DtSheet

ETC ZR36506

ZR36506 USBVision
The One Chip Solution for
Multi-Mode Digital Cameras
Datasheet
February 2001
Zoran Proprietary and Confidential
Rev. 1.0
Zoran ZR36506 USBVision – Datasheet
Zoran Proprietary and Confidential
Zoran reserves the right to make changes without further notice to any product herein. Zoran
makes no warranty, representation or guarantee regarding the suitability of its products for any
particular purpose, nor does Zoran 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 consequential or incidental damages. Zoran products are not designed, intended, or
authorized for use as components in systems intended for surgical implant into the body, or other
applications intended to support or sustain life, or for any other application in which the failure
of the Zoran product could create a situation where personal injury or death may occur.
Zoran ZR36506 USBVision – Datasheet
Zoran Proprietary and Confidential
Table of Contents
1
Introduction ............................................................................ 1-1
ZR36506 - Multi-mode Digital Camera Chip .....................................................1-1
Support for OEM Customizations.......................................................................1-1
Features and Benefits ..........................................................................................1-2
On-Line (USB, Serial, Wireless) Mode ....................................................1-2
Product Description .............................................................................................1-3
2
ZR36506 Pinout....................................................................... 2-1
Pin Descriptions ...................................................................................................2-1
Flash Memory......................................................................................................2-5
Power Management .............................................................................................2-5
LCD Control, Functional Button, General Purpose Pins ....................................2-6
SPO Pins ..............................................................................................................2-6
Absolute Maximum Ratings (Voltages Referenced to GND).............................2-7
Electrical Characteristics (Vcc=3.3 V, T A = 0 to 70o C) ....................................2-7
USB_VP/VM Pins Electrical Characteristics (V cc=3.3 V, T A = 0 to 70o C) .....2-8
Video Parameter Specifications ..........................................................................2-8
USB Interface Parameter Specifications .............................................................2-9
Audio Parameter Specifications ..........................................................................2-9
3
General Architecture ............................................................... 3-1
4
Register Bank (Control and Status) ....................................... 4-1
Write Transaction Protocol..................................................................................4-1
Read Transaction Protocol ..................................................................................4-2
EEPROM Read/Write Registers ..........................................................................4-6
SDRAM and Memory Buffer Setup Registers....................................................4-6
Video Setup and Control Registers .....................................................................4-8
Audio & Bulk -Data Port Read/Write Registers ................................................4-10
USB Watch-Dog Register .................................................................................4-11
Compression Ratio Management Registers.......................................................4-11
Table of Contents
i
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5
Internal Microcontroller Host Request Interface................... 5-1
6
V8 µ-RISC Block ....................................................................... 6-1
General................................................................................................................6-1
Memory Resources .............................................................................................6-1
7
Power Management.................................................................7-1
8
Video Input Interface.............................................................. 8-1
Video Interface Timing Parameters ....................................................................8-3
Input Video Parameters.......................................................................................8-3
Frame-Rate Control.............................................................................................8-6
Video Scaling......................................................................................................8-7
Video Filters........................................................................................................8-8
Video Output Format ..........................................................................................8-9
Compressed Data Format....................................................................................8-9
YUV 4:2:2 Interleaved Format......................................................................... 8-10
YUV 4:2:0 Planar Format................................................................................. 8-10
Video Buffer Control registers.......................................................................... 8-11
Special Video Control bits ................................................................................ 8-12
USB Pipe Video Data Format ........................................................................... 8-12
Data Packets............................................................................................ 8-12
Video Frame Synchronization ................................................................ 8-13
Video Frame Header ............................................................................... 8-13
9
SDRAM Control and Interface ................................................. 9-1
MAU (Memory Access unit) ..............................................................................9-1
SDRAM and Memory Buffer Setup Registers ...................................................9-3
Video Setup and Control Registers .....................................................................9-4
CLK48 Output.....................................................................................................9-5
ii
Table of Contents
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10 Camera Control Serial Port ................................................... 10-1
Soft Mode: (MODE=0) .....................................................................................10-3
SIO Mode: (MODE=1)......................................................................................10-3
IIC LRACK Mode: (MODE=2) ........................................................................10-4
IIC LRNACK Mode: (MODE=3) .....................................................................10-5
CAM1 Mode: (MODE=4) .................................................................................10-6
CAM2 Mode: (MODE=5) .................................................................................10-7
11 External EEPROM................................................................... 11-1
EEPROM Data Structure...................................................................................11-1
V8 Downloadable Code ....................................................................................11-2
Supported UNICODE Language Table:............................................................11-3
Table of Descriptor Pointers..............................................................................11-5
Table of Descriptors..........................................................................................11-7
EEPROM Access Registers...............................................................................11-8
EEPROM Control Signals.................................................................................11-9
12 ZR36506 USB and Status Registers ...................................... 12-1
13 Programmable I/O Pins and 48 MHz Output Pin ................. 13-1
14 Audio Channel ....................................................................... 14-1
Codec Interface..................................................................................................14-2
15 Bulk Channel.......................................................................... 15-1
16 Serial Pipe Out Interface ...................................................... 16-1
Description ........................................................................................................16-1
Timing Table .....................................................................................................16-3
17 Software Package.................................................................. 17-1
18 Mechanical Specifications..................................................... 18-1
19 Contact Information.............................................................. 19-1
Table of Contents
iii
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1
INTRODUCTION
ZR36506 - Multi-mode Digital Camera Chip
Zoran’s USBvision ZR36506 is a revolutionary, multi-mode digital camera chip offering
integrated live digital video and audio capture functionality.
Powered by an integrated microprocessor, the chip’s high level of versatility facilitates the
design and implementation of multi-function digital cameras. The ZR36506 supports on-line
operation (over USB, wireless or any other, non-USB connections), for such applications as live
audio/video streaming and surveillance, as well as standalone applications, such as digital still
cameras with audio recording capabilities.
For applications requiring alternative digital video connection schemes (wireless connections,
surveillance cameras or devices lacking USB support), the ZR36506 may be integrated into
camera designs built around a serial interface for transferring images, audio clips and
compressed video.
Support for OEM Customizations
Zoran supplies a full reference design kit, software A/V streaming WDM driver which is
Microsoft DirectShow compatible, digital camera TWAIN drivers and software API support for
the ZR36506 FLASH memory – transfer and management (preview, deletion, photo album
creation). The API reference kit contains header and library files, as well as sample programs
demonstrating their use. Device drivers may easily be renamed (OEM USB vendor and product
IDs may be programmed via a .INF file) to reflect different OEM branding schemes.
Introduction
1 -1
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Features and Benefits
On-Line (USB, Serial, Wireless) Mode
Applications: video conferencing, live video capture and editing, video gaming and
surveillance.
§ Full-motion, full-color video
Up to 30 frames per second at CIF (352 x 288) resolution; up to 15 frames per second at
VGA (640 x 480) resolution. Live video may be streamed over serial connections (either
wireless or wired) at up to 1 Mbyte/sec. Software controlled digital pan and zoom. Support
for raw and compressed video at variable compression ratios (over USB or non-USB
connections).
§ Simultaneous video and stereo audio capture
Full compatibility with Microsoft DirectShow WDM streaming and popular video
conferencing and video editing software applications.
§ VGA (640 x 480) resolution TWAIN compatible still image capture
TWAIN compatibility for live still image capture and for control over digital camera flash
memory: preview, transfer or erase pictures.
§ Easy Plug -and-Play operation
Video camera configuration is stored in external EEPROM. Powered by USB port, with
adjustable USB bandwidth utilization (0.5 – 7.5 Mb/sec).
Off-Line (Standalone) Mode
Applications: digital still image and audio capture.
§ Easy digital image and audio clip capture anywhere
Pictures and audio clips are stored on the camera’s flash memory and may be transferred to
a computer or PDA via USB, wireless or other connections. An audio clip may be recorded
for each picture via an integrated microphone.
§ Large storage capacity
Up to 4 Megabytes of flash memory accommodate up to 120 pictures at 320 x 240 QVGA,
or up to 30 images at high quality, VGA resolution.
§ Built-in hardware interfaces and support for still digital camera applications
Built-in support for camera Capture and Function buttons. Support for two 7-segment LCD
displays to indicate camera mode or status, and the number of stored images. Low power
consumption and an Auto Power Off feature extend battery life.
§ Easy firmware upgradeabilty
Microprocessor code updates and expansions may easily be performed via the ZR36506’s
integrated EEPROM.
1-2
Introduction
Zoran ZR36506 USBVision – Datasheet
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Product Description
16MB SDRAM
Digital
camera
MT48LC1MA6ATGS
Audio Codec (Optional)
OKI MSM7508B
OKI MSM7716
FUJ. MB86435
NT1006CHIP
CHIP
ZR36506
DVS
ACI
DVI
Digital Video
Interface
Serial data in
(0-2Mbps)
MAU
Digital Video
Scaler
Memory
Access
Unit
Audio Codec
Interface
USB 1.1
Host
DVC
USBI
Digital Video
Compressor
UL_GL
LCD
Universal
serial Bus
Inte rface
V8
Micro
Controller
Serial EEPROM
Flash
Interface
PMU
Power
Management
Unit
PLL
24FC16 -SN/P
AT24C16N -2.7
RBCS
Register Bank
Control & Status
Prog.
I/O
Serial Protocol
Controller
Serial Interface
SPO
Serial data out
1 Mbytes/sec
FLASH 16M -32M
Camera Board Logic
AT49BV1614T
AM29LV160D
X
T
L
ZR36506 Internal Block Diagram
The ZR36506 utilizes a single USB port to enable the host computer to access 4 different data
channels simultaneously. These 4 channels are the Digital Video input (7.5 Mbit/sec), Digital
Audio input, Serial Bulk Data input, and I/O control (internal registers, programmable I/O pins
and selectable Data/Clock serial protocols).
Due to the sophisticated architecture and protocol of the USB interface, the software application
is not required to handle time-sharing management of several tasks using a single serial bus. This
is handled by lower-level drivers, so that the application program can access each function of the
ZR36506 independently.
