enabled, the internal control stores the optimal gain value in this register. IF AGC is not enabled, a "00" is stored in this register.
01
Blue[7:0]
80
RW
Blue Gain Control BLU[7] - "0" decrease gain, "1" increase gain. BLU[6:0] - blue channel gain balance value. Red Gain Control RED[7] - "0" decrease gain, "1" increase gain. RED[6:0] - red channel balance value. Saturation Control SAT[7:0] - saturation adjustment. "FFh"- highest, "00h"-lowest reserved Contrast Control CTR[7:0] - contrast adjustment. "FFh"-highest, "00h"-lowest Brightness Control BRT[7:0] - brightness adjustment. "FFh"-highest,"00h"-lowest Sharpness Control SHP[7:4] - Threshold of sharpness. Range: 0~80mV, Step: 5 mV SHP[3:0] - Sharpness control. Range: 0 ~ 8x, Step: 0.5x reserved reserved reserved reserved
02 03 04 05 06 07 08 09 0A 0B
Red[7:0] Sat Rsvd04 Cnt Brt Sharpness Rsvd08 Rsvd09 Rsvd0A Rsvd0B
80 80 XX 48 80 C6 XX XX XX XX
RW RW RW RW RW -
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Subaddress (hex) Register Default (hex) Read/ Write
Advanced Information Preliminary
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Descriptions
White Balance Background: Blue Channel ABLU[7:6] - rsvd ABLU[5] - Sign bit. "0" - decrease background blue component "1" - increase background blue component ABLU[4:0] - White balance blue ratio adjustment White Balance Background: Red Channel ARED[7:6] - rsvd ARED[5] - Sign bit. "0" - decrease background red component "1" - increase background red component ABLU[4:0] - White balance red ratio adjustment Common Control R COMR[7] - Analog signal 2x gain control bit. "1" - Additional 2x gain, "0" - normal COMR[6:0] - Reserved Common Control S COMS[7:6] - Reserved COMS[5:4] - Black expanding level "00" - 1.2V, "01" - 1.26V, "10" - 1.3V, "11" - 1.4V COMS[3:2] - Set high threshold level "00" - 1.9V, "01" - 2.0V, "10" - 2.1V, "11" - 2.2V COMS[1:0] - Set low threshold level "00" - 1.3V, "01" - 1.45V, "10" - 1.5V, "11" - 1.6V Automatic Exposure Control AEC[7:0] - Set exposure time Interlaced: Tex = Tline x AEC[7:0] Progressive: Tex = Tline x AEC[7:0] x 2 Clock Rate Control CLKRC[7:5] - Sync output polarity selection "00" - HSYNC=Neg, CHSYNC=Neg, VSYNC=Pos "01" - HSYNC=Neg, CHSYNC=Neg, VSYNC=Neg "10" - HSYNC=Pos, CHSYNC=Neg, VSYNC=Pos "11" - HSYNC=Pos, CHSYNC=Pos, VSYNC=Pos CLKRC[5:0] - Clock prescaler CLK = (CLK_main / ((CLKRC[5:0] + 1) x 2)) / 2 Common Control A COMA[7] - SRST, "1" initiates soft reset. Initiate soft reset. All registers are set to default values and chip is reset to known state and resumes normal operation. This bit is automatically cleared after reset. COMA[6] - MIRR, "1" selects mirror image COMA[5] - VSFR, "1" enables AGC, COMA[4] - Digital output format, "1" selects 8-bit: Y U Y V Y U Y V COMA[3] - Select video data output: "1" - select RGB, "0" - select YCrCb COMA[2] - Auto White Balance "1" - Enable AWB, "0" - Disable AWB COMA[1] - Color Bar Test Pattern: "1" - Enable color bar test pattern COMA[0] - reserved Common Control B COMB[7] - reserved COMB[6] - reserved COMB[5] - Select data format. "1" - Select 8-bit format, Y/CrCb and RGB is multiplexed to 8-bit Y bus, UV bus is tri-stated, "0" - Select 16-bit format COMB[4] - "1" - enable digital output in CCIR656 format COMB[3] - CHSYNC output: "1" - Horizontal sync, "0" - composite sync COMB[2] - "1" - Tristate Y and UV busses. "0" - enable both busses COMB[1] - "1" - Initiate single frame transfer COMB[0] - "1" - Enable auto adjust mode Common Control C COMC[7] - reserved COMC[6] - reserved COMC[5] - QCIF digital output format selection. 1 - 176x144; 0 - 352x288. COMC[4] - Field/Frame vertical sync output in VSYNC port selection: 1 - frame sync, only ODD field vertical sync; 0 - field vertical sync, effect in Interlaced mode COMC[3] - HREF polarity selection: 0 - HREF positive effective, 1 - HREF negative. COMC[2] - gamma selection: 1 - RGB Gamma on ; 0 - gamma is 1. COMC[1] - reserved COMC[0] - reserved
0C
AWB - Blue
20
R/W
0D
AWB - Red
20
R/W
0E
COMR
0D
RW
0F
COMS
05
RW
10
AEC
9A
R
11
CLKRC
00
R
12
COMA
24
RW
13
COMB
01
RW
14
COMC
00
RW
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Subaddress (hex) Register Default (hex) Read/ Write
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Descriptions
Common Control D COMD[7] - reserved bit. COMD[6] - PCLK polarity selection. "0" OV6620 output data at PCLK falling edge and data bus will be stable at PCLK rising edge; "1" rising edge output data and stable at PCLK falling edge. When OV6620 work as CCIR656 format, COMB4=1, this bit is disable and should use PCLK rising edge latch data bus. COMD[5:1] - reserved bit. COMD[0] - U V digital output sequence exchange control. 1 - UV UV ... for 16-bit, U Y V Y ... for 8-bit; 0 - V U V U ... for 16Bit and V Y U Y ... for 8 Bit. Field Slot Division FSD[7:2] - Field interval selection. Odd Even mode defined by FD[1:0] 000000 - disable digital data output, only output black reference level. 000001 - divide to 2 slots, HREF is active one in every 2 field/frame 000010 - divide to 4 slots, HREF is active one in every 4 field/frame 000100 - divide to 8 slots, HREF is active one in every 8 field/frame 001000 - divide to 16 slots, HREF is active one in every16 field/frame 010000 - divide to 32 slots, HREF is active one in every 32 field/frame 100000 - divide to 64 slots, HREF is active one in every 64field/frame FSD[1:0]- field mode selection. Each frame consists of two fields: Odd & Even, these bits defines the assertion of HREF in relation to the two fields. 00 - OFF mode; HREF is not asserted in both fields, one exception is the single frame transfer operation (see the description for the register 13) 01 - ODD mode; HREF is asserted in odd field only. 10 - EVEN mode; HREF is asserted in even field only. 11 - FRAME mode; HREF is asserted in both odd field and even field. FD[7:2] useless. Horizontal HREF Start HS[7:0] - selects the starting point of HREF window, each LSB represents two pixels for CIF resolution mode, one pixels for QCIF resolution mode, this value is set based on an internal column counter, the default value corresponds to 352 horizontal window. Maximum window size is 356. see window description below. HS[7:0] programmable range is [38]- [EB], and should less than HE[7:0]. HS[7:0] should be programmable to value larger than or equal to [38]. Value larger than [EC] is invalid. See window description below. Horizontal HREF End HE[7:0] - selects the ending point of HREF window, each LSB represents two pixels for full resolution and one pixels for QCIF resolution, this value is set based on an internal column counter, the default value corresponds to the last available pixel. The HE[7:0] programmable range is [39] - [EC]. HE[7:0] should be larger than HS[7:0] and less than or equal to [EC]. Value larger than [EC] is invalid. See window description below. Vertical Line Start VS[7:0] - selects the starting row of vertical window, in full resolution mode, each LSB represents 1 scan line in one frame. see window description below. Min. is [03], max. is [93] and should less than VE[7:0]. Vertical Line End VE[7:0]- selects the ending row of vertical window, in full resolution mode, each LSB represents 1 scan line in one frame, see window description below. Min. is [04], max. is [94] and should larger than VS[7:0]. Pixel Shift PS[7:0] - to provide a way to fine tune the output timing of the pixel data relative to that of HREF, it physically shifts the video data output time late in unit of pixel clock as shown in the figure below. This function is different from changing the size of the window as is defined by HS[7:0] & HE[7:0] in register 17&18. Higher than default number shifts the pixel in delay(right) direction, the highest number is "FF". so maximum shift number is: Late: 256 pixels. Manufacture ID Byte: High MIDH[7:0] - read only, always returns "7F" as manufacturer's ID no. Manufacture ID Byte: Low MIDL[7:0] - read only, always returns "A2" as manufacturer's ID no. reserved reserved
15
COMD
01
RW
16
FSD
03
RW
17
HREFST
38
RW
18
HREFEND
EA
RW
19
VSTRT
03
RW
1A
VEND
92
RW
1B
PSHFT
00
RW
1C 1D 1E 1F
MIDH MIDL Rsvrd1E Rsvrd1F
7F A2 C4 04
R R R R
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Subaddress (hex) Register Default (hex) Read/ Write
Advanced Information Preliminary
SINGLE IC CMOS COLOR AND B/W DIGITAL CAMERAS
Descriptions