Introduction
1 -3
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In normal operation, the ZR36506 performs following tasks:
Compressed Video Channel
The ZR36506 connects to a Y/U/V digital video source, scales the image horizontally and
vertically on the fly, compresses the data down to 0.5-7.5 Mbit/sec, and sends it to the host
computer via the USB port. The ZR36506 scaler supports zoom-in-like effects by applying
combinations of built-in zooming and cropping functions. This unique compression method is
proprietary to Zoran and allows fast and easy software-only decompression.
The decompression software driver supplied with the ZR36506 will accept compressed data and
convert it back to standard video formats in less time than it would take to read raw video from
any external port. Still images may be captured and sent via USB in the best quality and
resolution that the camera can provide.
§ Sound System
Some camera applications require that a microphone sound system be implemented inside
the camera. Additionally, composite-video to USB adapter applications require audio
recording support. The ZR36506 provides a solution for these applications by multiplexing
serial digital audio input with video data that is sent via the USB port. The microphone can
be located inside the camera, up to 5 meters away from the host computer. The ZR36506
does not include the audio A/D, and is designed to use an external low-cost telephony audio
codec.
§ Camera Control
Camera (or any video source) control and status monitoring can be carried out via a built-in
serial interface or direct I/O pins. The serial interface supports some common serial
protocols. Control and monitoring software for other remote devices may use these ports as
well. In a video conference application, this feature allows the local or remote user to set the
focus, zoom and other parameters of the camera, and even switch the camera’s power off.
The ZR36506 also supports usage of an external capture button that is mounted on the
camera board and is used for capturing video frames to the host computer hard disk (this is
application dependent - the ZR36506 only delivers the capture command signaling from
button to host computer via USB).
1-4
Introduction
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2
ZR36506 PINOUT
Pin Descriptions
Pin Number
Signal
18, 60, 99, 139
VDD
2.5 V supply (for core logic).
8, 51, 87, 96,
114, 141
VCC
3.3 V supply (for I/O pins).
36
AVDD
2.5 V Analog supply for internal PLL.
19, 59, 100, 140
VSS
Digital ground connections (for core).
9, 52, 91, 107,
142
VSSE
Digital ground connections (for I/O pins).
37
AVSS
Analog ground for internal PLL.
41 – 48
Y0-Y7
I
Video Luminance input from camera. The VCLK
input is used to sample the bus. Each input pin
features an internal Pull-Down resistor.
49 – 50, 53 – 58
U0-U7
I
Video Chroma U or U/V-components input from
camera. The VCLK input is used to sample this bus.
Each input pin features an internal Pull-Down
ZR36506 Pinout
I/O Description
2 -1
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Pin Number
Signal
I/O Description
resistor.
40
TEST1 (MST)
I
This pin must be connected to GND.
61
VCLK
I
Video Pixel-Clock input from camera
64
HVALID
I
Video Clock Enable input qualifier. This input pin
should be connected to GND if not used.
62
VSYNC
I
Video Vertical-Sync input signal from camera. This
input pin should be connected to GND if not used.
65
HSYNC
I
Video Horizontal-Sync input signal from camera.
This input pin should be connected to GND if not
used.
63
FID
I
Video Field-ID input signal from camera. This input
pin should be connected to GND if not used.
12 – 13
IO-1 - IO-2
38
XIN
I
Crystal Oscillator input pin (12 MHz). Crystal
frequency must provide at least 100 PPM accuracy.
39
XOUT
O
Crystal Oscillator output pin (12 MHz).
1
BLK_FULL
O
"Bulk-FIFO full" indication output signal. This
output signal is normally '0' and is set to '1' when the
ZR36506 Bulk-FIFO is full. This output is
temporarily set to '0' while in the Suspend or PowerDown position.
2
BLK_EN
I
Bulk Data Enable input. When set to '1', Bulk input
data from the DAT_IN pin is sampled in by falling
edge of BCLK into the ZR36506 Bulk-FIFO.
3
DAT_IN
I
Data Input pin for both Audio CODEC Tx channel
and Bulk Data in. This input pin requires an external
Pull-Up resistor.
4
FS_L
O
Audio Codec Frame-Sync pulse for Left channel.
This signal triggers the beginning of a new audio
sample (left chan). This output is temporarily set to
'0' while in the Suspend or Power-Down position.
5
FS_R
O
Audio Codec Frame-Sync pulse for Right channel.
This signal triggers the beginning of a new audio
2-2
I/O
General Programmable I/O pins. Each of these 2 pins
has an Open Drain, and is supposed to be connected
to an external Pull-Up resistor. The host uses these
pins as programmable output ports by writing '0' or
'1'. By writing '1' and read back, the host can use
these pins’ input ports - as this allows any external
source to force the Pull-Up resistor. The se outputs
are temporarily set to High-z while in Suspend mode.
ZR36506 Pinout
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Pin Number
Signal
I/O Description
sample (right chan). This output is temporarily set to
'0' while in the Suspend or Power-Down position.
6
BCLK
O
Main Clock for both Audio CODEC and Bulk Data
in. This output is temporarily set to '0' while in the
Suspend or Power-Down position.
138
CLK48
O
48 MHz Clock output for SDRAM interface. This
output is set to '0' while in Suspend or Power-Down
modes.
159, 157, 155,
153, 151, 149,
147, 145, 144,
146, 148, 150,
152, 154, 156,
158
DD0-DD15
125
CASN
O
SDRAM Column Address Select Active low. This
output is set to High-z while in Suspend or PowerDown modes.
143
WRN
O
SDRAM Write Enable Active low. This output is set
to High-z while in Suspend or Power-Down modes.
160
CSN
O
SDRAM Chip Select Active low. This output is set to
High-z while in Suspend or Power-Down modes.
123
RASN
O
SDRAM Row Address Select Active low. This
output is set to High-z while in Suspend or PowerDown mode.
133, 131, 129,
127, 126, 128,
130, 132, 134,
136, 135, 137
DA0-DA11
O
SDRAM Row/Column Address-bus. These outputs
are set to '0' while in Suspend or Power-Down
modes.
124
CKE
O
SDRAM Clock Enable. Active high, enable clock for
SDRAM.
24
SCL/PWR0
I/O
Serial EEPROM clock signal, and LSbit of Device
Power Code. If an EEPROM is detected, this pin is
used as the EEPROM clock output signal; otherwise
its voltage (Vdd or GND) is used as the LSbit of the
Device Power Code for the USB Device Descriptor.
If EEPROM is detected, this pin is temporarily set to
'1' while in the Suspend position.
22
EEPROM
I
EEPROM Detect pin. If EEPROM is used, a 10 KΩ
Pull-Up resistor to Vdd should be connected to this
pin. Otherwise, it should be tied to GND.
23
SDA
ZR36506 Pinout
I/O
I/O
SDRAM Data bus input/output pins. These pins
feature internal Pull-Down resistors, and are set to
High-z while in Suspend or Power-Down modes.
Serial EEPROM data signal. High-z in Suspend and
Power-Down modes.
2 -3
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Pin Number
Signal
14
PWR1
I
MSbit of Device Power Code. The voltage level in
this input (Vdd or GND) is used by the ZR36506 as
the MSbit of the Device Power Code for the USB
Device Descriptor. If an external EEPROM exists,
this input is ignored.
7
RESIN
I
Power-On Reset input. This input is of SchmittTrigger type, and is active low. It is recommended to
use a power-on RC network for proper Reset.
15
SENS
O
Serial control Enable Signaling. This pin has an Open
Drain output. It should be connected to an external
3.3-10 KΩ Pull-Up resistor. This output is set to
High-z while in Suspend or Power-Down modes.
16
IICDT
I/O
Camera-Control Data I/O (supports some commonly
used serial protocols). This pin has an Open Drain
output. It should be connected to an external 3.3-10
KΩ Pull-Up resistor. This output is temporarily set to
High-z while in the Suspend or Power-Down
position.
17
IICCK
O
Camera-Control Clock output (supports some
commonly used serial protocols). This pin has an
Open Drain output. It should be connected to an
external 3.3-10 KΩ Pull-Up resistor. This output is
temporarily set to High-z while in the Suspend or
Power-Down position.
10
PWR_DWN
O
Camera Power-Down control. This is an Open Drain
output, which is used to switch power On or Off to
the camera and/or external circuit (using an external
switching P-MOSFET transistor). While in Reset, the
output is set to High-z (Off). It is set to High-z in
Suspend mode, and remains High-z when resuming
from Suspend.
11
SUSPND
O
USB Suspend mode control. This is an Open Drain
output. A Power-On Reset or a USB-Reset turn the
output to active low It is set to High-z in Suspend
mode, and is turned to active low when Resuming
from Suspend.
31
CAPTRN
I
Capture Button input. A Schmitt-Trigger input with
an internal Pull-Up resistor When forced to '0', the
host computer is automatically informed that a video
frame capture was requested by the user.
2-4
I/O Description
ZR36506 Pinout
Zoran ZR36506 USBVision – Datasheet
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Pin Number
Signal
I/O Description
20
USB_VP
I/O
Universal-Serial-Bus Positive data line. This line
should be connected to an external Pull-Up resistor
of 1.5 KΩ. Refer to Electrical Characteristics table
for pin spec. This pin is kept High-z while in the
Suspend position.
21
USB_VM
I/O
Universal-Serial-Bus Negative data line. Refer to
Electrical Characteristics table for pin spec. This pin
is kept High-z while in the Suspend position.
Flash Memory
Pin Number
Signal
97-98, 101-106,
113, 115-121,
85, 108-112
FA-1-FA20
95, 94, 93, 92,
90, 89, 88, 86
FD0-FD7
82
I/O Description
O
Flash memory Address Bus. Can address up to
4 Mbytes. Set to ‘0’ logic in Power-Down and
Suspend modes.
I/O
Flash memory Data Bus. Features internal
Pull-Down resistors. High-z in Power-Down
and Suspend modes.
FCEN
O
Flash memory Chip Enable. Active LOW.