Common Control E COME[7] - HREF pixel number selection. "1" - HREF include 704 PCLK, every data output twice. COME[6] - reserved. COME[5] - "1" First stage aperture correction enable. Correction strength will be decided by register [07]. "0" disable first stage aperture correction. COME[4] - "1" Second stage aperture correction enable. Correction strength and threshold value will be decided by COMF[7] ~ COMF[4]. COME[3] - AWB smart mode enable. 1 - Drop out pixel when compare pixel red, blue and green component level to change register [01] and [02], which luminance level is higher than presetting level and lower than presetting level, this two level is set by register [0F]. 0 - calculate all pixels to get AWB result. Valid only when COMB[0]=1 and COMA[2]=1 COME[2] - AWB stop when field/frame image average luminance level is lower than a presetting level enable. 1 - enable stop AWB when image luminance level is low. 0 - AWB is independent with field/frame luminance level. Valid only when COMB0=1 and COMA[2]=1. Average compare level is set by GAM[7:5]. COME[1] - AWB fast/slow mode selection. "1" - AWB is always fast mode, that is register [01] and [02] is changed every field/frame. "0" AWB is slow mode, [01] and [02] change every 16/ 64 field/frame decided by COMK[1]. When AWB enable, COMA[2]=1, AWB is working as fast mode at first 1024 field/frame, than as slow mode later. COME[0] - Digital output driver capability increase selection: "1" Double digital output driver current; "0" low output driver current status. Y Channel Offset Adjustment YOFF[7] - Offset adjustment direction 0 - Add Y[6:0]; 1 -Substrate Y[6:0]. YOFF[6:0] -Y channel digital output offset adjustment. Range: +127mV ~ -127mV. If COMG[2]=0, this register will be updated by internal auto A/D BLC circuit, and write a value to this register with I2C has no effect. If COMG[2]=1, Y channel offset adjustment will use the register stored value which can be changed by I2C. If COMF[1]=0, this register has no adjustment effect to A/D output data. If output RGB raw data, this register will adjust R/G/B data. U Channel Offset Adjustment UOFF[7]: - Offset adjustment direction: 0 - Add U[6:0]; 1 -Substrate U[6:0]. UOFF[6:0] - U channel digital output offset adjustment. Range: +128mV ~ -128mV. If COMG[2]=0, this register will be updated by internal auto A/D BLC circuit, and write a value to this register with I2C has no effect. If COMG[2]=1, U channel offset adjustment will use the register stored value which can be changed by I2C. If COMF[1]=1, this register has no effect to A/D output data. If output RGB raw data, this register will adjust R/G/B data. Reference Control REFC[7:6] - Select different crystal circuit power level (11 = minimum). REFC[5:4] - reserved REFC[3:0]: Reference Voltage range selection. 2.5V - 3.5V and step is 0.0625V. Automatic Exposure Control: Bright Pixel Ratio Adjustment AEW[7:0] - Used as calculate bright pixel ratio. OV6620 AEC algorithm is count whole field/ frame bright pixel (its luminance level is higher than a fixed level) and black pixel (its luminance level is lower than a fixed level) number. When bright/black pixel ratio is same as the ratio defined by register [25] and [26], image stable. This register is used to define bright pixel ratio, default is 25%, each LSB represent step: 1.3% Change range is: [01] ~ [CA]; Increase AEW[7:0] will increase bright pixel ratio. For same light condition, the image brightness will increase if AEW[7:0] increase. Note: AEW[7:0] must combine with register [26] AEB[7:0]. The relation must be as follows: AEW[7:0] + AEB[7:0] > [CA]. Automatic Exposure Control: Black Pixel Ration Adjustment AEB[7:0] - used as calculate black pixel ratio. OV6620 AEC algorithm is count whole field/ frame bright pixel (its luminance level is higher than a fixed level) and black pixel (its luminance level is lower than a fixed level) number. When bright/black pixel ratio is same as the ratio defined by register [25] and [26], image stable. This register is used to define black pixel ratio, default is 75%, each LSB represent step: 1.3%; Change range is: [01] ~ [CA]; Increase AEB[7:0] will increase black pixel ratio. For same light condition, the image brightness will decrease if AEB[7:0] increase. Note: AEB[7:0] must e combined with register [25] AEW[7:0]. The relation must be as follows: EW[7:0] + AEB[7:0] > [CA].