‘0’ logic in Power-Down and Suspend modes.
81
FOEN
O
Flash memory Output Enable. Active LOW.
‘0’ logic in Power-Down and Suspend modes.
112
FWEN
O
Flash memory Write Enable. Active LOW.
‘0’ logic in Power-Down and Suspend modes.
84
FRESN
O
Flash memory Reset. Active LOW.
‘0’ logic in Power-Down and Suspend modes.
83
FRDY
I
Flash Ready input (used to indicate end of
Write or Erase operations).
Power Management
Pin Number
Signal
33
USB_PWR
I
‘1’ logic indicates that power comes from USB port.
This input is sampled a few milliseconds after power-on
or Reset operation.
34
BAT_PWR
I
‘1’ indicates that power comes from Battery. This input
is sampled a few milliseconds after power-on or Reset
operation.
ZR36506 Pinout
I/O
Description
2 -5
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Pin Number
Signal
35
PWR_OFF
I/O
O
Description
Auto-Power-Off indication output pin.
A negative pulse on this output is used to turn-off the
battery supply. It is ‘0’ logic in Power-Down and
Suspend modes.
LCD Control, Functional Button, General Purpose Pins
Pin Number
Signal
I/O Description
66-79
SEG0-SEG13
O
Driving two 7-segment LCDs.
‘0’ in Power-Down and Suspend modes.
80
SEG_REF
O
A Reference pin, driving two 7-segment LCDs. ‘0’ in
Power-Down and Suspend modes.
32
FUNCTION
I
Function Button input. A Schmitt-Trigger input with an
internal Pull-Up resistor It is used for the Stand alone
Digital Still Camera MMI.
SPO Pins
Pin Number
Signal
25
USB_CLK
O
Serial Data Clock. Data is valid on Up-going edge.
‘0’ in Power-Down and Suspend modes. Used in non
USB Stand alone mode.
26
USB_DAT
O
Serial Data signal. ‘0’ in Power-Down and Suspend
modes.
27
USB_VALID
O
Serial Data Valid. Data is valid when
USB_VALID=’1’.
‘0’ in Power-Down and Suspend modes.
28
USB_EP2
O
EP2 (Video) transaction indicator.
‘0’ in Power-Down and Suspend modes.
29
USB_EP3
O
EP3 (Audio) transaction indicator.
‘0’ in Power-Down and Suspend modes.
30
USB_EP4
O
EP4 (Bulk) transaction indicator.
‘0’ in Power-Down and Suspend modes. Not valid in
Non USB Stand alone mode.
2-6
I/O Description
ZR36506 Pinout
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Absolute Maximum Ratings
(Voltages Referenced to GND)
Rating
Symbol
Value
Unit
Core DC Supply Voltage
Vdd - GND
-0.5 to 2.5
V
I/O DC Supply Voltage
Vcc - GND
-0.5 to +3.3
V
Voltage, any pin to GND
V
-0.5 to V cc+0.5
V
DC Current Drain per Pin (Excluding V dd, GND)
I
±20
mA
Junction Temperature Range
TJ
-40 to +125
o
C
T stg
-40 to +125
o
C
Storage Temperature Range (plastic package)
o
Electrical Characteristics (Vcc=3.3 V, TA = 0 to 70 C)
Characteristic
Symbol
Min
T ype
Max
Unit
Core DC Supply Voltage (Vdd to GND)
Vdd
2.25
2.5
2.75
V
I/O DC Supply Voltage (Vcc to GND)
Vcc
3.0
3.3
3.6
V
Core DC Supply Current (@ V dd=2.5 V)
Idd
52
53.16
54
mA
I/O DC Supply Current (@ Vdd=3.3 V)
ICC
12.36
12.49
12.6
mA
Suspend mode Current (@ V dd=3.3 V)
ISuspend
-
-
200
µA
High Level Input Voltage
VIH
0.7xVcc
-
Vdd+0.3
V
Low Level Input Voltage
VIL
-0.3
-
0.3xVcc
V
Input Current
Iin
-10
+1
+10
µA
Input Capacitance
Cin
-
5
16
pF
3-State Output Leakage Current
VO = V cc+0.3 or GND
IOZ
-10
+1
+10
µA
Output Capacitance
C out
-
5
16
pF
High Level Output Voltage (@ Ioh = 0.8 mA)
VOH
V cc-0.1
-
-
V
Low Level Output Voltage (@ Iol = 0.8 mA)
VOL
0
-
0.1
V
Pull-Up / Pull-Down Resistance
RPU
25
50
200
KΩ
VI = Vcc+0.3 or GND
ZR36506 Pinout
2 -7
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USB_VP/VM Pins Electrical Characteristics
o
(Vcc =3.3 V, T A = 0 to 70 C)
Characteristic
Symbol
Min
Type
Max
Unit
High-z State Data Line Leakage
(@ 0<Vin<3.3 V)
ILO
-10
-
+10
µA
Differential Input Sensitivity
VDI
0.2
-
-
V
Differential Common Mode Range
VCM
0.8
-
2.5
V
Single Ended Receiver Threshold
VSE
0.8
-
2.0
V
Static Output Low
(@ 1.5 KΩ Pull-Up resistor to 3.6 V)
VOL
-
-
0.3
V
Static Output High
(@ 15 KΩ Pull-Down resistor to GND)
VOH
2.8
-
3.6
V
Capacitance
CIN
-
-
20
pF
Rise Time (@ CL =50 pF)
TR
4
-
20
nS
Fall Time (@ C L =50 pF)
TF
4
-
20
nS
ZDRV
28
-
43
Ω
Driver Output Resistance
(@ external serial 24 Ω resistor)
Video Parameter Specifications
Parameter
Symbol
Value
Unit
Y/U/V
-
-
Down Scaling
(V/H independent and arbitrary)
-
Up to 16:1
vertical and
horizontal
-
Horizontal Anti Aliasing Filter (2)
-
2-5 taps
-
Vertical Anti Aliasing Filter (2)
-
2-3 taps
-
Digital Video Input Format (1)
o
Interpolation Phase Resolution
-
360 /4
-
Image Cropping (V/H independent and
arbitrary)
-
Any window of
length 1 to full
image
-
Video Compression Ratio
Cr
1-8
-
Video Compressor Clock Frequency
-
48.000
MHz
Compressed Video Bit Rate
2-8
-
0.5 to 7.5
Mbit/sec
-
ZR36506 Pinout
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§
Refer to Video Channel chapter for specification of
digital video input modes and waveforms.
§
Filter uses interpolation process.
USB Interface Parameter Specifications
Parameter
Value
Unit
USB Pipe
mode
USB Maximum Data Rate
12
Mbit/sec
-
Compressed Video Maximum Data Rate
7.5
Mbit/sec
Isochronous
I/O channel Rate Capacity
0-16
Kbit/sec
Control &
Bulk
I/O channel uses transactions of up to 8 bytes per package.
Audio Parameter Specifications
Parameter
Symbol
Value
Unit
Digital Audio Sampling Rate
Fs
8.0/16.0 ±
0.25%
KHz
Audio channel Bit Rate
-
64-512 Kb/sec
µ-Law or ALaw
-
1.536, 2.048
MHz
Audio CODEC clock frequency
Audio CODEC clock frequency is programmable to either
1.536 or 2.048 MHz.
ZR36506 Pinout
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3
GENERAL ARCHITECTURE
The following diagram describes the general architecture of the ZR36506, regarding it as a
standard USB device:
NT1006
Software Drivers
Host
Computer
Buffers
Message
Pipe
Message
Pipe
Bulk Pipe
0-2Mb/s
End Point 0
End Point4
CONTROL type
BULK DATA IN
type
Descriptors &
Configurations
Stream Pipe
0.5-7.5Mb/s
Stream Pipe
64-512Kb/s
End Point 2
NT1006
Camera
Device
End Point 1
ISOCHRONOUS
DATA IN type
CONTROL type
Register Bank
Control & Status
General Architecture
Video Data
(Compressed or
Raw)
End Point3
ISOCHRONOUS
DATA IN type
Audio Data
3 -1
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The ZR36506 has 5 USB End-Points located on chip:
§ End-Point #0: This is the Descriptors and Configuration End-Point, which is required by the
USB standard.
§ End-Point #1: This is the control end-point used to access the Register Bank. The host
computer uses these registers to control the ZR36506 and the camera.
§ End-Point #2: This End-Point produces and sends the digital video data to the host
computer. It uses 0.5 to 7.5 Mbit/s of the USB bandwidth, depending on the amount of
bandwidth available to the camera.
§ End-Point #3: This End-Point sends the input digital audio data to the host computer. It uses
64 to 512 Kbit/s of the USB bandwidth, depending on the audio quantization and sampling
rate.
§ End-Point #4: This End-Point sends the external Bulk Data input to the host computer. It
uses 0 to 2 Mbit/s of the USB bandwidth, depending on the external source of data.
The ZR36506 has a default set of USB Descriptors on-chip, which are automatically used in
absence of an external serial EEPROM (otherwise, all descriptors are read from the EEPROM).
The default descriptors allow the host computer to select one of 4 different configurations to
operate the camera.
Camera manufacturers may define new configurations (which combine only the available EndPoints), using the 8-pin serial EEPROM. Additionally, string descriptors may be added (in
multiple languages) to define such parameters as the camera vendor's name, product name, serial
number, etc. The USB standard regards these features as optional.
The ZR36506 supports the USB Power-Management-Protocol. The camera and external circuits
may be power-controlled by their vendor-specific software drivers, via serial Data/Clock and I/O
ports. The PWR_DWN output pin may also be used to turn off the local power supply to these
external circuits (refer to ZR36506 application notes). The ZR36506 uses a single 12 MHz
crystal to derive all of its internal clock sources. Power management also involves switching of
internal clock sources, which are not in use in certain modes of operation. This further reduces
the device’s power consumption.
The ZR36506 has two sources of Reset control: The Power-On-Reset that comes from a
dedicated input pin (RESIN), and the USB-Reset command received from the host computer.