20
COME
00
RW
21
YOFF
80
RW
22
UOFF
80
RW
23
REFC
04
RW
24
AEW
33
RW
25
AEB
97
RW
28
Version 1.11
14 May 1999
OMNIVISION TECHNOLOGIES, Inc. OV6620/OV6120
Subaddress (hex) Register Default (hex) Read/ Write
Advanced Information Preliminary
SINGLE IC CMOS COLOR AND B/W DIGITAL CAMERAS
Descriptions
Common Control F COMF[7:6] - Second aperture correction threshold selection. [00] - Difference of neighbor pixel luminance is larger than 8 mV, correction on. [01] - 16 mV. [10] - 32 mV. [11] - 64 mV. COMF[5:4] - Second aperture correction strength selection. [00] and [01] - Strength is 50% of difference of neighbor pixel luminance. [10] - 100%. [11] - 200%. COMF[3] - UV BLC swap. "1" swap; "0" no swap. COMF[2] - Digital data MSB/LSB swap. "1" LSB->Bit7, MSB->Bit0; "0" normal. COMF[1] - "1" A/D Black level calibration enable. "0" Disable A/D BLC. COMF[0] - "1" Output first 4 line black level before valid data output. HREF number will increase 4 relatively. "0" no black level output. Common Control G COMG[7] - reserved COMG[6] - reserved. COMG[5] - Select CKOUT pin output V flag. 1 - CKOUT output V flag signal. CKOUT=1, means related UV channel output V component (or Red component), CKOUT=0 pointed to U component (or Blue component). 0 - CKOUT output buffered XCLK2 COMG[4] - reserved. COMG[3] - reserved COMG[2] - "1" A/D offset adjustment manually mode enable: 1 - A/D data will be add/substrate a value defined by register [21] and [22], which content is written by I2C. 0 - A/D data will be added/substrate a value defined by register [21] and [22], which is updated by internal circuit. COMG[1] - Digital output full range selection. OV6620 output data value range is [10] - [F0], if COMG[1] -1, range change to [01] - [FE] with signal overshoot and undershoot level. COMG[0] - reserved. Common Control H COMH[7]: - "1" selects One-Line RGB raw data output format, "0" selects normal two-line RGB raw data output, effective only in Progressive Scan mode. COMH[6]: - "1" enable Black/White mode. When OV6620 working as BW camera, its vertical resolution will be higher than color mode. At this mode, can't set OV6620 working at 8 bit output mode. OV6620 output data YUV/RGB from Y port. UV port will be tri-state. COMB[5] and COMB[4] will be set to "0". "0" normal color mode. COMH[5]: - reserved. COMH[4]: - Freeze AEC/AGC value, effective only when COMB0=1. "1" - register [00] and [10] will not be updated and hold latest value. "0" - AEC/AGC normal working status. COMH[3]: - AGC disable. 1 - when COMB[0]=1 and COMA[5]=1, internal circuit will not update register [00], register [00] will kept latest updated value before COMH[3]=1. 0 - when COMB0=1 and COMA[5]=1, register [00] will be updated by internal algorithm. COMH[2]: - RGB raw data output YG format: 1 - Y channel G, UV channel B R; 0 - Y channel: G R G R..., UV channel B G B G.... COMH[1]: - Gain control bit. "1" Double PreAmp gain to 12dB. "0" PreAmp gain is 6dB. COMH[0]: - High gain mode. "1" - AGC maximum gain is 24dB. AGC step is 1/8. "0" AGE maximum gain is 18dB, AGC step is 1/16. Only effective when COMB[0]=1, COMA[5]=1 and COMH[3]=0. Common Control I COMI[7]: - AEC disable. "1" If COMB[0]=1, AEC stop and register [10] value will be held at last AEC value and not be updated by internal circuit. "0" - if COMB[0]=1, register [10] value will be updated by internal circuit COMI[6]: - Slave mode selection. "1" slave mode, use external Sync and Vsync; "0" master mode COMI[5]: - reserved