Both Reset sources produce a single Reset signal inside the ZR36506, which initializes the
ZR36506. It is assumed that a Power-On-Reset is applied to the RESIN pin before any USB
transaction is sent to the ZR36506 by the host. This is required so that the Serial-InterfaceEngine inside the ZR36506 be able to receive any valid host command that will follow
(including a USB-Reset command).
3-2
General Architecture
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The total USB bandwidth that is consumed by the ZR36506 is mainly affected by the bandwidth
of the Video Data Stream (End-Point #2). To prevent a host computer, which initially has little
available bandwidth, from rejecting the camera device, the ZR36506 uses the Alternate-Interface
mechanism to enable variable bandwidth. This allows the host computer to select the highest bitrate that it can reserve for the video stream, starting from 7.5 Mbit/s down to 0.5 Mbit/s in 0.5
MHz increments (the selected bit-rate affects video quality).
When the ZR36506 is used as a Digital Still Camera in Standalone mode, the internal
microcontroller controls the chip. This includes camera initialization, setting camera control
parameters that are stored in the serial EEPROM, capturing of still images and audio into Flash
memory.
General Architecture
3 -3
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4
REGISTER BANK (CONTROL AND STATUS)
The ZR36506 uses the End-Point #1 message pipe for ZR36506 and camera control. As a bidirectional pipe, this channel allows the host computer to write contents to control registers, as
well as to read status registers. Control registers may also be read by the host computer to check
their contents. All registers are byte-oriented.
The following section defines a USB vendor-specific protocol for read and write operations
applied to the ZR36506 register bank. This protocol uses a standard USB request of a vendorspecific type (defined in chapter 9.3 of USB standard rev.1.1) to perform a data transfer of up to
8 bytes to/from End-Point #1. A single write operation will write 1-8 concurrent bytes to the
register bank, and a single read operation will read 1-8 concurrent bytes from the register bank.
The USB Request Command always defines the address of the first I/O -register to be read or
write. This address is automatically incremented by the ZR36506 for the following data bytes.
The first byte of the USB Request Command defines the direction of the data transfer (0x42 for
write, and 0xC2 for read). The second byte is an ZR36506-specific code - 0x33. The address of
the first I/O-register in the list is defined by the wIndex parameter of the standard USB Request
Command (these are bytes 4 and 5 of the command). All other bytes in the Request Command
are not important to the ZR36506.
Write Transaction Protocol
SETUP PID
Device Address
byte0=0x42
byte1=0x33
byte4 = RA
I/O-Reg address
byte5=0x00
Host defines
Reg-Address
NT1006 sends handshake to host
ACK PID
OUT PID
Device Address
DATA0(1) PID
DATA-byte #1
End-Point #1
DATA-byte #2
(optional)
Host initiates Write operation
DATA-byte #8
(optional)
Reg Data
NT1006 sends handshake to host
ACK PID
IN PID
Host initiates I/O-Reg
operation
End-Point #1
...Empty IN Packet
ACK PID
Register Bank (Control and Status)
Host terminates Setup Command
Host sends handshake to NT1006
4 -1
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The following table specifies the addresses to which the ZR36506 stores each of the bytes that
appear in the data-section of the USB OUT transaction. These addresses relate to the contents of
the wIndex parameter (bytes 4 and 5 of the SETUP command), which is denoted here by RA.
DATA
Byte #
Contents
Description
1
Out Data
Will be stored in register at address RA.
2
Out Data
Optional. Will be stored in register at address RA+1.
3
Out Data
Optional. Will be stored in register at address RA+2.
4
Out Data
Optional. Will be stored in register at address RA+3.
5
Out Data
Optional. Will be stored in register at address RA+4.
6
Out Data
Optional. Will be stored in register at address RA+5.
7
Out Data
Optional. Will be stored in register at address RA+6.
8
Out Data
Optional. Will be stored in register at address RA+7.
Read Transaction Protocol
SETUP PID
Device Address
byte0=0xC2
byte1=0x33
byte4 = RA
I/O-Reg address
IN PID
Device Address
DATA0(1) PID
DATA-byte #1
End-Point #1
DATA-byte #2
(optional)
4-2
Host defines
Reg-Address
Host initiates Read operation
DATA-byte #8
(optional)
NT1006
sends Data
bytes 1-8
Host sends handshake to NT1006
ACK PID
ACK PID
byte5=0x00
NT1006 sends handshake to host
ACK PID
OUT PID
Host initiates I/O-Reg
operation
End-Point #1
...Empty OUT Packet
Host terminates Setup Command
NT1006 sends handshake to host
Register Bank (Control and Status)
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DATA
Byte #
Contents
Description
1
Register Data
Byte read from register at address RA.
2
Register Data
Optional. Byte read from register at address RA+1.
3
Register Data
Optional. Byte read from register at address RA+2.
4
Register Data
Optional. Byte read from register at address RA+3.
5
Register Data
Optional. Byte read from register at address RA+4.
6
Register Data
Optional. Byte read from register at address RA+5.
7
Register Data
Optional. Byte read from register at address RA+6.
8
Register Data
Optional. Byte read from register at address RA+7.
Reading from an address that does not exist is legal, but
will return unpredicted data.
The following tables specify all control and status registers in the ZR36506. A brief description
is provided for every specific bit in these registers, and default values (after a Reset operation)
are defined. For more details about a specific register, consult the appropriate session in this data
sheet.
Register
Address Register Name
0
1
PWR_REG
CONFIG_REG
Function
d0:
WD_EN: '1' Enables USB Watch-Dog
timer.
d1:
SSPND_EN: '0' Enables SuspendResume logic.
d2:
RES2: '0' Restarts End-Point #2 logic,
'1' Releases.
d3:
CLK48_EN: '1' Enables 48 MHz at
CLK48 output pin.
d4:
reserved, should be ‘0’.
d5:
PWR_VID: '1' Video-logic Power-On.
d6:
reserved.
d7:
E2_EN: '1' Enables EEPROM R/W.
d7-d0: Configuration (set via USB). ReadOnly reg.
Register Bank (Control and Status)
Default
Value
00H
00H
4 -3
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Register
Address Register Name
2
ADRS_REG
Default
Value
Function
d6-d0: Device Address (set via USB). ReadOnly reg.
00H
d7: '0'. reserved.
3
ALTER_REG
d3-d0: Video Bandwidth (set via USB).
Read-Only reg.
00H
d7-d4: '0000'. reserved.
4
FORCE_ALTER_ d3-d0: NEW_ALT Forced Video Bandwidth.
REG
R/W reg.
d7:
00H
FORCE_ALT ('1'=force, '0'=ignore).
d6-d4: '000'. reserved.
5
STATUS_REG
d0:
VFRM_BLNK Vertical Blank (if '1').
Read-Only reg.
00H
d7-d1: '0000000'. reserved.
6
IOPIN_REG
d0:
IO_1 Read/Write level of ZR36506
pin IO-1.
d1:
IO_2 Read/Write level of ZR36506
pin IO-2.
00H
d7-d4: TEST[3..0], must be '0000' for proper
operation.
d3-d2: '00'. Reserved.
4-4
Register Bank (Control and Status)
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Register
Address Register Name
7
SER_MODE
Function
d6-d4: MODE (Soft, IICC, Cam1, Cam2).
d7:
Default
Value
00H
Auto Bulk.
‘1’ – Enable Bulk.
‘0’ – Disable Bulk.
Normal operation (when not in Soft mode):
d0:
CLK_RATE ('0' = 93.75 KHz,
'1' =1.5 MHz).
d1:
CLK_POL ('0' = Normal, '1' =
Inverted).
d2:
Must be '0' for proper operation.
d3:
VSYNC ('1' = wait to new input video
field).
Soft mode:
d0:
CLK_OUT (functional in Soft mode
only).
d1:
DAT_IO (functional in Soft mode
only).
d2:
SENS_OUT (functional in Soft mode
only).
8
SER_ADRS
d7-d0: Address of serial device/cameraparam.
00H
9
SER_CONT
d2-d0: SER_LEN Number of bytes to Wr/Rd.
00H
d3:
SER_DIR ('0' = Wr, '1' = Rd).
d4:
SER_GO/SER_BUSY.
d5:
NACK_RCV (Read-Only. '1' means
Not Ack.).
d6:
CONTINUE (Do not send START
signal next time).
d7:
NO_STOP (Do not send STOP signal
this time).
10
SER_DAT1
d7-d0: 1st serial byte to be sent/received.
00H
11
SER_DAT2
d7-d0: 2nd serial byte to be sent/received.
00H
12
SER_DAT3
d7-d0: 3rd serial byte to be sent/received.
00H
13
SER_DAT4
d7-d0: 4th serial byte to be sent/received.
00H
Register Bank (Control and Status)
4 -5
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EEPROM Read/Write Registers
Register
Address
Register
Name
Default
Value
Function
14
EE_DATA
d7-d0: EEPROM byte to be Written/Read.
00H
15
EE_LSBAD
d7-d0: 8-LSbits of byte address in EEPROM.
00H
16
EE_CONT
d2-d0: 3-MSbits of byte address in EEPROM.
00H or
xxx0000
(when no
EPROM)
d3:
EE_DIR ('0' = Write, '1' = Read).
d4:
EE_GO/EE_BUSY.
d7-d5: EE_CLK_FORCE (This field is ReadOnly)
SDRAM and Memory Buffer Setup Registers
Register Register
Address Name
18
Default
Value
Function
DRM_CONT d0:
REF ('0' = 8.2 ms, refresh rate).
d1:
Enable operation of SDRAM. The bit
SDRAM_EN is Reset to ‘0’ by Reset, Suspend or
Power-Down events. User should write ‘1’ to
enable SDRAM after these events, allowing for at
least 100 uSec after Power-Up.
d2:
RES_UR Restart video out buffer read logic.
d3:
RES_FDL Restart video-frame-delay logic.
d4:
RES_VDW Restart video out buffer write logic.
00H
d5-d7: reserved.
19
DRM_PRM1
d0-d3: Bits 19-16 of FDL_LST_WORD.
00H
d4-d7: reserved.
20
DRM_PRM2
d0-d3: Bits 11-8 of FDL_1ST_ROW.
00H
d4-d7: reserved.
21
DRM_PRM3
d0-d3: Bits 11-8 of VDW_LST_ROW.
00H
d4-d7: Bits 11-8 of VDW_1ST_ROW.
22
DRM_PRM4
d7-d0: Bits 7-0 of FDL_1ST_ROW parameter.
00H
23
DRM_PRM5
d7-d0: Bits 7-0 of FDL_LST_WORD parameter.
00H
24
DRM_PRM6
d7-d0: Bits 15-8 of FDL_LST_WORD parameter.
00H
25
DRM_PRM7
d7-d0: Bits 7-0 of VDW_1ST_ROW parameter.
00H
4-6
Register Bank (Control and Status)
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26
DRM_PRM8
d7-d0: Bits 7-0 of VDW_LST_ROW parameter.
Register Bank (Control and Status)
00H
4 -7
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Video Setup and Control Registers
Register Register
Address Name
27
28
VIN_REG1
VIN_REG2
Default
Value
Function
d2-d0: VIN_MODE Digital video input format.
d3:
VSNC_POL Vertical-Sync. Pulse
polarity.
d4:
HSNC_POL Horizontal-Sync. Pulse
polarity.
d5:
FID_POL Field Identity signal polarity.
d6:
HVALID_POL Pixel Envelope polarity.
d7:
VCLK_POL ('1'=data valid on up-going
clock).
d0:
AUTO_FID Auto Field Identity
generation. When set to '1', the
ZR36506 ignores the FID input from
camera, and generates an internal
toggling signal of its own instead.
d1:
NONE_INTERLACE Interlace/NonInterlace mode. If set to '1', all input
fields from the camera are processed,
otherwise odd fields are ignored.
d2:
NO_HVALID If set to '1', HVALID
input ignored.
d3:
UV_ID If set to '1', use V7 pin as UV-id
('1'=U).
d4:
FIX_2C If set to '1', U7 & V7 are
inverted (2's comp).
d5:
SEND_FID- If set to '1',
Frame_Phase[0]=FID.
d6:
'0' reserved.
d7:
KEEP_BLANK - Set to '1' to drop
incoming frames.
00H
00H
29
LXSIZE_IN
d7-d0: bits 7-0 of input video line length.
00H
30
MXSIZE_IN
d1-d0: bits 9-8 of input video line length.
00H
d7-d2: '000000' reserved.
31
4-8
LYSIZE_IN
d7-d0: bits 7-0 of input video number of lines.
00H
Register Bank (Control and Status)
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Register Register
Address Name
32
MYSIZE_IN
Function
d1-d0: bits 9-8 of input video number of lines.
Default
Value
00H
d7-d2: '000000' reserved.
33
LX_OFFST
d7-d0: bits 7-0 of input video horizontal offset.
00H
34
MX_OFFST
d1-d0: bits 9-8 of input video horizontal offset.
00H
d7-d2: '000000' reserved.
35
LY_OFFST
d7-d0: bits 7-0 of input video vertical offset.
00H
36
MY_OFFST
d1-d0: bits 9-8 of input video vertical offset.
00H
d7-d2: '000000' reserved.
37
FRM_RATE
d4-d0: Frame-Rate factor Numerator for video
data output.
00H
d6-d5: Frame-Rate factor Denumerator code:
'00': 32, '01': 30, '10': 25.
d7:
'0' reserved.
38
LXSIZE_O
d7-d0: bits 7-0 of output video line length.
00H
39
MXSIZE_O
d1-d0: bits 9-8 of output video line length.
00H
d7-d2: '000000' reserved.
40
LYSIZE_O
d7-d0: bits 7-0 of output video number of lines.
00H
41
MYSIZE_O
d1-d0: bits 9-8 of output video number of lines.
00H
d7-d2: '000000' reserved.
42
FILT_CONT
d2-d0: XFILT_CONT Horizontal-Filter select.
00H
d4-d3: YFILT_CONT Vertical-Filter select.
d7-d5: '000' reserved.
43
VO_MODE
d5-d0
Digital Video-Out format (4:2:2, 4:2:0,
compression).
d6:
('1' = Compressed Video, '0' = Raw).
d7:
'0' reserved.
00H
44
INTRA_CYC d7-d0: Intra-Compression cycle (in frame
units).
00H
45
STRIP_SZ
00H
d3-d0: ACT_STRIP Actual Strip width (# of
video lines).
d7-d4: VIRT_STRIP Virtual Strip width (# of
video lines).
Register Bank (Control and Status)
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Register Register
Address Name
46
FORCE_INT
RA
Default
Value
Function
d0:
('1' = Force next frame Intra).
00H
d7-d4: MIN_DENUM[3..0].
d3-d1: '000' reserved.
47
FORCE_UP
d0:
('1' = Force Up-mode Intra segments).
00H
d7-d1: STRIP_DAT_LIMIT[6..0].
48
BUF_THR
d7-d0: Threshold for buffer space Frame-Drop
decision (given in units of 2 KB).
00H
49
DVI_YUV
d2-d0: Code for YUV re-order processor.
00H
d4-d3: BUF_THR[9..8]. Extension for 16 Mbit
SDRAM.
d6:
SLOW_CLK12 '1' Select 12 MHz for
Horizontal blank.
d7:
SLOW_CLK16 '1' Select 16 MHz for
Horizontal blank.
d5:
'0' reserved.
Audio & Bulk-Data Port Read/Write Registers
Register Register
Address Name
50
AUDIO_CONT
Default
Value
Function
d0:
E_A - Enable Audio channel ('1'
enables, '0' disables).
d1:
E_B - Enable Bulk-Data port ('1'
enables, '0' disables).
00H
d3-d2: BPS - bits/samp: 00: 8b, 01: 12b, 10:
14b, 11: 16 b.
d4:
S/M - Select Stereo/Mono
'0': Mono.
'1': Stereo.
d5:
FS - Audio Sampling Rate
'0': 8 Ks/sec.
'1': 16 Ks/sec.
d7-d6: BK - Bit-Clk Freq
1: 64 [KHz].
2: 1544 [KHz].
3: 2048 [KHz].
51
4-10
AUD_PK_LEN d7-d0: Max. number of bytes in Audio packet
00H
Register Bank (Control and Status)
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(0 to 128).
52
BLK_PK_LEN
d6-d0: Max. number of bytes in Bulk packet (0
to 64).
d7:
00H
'0' reserved.
USB Watch-Dog Register
Register Register
Address Name
53
Function
WD_COUNT d7-d0: USB_frame Watch-Dog delay
parameter. A value 0x00 produces a 686
micro-seconds delay. A value of 0xE9
produces a 996 micro-seconds delay.
Any value between these two values
affects the delay in steps of 1.33 microseconds. Values higher than 0xE9 have
no effect.
Default
Value
00H
Compression Ratio Management Registers
Register
Address Register Name
Function
Default
Value
56
PCM_THR1
d7-d0: PCM Threshold 1 (unsigned 0-255).
00H
57
PCM_THR2
d7-d0: PCM Threshold 2 (unsigned 0-255).
00H
58
DIST_THR_I
d7-d0: DIST_THR_I (Distortion. Threshold for
Inter).
00H
59
DIST_THR_A
d7-d0: DIST_THR_I (Distortion. Threshold for
Intra).
00H
60
MAX_DIST_I
d7-d0: MAX_DIST (Maximum Distortion for
Inter).
00H
61
MAX_DIST_A
d7-d0: MAX_DIST (Maximum Distortion for
Intra).
00H
62
VID_BUF_ LEFT d7-d0: Space left in ZR36506 SDRAM buffer
for compressed video data (given in
units of 2KB).
00H
Read-Only Register.
63
LFP_LSB
d7-d0: bits 10-3 of LAST_FRM_PNTR
(SDRAM pointer).
Register Bank (Control and Status)
00H
4-11
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Register
Address Register Name
Default
Value
Function
Read-Only Register.
64
LFP_MSB
d6-d0: bits 17-11 of LAST_FRM_PNTR
(SDRAM pointer).
d7:
00H
RAM_FULL ('1' if event occurred from
last Read).
Read-Only Register.
65
VID/LPF
d1-d0: VID_BUF_LEFT[9..8].
00H
d3-d2: LPF[19..18].
d7-d4: '0000' reserved.
Read-Only Register.
4-12
Register Bank (Control and Status)
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5
INTERNAL MICROCONTROLLER HOST REQUEST
INTERFACE
In USB mode, the ZR36506 internal 8-bit microcontroller (the V8) waits for a command from
the host PC to perform one of the following tasks: Load EEPROM, Upload Flash, cancel Flash
Upload and Erase Flash.
In USB mode, the microcontroller does not access the RBCS directly. This is due to the fact that
in this mode, the master of the RBCS is the host PC (via USB).
The following register is an interface with the microcontroller:
RBCS Register
Address Name
66
V8_CMMND
Function
Value
Default
Value
00H
d0:
LD_EPRM (Download
EEPROM to SRAM).
‘01’
d1:
LD_FLSH (Upload
Flash to PC).
‘02’
d0-d1: CLR_FLSH (Clear
Flash memory).
‘03’
d2:
‘04’
(R/W register)
CNCL_LD (Cancel
Flash Upload).
d3-d7: reserved.
Once the ZR36506 device is connected to USB, the software driver can perform these
operations:
1.
Set the LD_EPRM bit (Reg.66, bit d0). This causes the camera to update the V8 software
from the external EEPROM, if it exists. Note that before setting the LD_EPRM bit of
Reg.66, the SER_MODE Reg. (Reg.7) has to be set to 0xb0. After setting the LD_EPRM
bit, the software waits until the LD_EPRM bit returns to ‘0’.
2.