COMI[4]: - reserved COMI[3]: - Central 1/4 image area rather whole image used to calculate AEC/AGC. "0" use whole image area to calculate AEC/AGC. COMI[2]: - reserved COMI[1:0] - Version flag. For Version A, value is [00], these two bits can only be read. Frame Rate Adjust High FRARH[7] - Frame Rate adjustment enable bit. "1" Enable. FRARH[6] - reserved FRARH[5] - Highest 1bit of frame rate adjust control byte. see explanation below. FRARH[4] - reserved FRARH[3] - Y channel brightness adjustment enable. When COMF[2]=1 active. FRARH[2] - reserved FRARH[1] - "1" When in Frame exposure mode, only One frame data output. FRARH[0] - reserved
26
COMF
B0
RW
27
COMG
A0
RW
28
COMH
01
RW
29
COMI
00
RW
2A
FRARH
84
RW
14 May 1999
Version 1.11
29
OMNIVISION TECHNOLOGIES, Inc. OV6620/OV6120
Subaddress (hex)
2B 2C
Advanced Information Preliminary
SINGLE IC CMOS COLOR AND B/W DIGITAL CAMERAS
Register
Default (hex)
Read/ Write
Descriptions
Frame Rate Adjust Low FRARL[7:0] - Lowest 8 bit of frame rate adjust control byte. Frame rate adjustment resolution is 0.21%. Control byte is 10 bit. Every LSB equal decrease frame rate 0.21%. Range is 0.21% - 109%. IF frame rate adjustment enable, COME7 must set to "0". reserved Common Control J COMJ[7:5] - reserved COMJ[4] - Enable auto black expanding mode. COMJ[3] - "1" = White Balance update when AGC/AEC stable. "0" = White Balance register update independent with AEC/AGC. COMJ[2] - Band filter enable. After adjust frame rate to match indoor light frequency, this bit enable a different exposure algorithm to cut light band induced by fluorescent light. COMJ[1] - reserved COMJ[0] - A/D U and V BLC separate mode. "1" = U and V offset cancelled by different register. "0" = U V offset cancelled by one common register [2E]. V Channel Offset Adjustment VCOFF[7]: Offset adjustment direction: "0" = Add V[6:0]; "1" = Substrate V[6:0]. VCOFF[6:0] - V channel digital output offset adjustment. Range: +128mV ~ -128mV. If COMG[2]=0, this register will be updated by internal auto A/D BLC circuit, and write a value to this register with I2C has no effect. If COMG[2] =1, V channel offset adjustment will use the register stored value which can be changed by I2C. If COMF[1] =1, this register has no effect to A/D output data. If output RGB raw data, this register will adjust R/G/B data. Reserved Color Processing Parameter Control CPP[7:6] - reserved CPP[5] - Luminance gamma on/off. "1" - luminance gamma on; "0" - luminance gamma is 1. CPP[4:0] - reserved Bias Adjustment BIAS[7:6] - A/D reference level adjustment. [00] - 110% internal full signal range; [01] - 120%, [10] - 130%, [11] - 140%. BIAS[5:0] - reserved reserved reserved reserved Common Control K COMK[7] - HREF edge latched by PCLK falling edge (When COMD[6] = 0). "0" HREF edge is 10 ns after PCLK rising edge. COMK[6] - Output port drive current additional 2x control bit. COMK[5] - reserved. COMK[4] - ZV port Vertical timing selection. "1" VSYNC output ZV port vertical sync signal. "0" = normal TV vertical sync signal. COMK[3] - Quick stable mode when camera mode change. After relative control bit set, the first VS will be the stable image with suitable AEC/AWB setting. "0" - slow mode, after mode change need more field/frame to get stable AEC/AWB setting image. COMK[2] - reserved COMK[1] - AWB stable time selection when in slow mode. "1" - 4 times less time needed to get stable AWB setting when in slow AWB mode. COMK[0] -reserved. Common Control L COML[7] - reserved COML[6] - PCLK output timing selection. 1 -- PCLK valid only when HREF is high; 0 -- PCLK is free running. COML[5] - Vertical sync selection, 1 -- Same period between 1st HREF and VS falling edge in two field; 0 - Different timing period between 1st HREF and VS falling edge COML[4] - "1" select CHSYNC output from HREF port. "0" normal COML[3] - "1" select HREF output from CHSYNC port. "0" normal COML[2] - Tristate all control signal output (FODD, CHSYNC, HREF, PCLK) COML[1] - Highest 1 bit of horizontal sync starting position, combined with register [3A] COML[0] - Highest 1 bit of horizontal sync ending position, combined with register [3B] Horizontal Sync Start Position HSST[7:0] - lower 8 bit of horizontal sync starting position, combined with register bit of COML[1], total 9 bit control. range: [00] -- [FF]. HSEND[8:0] must less than HSST[8:0] Horizontal Sync End Position HEND[7:0] - lower 8 bit of horizontal sync ending position, combined with register bit of COML[0], total 9 bit control. range: [00] -- [FF]. HSEND[8:0] must be larger than HSST[8:0]
FRARL Rsvd2C
5E 88
RW RW
2D
COMJ
03
RW
2E
VCOFF
80
RW
2F-32 33
Rsvd2F-Rsvd32 CPP
xx 00
RW
34 35 36 37
BIAS Rsvd35 Rsvd36 Rsvd37
A2 80 48 41
RW RW RW RW
38
COMK
81
RW
39
COML
00
RW
3A
HSST
0F
RW
3B
HSEND
3C
RW
30
Version 1.11
14 May 1999
OMNIVISION TECHNOLOGIES, Inc. OV6620/OV6120
Subaddress (hex) Register Default (hex) Read/ Write Descriptions
Advanced Information Preliminary
SINGLE IC CMOS COLOR AND B/W DIGITAL CAMERAS
3C
COMM
21
RW
Common Control M COMM[7:5] - Select minimum AEC number if Banding filter enable. [000] -- 1 field, [001] -- 1/2; [010] -- 1/4; [011] -- 1/8; [100] -- 1/16; [101]~[111] -- 1/32; COMM[4] - AEC/AGC change mode selection COMM[3] - AEC/AGC change mode selection COMM[2] - AEC/AGC change fastest mode COMM[1] - AEC/AGC change fast mode COMM[0] - AEC/AGC change slowest mode Common Control N COMN[7] - Enable one frame drop when AEC change to keep data valid when Banding filter mode enable. COMN[6:4] - reserved COMN[3] - Enable 50 Hz PAL video timing, so VTO analog signal can be displayed on TV COMN[2:0] - reserved Common Control O COMO[7] - Input main clock divided by 2 or 4 selection. 1 -- 2; 0 -- 4 COMO[6:5] - reserved COMO[4] - Select 4 bit nibble mode output COMO[3] - reserved COMO[2] - Enable Minimum exposure time is 4 line. Default is 1 line COMO[1] - reserved COMO[0] - reserved Common Control P COMP[7] - reserved COMP[6] - Output main clock output from FODD port COMP[5] - reserved COMP[4] - Software whole chip power down enable, can be waked up by disable this bit COMP[3:2] - reserved COMP[1] - CCIR656 output control COMP[0] - Reset internal timing circuit without reset AEC/AGC/AWB value reserved YUV Matrix Control (Main) YMXA[7:5] - reserved YMXA[4:3] - YUV/YCrCB selection: [00] U = u, V = v [01] U = 0.938u, V = 0.838v [10] U = 0.563u, V = 0.714v [11] U = 0.5u, V = 0.877v YMXA[2:0] - Reserved reserved YUV Matrix Control (Secondary) YMXB[7:6] - Y channel delay selection: 0 ~ 3 tp YMXB[5:4] - UV delay selection: 0 ~ 6 tp YMXB[3:2] - Select UV average mode. [00] & [10]: U0/V0 (no delay); [01] -- 3 point average; [11] -- 5 point average mode YMXB[1:0] - Color killer control: [00]:2.4v;[01]:2.6v;[10]:2.8v;[11]:3.0v reserved
3D
COMN
08
RW
3E
COMO
80
RW
3F
COMP
02
RW
40
Rsvd40 - Rsvd4C
XX
-
4D
YMXA
02
RW
4E
Rsvd4E
XX
-
4F
YMXB
00
RW
50
Rsvd50 - Rsvd53
XX
-
14 May 1999
Version 1.11
31


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