Set the AUTO_BLK bit (Reg.7, bit d7) to enable the V8 to use the Bulk pipe to send data
to the host computer. Set the LD_FLSH bit (Reg.66= 0x02, bit d1). This causes the camera
to upload all picture and audio data from Flash memory to the host computer using the
Bulk pipe (EP #4). The software should wait until the LD_FLSH bit returns to ‘0’. Note
that even if there is no data in the Flash memory (i.e. no pictures were taken), the data
transfer starts from address 0 of the Flash memory and ends at the last byte of the Flash
(size of the Flash memory is 2 Mbytes). Note that audio data is optional and follows the
given picture.
3.
If there is a request to cancel the operation of uploading the Flash memory, set the
CNCL_LD bit (Reg.66=0x04, bit d2). The software waits until Reg.66 returns to 0x00.
4.
Set the CLR_FLSH bits (Reg.66, bit d0-d1, 0x03) upon request from user. This causes the
camera to erase Flash memory. The software waits until Reg.66 returns to 0x00.
Internal Microcontroller Host Request Interface
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6
V8 µ-RISC BLOCK
General
The v8 µ-RISC is an 8-bit microcontroller, which is used in a detachable USB standalone mode
to control and store captured still images and audio clips in FLASH memory. It initializes the
camera and sets the required registers to perform still image capture. In A/V stream standalone
mode, the microcontroller transfers data from corresponding data FIFOs to the serial interface.
When connected to a PC, it is possible to download stored images and audio clips.
Memory Resources
The µ-RISC will require the following memory resources:
§ External 2 Kbyte EEPROM which contains all parameters for the ZR36506 operation mode,
camera setup parameters and tables, Video/Audio Class parameters, and optional direct code
for the microcontroller to replace specific functions or add special, new functionality.
§ On-chip 5 KByte ROM, which contains the kernel program, service routines, interrupt
handling routines and main program.
§ On-chip 2 Kbyte SRAM, which is used for Stack, Interrupt Vectors, EEPROM download,
and microcontroller work area.
V8 µ-RISC Block
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7
POWER MANAGEMENT
To meet USB standard requirements, the ZR36506 must be able to control USB power supply
for the entire device implemented around it. Two pins of the ZR36506 were dedicated to this
task: PWR_DWN and SUSPND. Both pins are Open-Drain, and active when High-z.
The USB standard requires that once a device is hot-connected, it must consume no more than
100 mA from the USB port. After configuration, the device may consume up to 500 mA.
Additionally, the device must not consume more than 0.5 mA in Suspend mode.
The ZR36506 uses its power management pins as follows:
§ The PWR_DWN pin was designed to switch the USB 5v source to the video/audio source
circuit (CCD, DSP, ADC, µ-Controller, Video-Decoder, audio CODEC, etc.). The only ICs
that continue to receive normal power supply in the Power-Down state are the ZR36506,
SDRAM, and EEPROM (all ICs operate on 3.3 V).
§ The SUSPND pin was designed to enable the designer to shut down any additional element
in the ZR36506 application circuit, which may increase the total current consumption to
more than the USB standard allows (> 0.5 mA).
Refer to the ZR36506 Application Notes for an example of how the PWR_DWN and SUSPND
pins should be used, and for the 3.3 V supply in application design.
The ZR36506 software driver can control part of the power-management process through the
following registers on the ZR36506:
Parameter
SSPND_EN
PWR_VID
RES2
Power Management
Register
Address
Reg.0/d1
SSPND_EN
Reg.0/d5
PWR_VID
Reg.0/d2
RES2
Usage
Enable Suspend state:
0:
Default (after Reset). Responds to
USB Suspend condition as required
by USB standard.
1:
Suspend state is disabled.
Apply USB 5 V to Video/Audio Source
0:
Default (after Reset). Video/Audio
Source is OFF.
1:
Video/Audio Source is powered ON.
Restart End-Point #2 (Video pipe) in the
ZR36506:
0:
Default (after Reset). Restart
ZR36506 video path.
1:
Enable ZR36506 Video Processor
and Pipe circuit (after video source is
powered on).
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After a USB-Reset operation, the ZR36506 is in its Power Down state (PWR_DWN pin is set to
High-z). After configuration, the software sets the PWR_VID bit to '1' to turn on the camera
circuit (PWR_DWN='0'). Suspend (if SSPND_EN bit is not set by software) occurs if a USB
Idle state is detected for as long as 3 milliseconds, and resets the PWR_VID bit.
7-2
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8
VIDEO INPUT INTERFACE
The ZR36506 digital video input is in YUV format. The ZR36506 interface for this format is
flexible and supports 4:2:2 (8-bit, or 16-bit), and 4:1:1 timings (12-bit). Horizontal and vertical
controls may be physical pulses or coded signals. Additionally, pixel clock and pulse polarity of
the control signals may be programmed to either positive or negative.
All the input buffers in the ZR36506 that are supposed to be connected to the digital video
source are 5-volt tolerant. This means that a camera with 5-volt CMOS outputs will not cause
any damage to the ZR36506, even though the ZR36506 operating voltage is 3.3 Volts.
The ZR36506 digital video input consists of the following signals:
§ Y0-Y7
In the 4:2:2 16-bit, and 4:1:1 (12-bit) modes, this is the Luminance input bus. In the 4:2:2 8bit mode, this bus is used for mux YUV data. This bus is sampled by the VCLK input clock
for the unsigned binary value (0-255) of the Y component (or U and V as well in the 8-bit
mode).
§ U0-U7
This is the Color (U or U/V) input bus. In the 4:2:2 16-bit and 4:1:1 (12-bit) formats, this
bus is sampled by the even cycles of VCLK input clock for the binary value (0-255) of the
U component, and by the odd cycles of VCLK input clock for the binary value (0-255) of
the V component.
§ VSYNC
This is the Vertical Synchronization pulse, which indicates the start of a new video field (in
Interlaced mode) or the start of a new video frame (in Non-Interlaced mode). This pulse is
normally negative.
§ HSYNC
This is the Horizontal Synchronization pulse, which indicates the start of a new video line.
This pulse is normally negative.
§ FID
This signal is used in Interlaced mode, to indicate whether the current field is even or odd.
In Non-Interlaced mode, this input is ignored by the ZR36506.
§ VCLK
This signal is the video pixel clock. It is used by the ZR36506 to sample all other inputs in
the digital video interface.
§ HVALID
This input is the pixel valid qualifier. When inactive, the ZR36506 refers to the samples that
come from the Y, U, and V buses as blank pixels (which are not considered a part of the
digital image). The ZR36506 may be programmed to ignore the HVALID input.
Video Input Interface
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The digital video camera timing signal expected by the ZR36506:
VSNC
First Line
Last Line
HSNC
FID
EVEN FIELD (if Interlace)
ODD FIELD (if Interlace)
not less than 63us
HSNC
not more than 53us
HVALID
VCLK
Y[0:7]
U[0:7]
xx
y0
y1
y2
y3
y4
y5
xx
xx
u0
v0
u2
v2
u4
v4
xx
V7
YUV-4:2:2 mode - 16-bit. Note that the order of U/V is set by Reg.49/d0.
VCLK
Y[0:7]
u0 y0
v0 y1 u2 y2 v2
y3 u4 y4 v4
y5 u6 y6 v6
y7 u8 y8 v8
YUV-4:2:2 mode 8-bit. Note that the order of Y/U/V is set by Reg.49/d2-d0
In YUV 8-bit mode, the VCLK frequency is twice the pixel
rate.
8-2
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VCLK
Y[0:7]
xx
y0
y1
y2
y3
y4
y5
xx
U[0:3]
xx
VM0
UM0
VL0
UL0
VM1
UM1
xx
VM0 = v0[7..4], VL0 = v0[3..0]
UM0 = u0[7..4], UL0 = u0[3..0]
YUV-4:1:1 mode (12-bit)
Video Interface Timing Parameters
VCLK_POL = '1'
90%
VCLK
10%
tSU > 15ns
VSNC, HSNC,
FID, HVALID,
Y[0:7], U[7:0],
V[7:0]
VCLK_POL = '0'
tH > 10ns
90%
90%
VALID
10%
10%
Input Video Parameters
The ZR36506 was designed to interface to most available YUV formats. To make this possible,
most video parameters are programmable via specific registers from the ZR36506 Register Bank.
The following table specifies all parameters that may be set by the host computer to fit a specific
video source (digital camera, video decoder, etc.):
Parameter
Video Input Interface
Register
Address
Usage
8 -3
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Parameter
VIN_MODE[2..0]
VSNC_POL
HSNC_POL
FID_POL
HVALID_POL
VCLK_POL
AUTO_FID
8-4
Register
Address
Reg.27/d2-d0
VIN_REG1
Reg.27/d3
VIN_REG1
Reg.27/d4
VIN_REG1
Reg.27/d5
VIN_REG1
Reg.27/d6
VIN_REG1
Reg.27/d7
VIN_REG1
Reg.28/d0
VIN_REG2
Usage
Video input mode:
000:
8-bit 4:2:2 mode, using
synchronization pulses.
001:
8-bit 4:2:2 mode, using CCIR 656
sync. codes.
010:
16-bit 4:2:2 mode, using
synchronization pulses.
011:
16-bit 4:2:2 mode, using CCIR
656 sync. codes.
110:
12-bit 4:1:1 mode, using
synchronization pulses.
101, 111:
spare.
Polarity of VSNC pulse:
0:
Synchronize on up-going edge.
1:
Synchronize on down-going edge.
Polarity of HSNC pulse:
0:
Synchronize on up-going edge.
1:
Synchronize on down-going edge.
Polarity of FID (Field Identifier in Interlace
mode) :
0:
FID='0' during first (odd) field.
1:
FID='0' during second (even) field.
Polarity of HVALID signal:
0:
input signal HVALID='1' for active
pixels.
1:
input signal HVALID='0' for active
pixels.
Polarity of VCLK (pixel clock):
0:
Camera data valid at VCLK falling
edge.
1:
Camera data valid at VCLK rising
edge.
0:
Use external FID signal.
1:
Generate internal toggling FID.
Ignore FID pin.
Video Input Interface
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Register
Address
Parameter
NON_INTERLACE
NO_HVALID
UV_ID
FIX_2C
Reg.28/d1
VIN_REG2
Usage
0:
Interlace mode. Only even fields are
transferred.
1:
Non-interlace mode. All frames are
transferred.
Reg.28/d2
VIN_REG2
0:
Normal operation.
1:
Ignore the HVALID input (assume
constant '1').
Reg.28/d3
VIN_REG2
0:
Normal operation.
1:
Use V7 input as a U/V identifier
('1'=U, '0'=V).
Reg.28/d4
VIN_REG2
Fix 2's Compliment U/V values
0:
Normal operation.
1:
Invert U[7] and V[7] to fix to
Unsigned Binary.
XSIZE_IN[9..0]
Regs.29-30
LXSIZE_IN
MXSIZE_IN
Number of pixels in active line of video
source.
YSIZE_IN[9..0]
Regs.31-32
LYSIZE_IN
MYSIZE_IN
Number of active lines in frame (/field) of
video source.
X_OFFST[9..0]
Regs.33-34
LX_OFFST
MX_OFFST
Horizontal offset (number of pixels to be
skipped after start of line).
Y_OFFST[9..0]
Regs.35-36
LY_OFFST
MY_OFFST
Vertical offset (number of lines to be skipped
after start of frame).
DVI_YUV[2..0]
Reg.49/d2-d0
DVI_YUV
Order of Ya/U/V/Yb components of a pixelpair in 8-bit modes (d0 affects 16-bit mode
also):
Video Input Interface
d0:
'0': U comes before V.
'1': U comes after V.
d1:
'0': Ya comes before U/V.
'1': Ya comes after U/V.
d2:
'0': Yb comes before U/V.
'1': Yb comes after U/V.
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Parameter
SLOW_CLK12
SLOW_CLK16
Register
Address
Reg.49/d7-d6
DVI_YUV
Usage
Use these control bits for cameras that have
slow VCLK or too short Horizontal Blank
time interval:
d6:
'0': Normal operation.
'1': Select 12 MHz clock during
Horizontal Blank.
d7:
'0': Normal operation.
'1': Select 16 MHz clock during
Horizontal Blank.
Frame-Rate Control
A camera, or any other video source, normally provides a fixed number of frames per second.
For example, an NTSC-based camera will always provide a frame rate of 30 frames per sec.
The ZR36506 allows the application software to modify the effective frame rate to fit its needs.
This allows some of the frames coming from the camera to be dropped before processing,
eliminating the effort that would be wasted on frames dropped by the computer anyway.
8-6
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The parameter that controls the effective frame rate is called FRM_RATE, and is specified in the
following table:
Register
Address
Parameter
Numerator[4..0]
Reg.37/d4-d0 n
Usage
Frame Drop factor (n = 0-31). Effective
frame rate is:
NTSC: 30*(n+1)/d.
Denum.code[1..0]
Reg.37/d6-d5
code for d
PAL:
25*(n+1)/d.
'00':
d=32.
'01':
d=30.
'10':
d=25.
The n parameter ranges from 0 to d-1. The value n=d-1 instructs the ZR36506 to transfer to the
host computer the full frame-rate that is delivered from the video source. Any value n that is less
than d-1 results in dropped frames from time to time, so that the effective frame rate is only
(n+1)/d of the full frame-rate.
Video Scaling
The ZR36506 has two independent down scalers: one for frame width and one for frame height.
It is the responsibility of the software application to select scale factors that result in a reasonable
aspect ratio.
In order to set the scaling factor, the host computer must simply specify the desired size of the
output frame (assuming XSIZE_IN and YSIZE_IN are initially set). Scaling is performed
automatically by the ZR36506, regarding the output frame size versus the input frame size.
The following table specifies the parameters that are used to set the output frame size:
Parameter
Register
Address
Usage
XSIZE_O [9..0]
Regs.38-39
LXSIZE_O
MXSIZE_O
Number of pixels in line of scaled output
video frame.
YSIZE_O [9..0]
Regs.40-41
LYSIZE_O
MYSIZE_O
Number of lines in scaled output video
frame/field.
Video Input Interface
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Note that if the host computer specifies the same values for input frame size and output frame
size, no scaling occurs (scaling factor is 1:1).
The ZR36506 performs no Up-Scaling (to produce CIF size from 240-line video fields, a special
interpolation process is applied by the software driver). This means that XSIZE_O should never
be greater than XSIZE_IN, and YSIZE_O should never be greater than YSIZE_IN.
Video Filters
The ZR36506 uses internal programmable anti-aliasing filters for the scaling process. There are
two filters that are used: one for horizontal scaling, and the other for vertical scaling. The filters
are programmed independently of each other, and independently of the scaling factors.
Both horizontal and vertical filters use a combination of FIR structure and interpolation to
eliminate pixel jitter in the output frame. The interpolation process effectively improves the
resolution of the input frame by a factor of 4, both horizontally and vertically.
The following table specifies the register that is used to set filter parameters:
Parameter
Register
Address
Usage
XFILT_CONT [2..0]
Reg.42/d2-d0
FILT_CONT
Select one of 5 possible horizontal filters.
YFILT_CONT [1..0]
Reg.42/d4-d3
FILT_CONT
Select one of 3 possible horizontal filters.
The following table specifies the horizontal filters:
XFILT_CONT [2..0]
FIR Filter Applied
(Horizontally)
Interpolation
(Horizontally)
000
FIR = (1.0)
NO
001
FIR = (1.0)
YES
010
FIR = (0.5, 0.5)
YES
011
FIR = (0.25, 0.5, 0.25)
YES
100
FIR = (0.25, 0.25, 0.25, 0.25)
YES
8-8
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The following table specifies the vertical filters:
YFILT_CONT [1..0]
FIR Filter Applied
(Vertically)
Interpolation
(Vertically)
00
FIR = (1.0)
NO
01
FIR = (1.0)
YES
10
FIR = (0.5, 0.5)
YES
Video Output Format
The ZR36506 supports 3 different formats for output video data: Compressed data format,
YUV 4:2:2 and 4:2:0 Raw data formats.
The following table specifies the register that is used to set output video format:
Parameter
VO_MODE [6..0]
Register
Address
Reg.43/d6-d0
VO_MODE
Usage
Select one of 3 video output formats:
0x60 = Compressed data format.
0x03 = YUV 4:2:2 Interleaved format.
0x14 = YUV 4:2:0 Planar format.
It is the responsibility of the ZR36506 software driver to make conversions to provide the
application software with several OS standard video data formats, but the data that is transferred
via USB must be one of these 3 formats.
Compressed Data Format
The ZR36506 compressor is designed to compress YUV 4:2:0 frames (12 bits/pixel) by a factor
of 1:3 to 1:15 (resulting in 4 to 0.8 bits/pixel). The compression algorithm is a proprietary Zoran
development, which meets 3 important requirements that were made to guarantee the high
performance of the ZR36506:
§ Fits the selectable bandwidth of the USB (0.5 - 7.5 Mbits/sec)
§ Supports variable compression rates (in very small increments)
§ Requires minimum CPU time for decompression (and fits the MMX® concept)
Video Input Interface
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The ZR36506 compressor compresses specific frames using its “Intra” mode and all others using
its “Inter” mode. Intra mode does not require any previous frame, while Inter mode is always
based on a reconstructed previous frame. “Intra” frames provide the algorithm with relative
resistance to error propagation between frames but consume more bits per pixel than “Inter”
frames. Error propagation within the frame itself (from higher lines to lower lines) is eliminated
by dividing the frame into many horizontal strips.
YUV 4:2:2 Interleaved Format
In this format, the ZR36506 transfers to the host computer 2 bytes for every pixel (16 bits/pixel).
The Y-component is available for every pixel, but the U and V components are each available
for every second pixel (Y0, U0, Y1, V2, Y2, U2, Y3...).
YUV 4:2:0 Planar Format
In this format, the ZR36506 transfers to the host computer 3 bytes for every 2 pixels (12
bits/pixel). The Y-component is available for every pixel, but the U and V components are only
available for every second pixel in even lines.
In this mode, the host computer receives a frame preformatted in the planar mode; this can save
CPU time in the host computer in most video conferencing applications. The Y and U/V
components are packed by the ZR36506 in 64-byte packets, and have the following structure:
Packet Number
Contents
1
Pixels 0-63 of the Y-Image.
2
Pixels 64-127 of the Y-Image.
3
Pixels 0-63 of the U-Image (or V-Image).
The U-Image and V-Image are half-size of
the Y-Image in both horizontal and vertical
dimensions. The ZR36506 produces a line of
U pixels followed by a line of V pixels, and
then U pixels again in a toggling manner.
These pixels are always packed in this
modulo-3 packet. The host computer knowing the frame-size - can separate
between U and V components.
8-10
4
Pixels 128-191 of the Y-Image.
5
Pixels 192-255 of the Y-Image.
6
Pixels 64-127 of the U-Image (or V-Image).
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Video Buffer Control registers
The ZR36506 uses a pre-defined SDRAM space to store the output video data before being
transferred to USB; this buffer is called Video Buffer, and is used as a FIFO which observes data
bursts at the video frame rate (up to 30 Hz) and supplies data bursts at the USB frame rate (1000
packets per second).
The size of the video buffer is set by the host computer via the SDRAM registers. Depending on
USB bandwidth and output frame size and rate, this buffer may become full in the middle of
video streaming. In this case, additional frames will be dropped by the ZR36506 until enough
free space is available in the buffer. When operating in Compressed mode, the host computer can
alter the compression rate by modifying some threshold registers on the fly. This may prevent
most "buffer-full" events and allows for consistent frame-rate (i.e. frames are not dropped). To
enable the host computer to monitor the status of the video buffer and control frame-dropping,
the ZR36506 provides the following registers:
Parameter
Register
Address
Usage
BUF_THR [9..0]
Reg.48/d7-d0
Reg.49/d4-d3
Minimum remaining buffer space to begin
frame dropping (in 2 Kbyte units). "BufferFull" occurs when remaining buffer space is
less than the value in this register. The host
computer sets this register according to the
maximum space that a video frame may
occupy.
VID_BUF_LEFT
[9..0]
Reg.62/d7-d0
Reg.65/d1-d0
This is a read-only register that provides the
actual remaining buffer space (in 2 Kbyte
units). The host computer can prevent
"Buffer-Full" occurrence by monitoring this
register and changing compression
thresholds.
LFP [19..0]
Reg.63/d7-d0
Reg.64/d6-d0
Reg.65/d3-d2
This is a read-only register that provides the
SDRAM address for data write in the video
buffer at the end of every video frame (in 16
byte units). The host computer can keep track
of the current compression rate by
monitoring this register from time to time.
Video Input Interface
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Special Video Control bits
The ZR36506 has two special bits in the VIN_REG2 register, which may alter the input video
sequence. These bits are normally used during still capture operation and are specified in the
following table:
Parameter
Register
address
Usage
SEND_FID
Reg.28/d5
VIN_REG2
Send FID information in frame header data.
The FID information is used for
reconstructing a 2-field frame from an
Interlaced camera.
KEEP_BLANK
Reg.28/d7
VIN_REG2
0:
Default value.
1:
FID bit overrides bit 0 of
Frame_Phase[4..0].
Force a "blank" position on the input video
frame source, and drop new frames. Software
driver must switch this bit from '0' to '1'
during a true blank position.
0:
Default value.
1:
Keep existing blank longer by
forcing "blank".
USB Pipe Video Data Format
Data Packets
Video data is received by the host computer as a stream of bytes via the End-Point #2
Isochronous pipe. There is an incoming data packet every 1 millisecond (every USB-Frame) and
its size is limited by the maximum bandwidth that was initially set for End-Point #2. The
maximum byte-count for each packet is one of the following numbers: 959 (for 7.5Mb/sec), 895,
831, 767, 703, 639, 575, 511, 447, 383, 319, 255, 191, 127, or 63 (for 0.5Mb/sec). Regarding the
data on the USB - the data of a new video frame always starts in a new data packet, so in most
cases the last packet of a video frame is shorter than a normal packet. The ZR36506 sends one or
more empty packets between every two video frames.
8-12
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Video Frame Synchronization
In all modes of operation (Compressed or Raw video), two concurrent video frames will be
separated by at least one empty data packet. The ZR36506 software driver uses this to detect a
Start-Of-Video-Frame. Additionally, the first two bytes of the video frame header contain a
Start-Of-Video-Frame-Pattern (=0xAA55), which is used by the software driver as a qualifier to
verify that the data represents an uncorrupted video frame.
Video Frame Header
A header precedes every video frame. The header data is organized in Little-Endian format, i.e.
the LSB of a 2-byte parameter precedes the MSB (LSB occupies the lower address). The same
header format is used in all modes of operation. The following table specifies the parameters of
this header:
Parameter
Offset Name
No. of
Bytes
Description & Specification
0
Vid_Frm_Patt
2
0xAA55 = Start of Video-Frame Pattern.
2
Header_Length
1
Number of bytes in this header = 12.
3
Frame_Numb
1
D4-D0: Unsigned integer. Incremented (mod 32)
on every frame that is delivered to host
computer.
4
Frame_Phase
1
D7:
Capture_Pressed (active if '1').
D6:
Resumed ('1': first frame after Suspend).
D5:
spare
D4-D0: Unsigned integer. Incremented mod 30 on
every frame that is acquired from camera.
D7-D5: spare.
5
Frame_Latency
1
Unsigned integer. Number of milliseconds elapsed
from the moment that the camera began delivery of
this frame to ZR36506, to the moment that the
ZR36506 began delivery of frame-header to USB.
6
Data_Format
1
D7:
'0'=Vendor Specific (like ZR36506)
(‘1’=Class Specific).
D6:
'0'=Raw Data.
'1'=Compressed Data.
D5-D0: Vid_Format_Code:
0x03 = YUV-4:2:2.
0x14 = YUV-4:2:0 Planar.
0x06-0x12, 0x15-0x1F = spare.
0x20 = Zoran's Compression.
Video Input Interface
8-13
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Parameter
Offset Name
7
Format_Param
No. of
Bytes
1
Description & Specification
D7:
Intra_Frame
('1' = Intra, '0' = Inter + Intra). This bit
should be ignored in raw data frames.
D6:
spare.
D4-D0: Pix_Depth (number of bits per pixel).
These bits should be ignored in
compressed data frames.
8
Frame_Width
2
Unsigned Word integer - number of pixels per line.
10
Frame_Height
2
Unsigned Word integer - number of lines in frame.
8-14
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9
SDRAM CONTROL AND INTERFACE
MAU (Memory Access unit)
The MAU is responsible for all data transfers between the internal units and external SDRAM.
The SDRAM in use is organized as two Banks of 524,288-Word X 16 Bit and is accessible via a
16 Bit data bus. The design is based on 3.3 V powered SDRAMs manufactured by Micron
(MT48LC1M16A1) and Fujitsu (MB81F161622C). The SDRAM operation modes employed by
the MAU are:
§ Full-Page-Mode-Read
§ Full-Page-Mode-Write
§ Burst-of-8-Read
§ Auto Precharge Mode
§ Manual two Bank Precharge
§ CAS Latency = 2 to support SDRAMS that do not have CAS Latency = 1(also sufficient for
operating frequency of 48 MHz). Both 8.2 ms and 16 ms refresh rates are supported.
Refer to the following MAU main block diagram:
From CVI
MAU
usb _dat_reg
clk48
rst48n
nextvf
next8w
pwr_dwn
vdw_buf_rd
From DVC
fdl_dat_req
DSM
DRAM
State
Machine
vid_mem_req
frame_end_pre
frame_end
VDW
Video
Data
Write
buf_state_idle
buf_state_last
eo8w
DIB
DRAM
Interface
Block
fdl_fifo_rd
fdl_fifo_wr
vdw_ret
cke
csn
rasn
buf_state_idle_pre
buf_state_last_pre
vdw_el
RFU
Refresh and
Initialization
Unit
DVC
drm_cont
FDL
Frame
Delay
Line
casn
wen
SDRAM
From RBCS
drm_ prm
CVI
ur_fifo_wr
URU
USB
Read
Unit
pix_rst48n
da [11:0]
dd [15:0]
SDRAM Control and Interface
9 -1
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The MAU performs the following tasks:
§ Read data from SDRAM to USB Fifo
The Universal Serial Bus can transfer 12 Mbits/sec – while this is considered the USB peakrate, the maximum average rate that can be used for video data is approximately 8 Mbits/sec
(Iso 1023 bytes every 1ms). The MAU performs an 8-word Read operation to fill the USB
Fifo. This lasts about 340 ns, and is expected to be performed every 10.6 us on average
(assuming continuous 12 Mbit/sec demand).
§ Read & Write data from/to SDRAM to obtain one video-frame delay
The video source for this operation is the reconstructed image from the Digital Video
Compressor (DVC), and its timing is derived from the Digital Video Scaler (DVS) output.
There are two FIF Os for this task in the DVC - one for Write to SDRAM operations and one
for Read from SDRAM operations. The data that is written to SDRAM from the Write Fifo
is read back from SDRAM to the Read Fifo after a delay of approximately one video frame.
This task is active only in Compressed Video mode, and its video format is always 4:2:0
(12 bits/pxl). The pixel rate is 12.2727 MHz for NTSC and 14.75 MHz for PAL (or
9.545454 MHz and 14.31818 MHz in Sanyo cameras), so the maximum rate in 16-bit words
is approximately 11.0625 Mw/sec for PAL when full frame-size is used. In all these
systems, the active line lasts within 53 us, followed by a 10-11 us blank with no activity.
The MAU uses 32-word Page-Read and 32-word Page -Write operations to perform the
transfer. This lasts approximately 1600 ns, and is expected to be performed every 2893 ns in
worst cases (at rates of 11.0625 Mw/sec).
§ Write output video-data to SDRAM
This is the same data that is later on read back into the USB Fifo. The source for this data is
the Video Data Buffer which is located in the DVC (Digital Video Compressor). When
operating in Compressed Video mode, the Video Data Buffer is first filled with compressed
data of at least one video frame line (one line for full-frame size, and additional lines for
small frame sizes). This takes place during the active-line time interval, so that the Video
Data Buffer is ready to be transferred to SDRAM when the video blank time interval begins.
The blank time-interval lasts approximately 10 us, and during this time the MAU writes up
to 384 words to SDRAM, using Page-Write mode. The MAU uses a Page -Write operation,
which lasts approximately 8400 ns (if N=384 in worst cases, where the MAU encounters
end of 256-word SDRAM line twice during the burst). When operating in Raw Video mode,
the Video Data Buffer is split into two 192-word buffers. At the same time that one buffer is
being filled with Raw video data (this time arriving from the DVS), the other buffer is being
transferred to SDRAM. This process is carried out during the active-line time, as well as
during the blank time - whenever there is data ready to be written to SDRAM. Residual data
is transferred at the end of the video frame.
§ SDRAM Refresh
A refresh operation lasts 60 ns and uses Auto Refresh. The ASIC supports both 8.2 ms and
16 ms refresh SDRAMs (32 ms, 2048-cycle refresh or 64 ms, 2048-cycle refresh). 8 ms rate
produces a 32 mS x 2048 cycle refresh (15.625 uS between refresh tasks), while 16 ms rate
produces a 64 mS x 2048 cycle refresh (31.25 uS between refresh tasks).
9-2
SDRAM Control and Interface
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§ SDRAM Initialization
SDRAM requires initialization after Reset, Suspend and power down. Users should write 1
to register 18 (DRM_CONT) bit 1 of RBCS after these events, allowing the SDRAM at
least 100 microseconds to stabilize internal circuitry. The MAU then automatically performs
an SDRAM initialization sequence and allows other memory tasks to be performed. This
task lasts approximately 600 nS.
§
In the beginning of every task, the MAU programs the
Mode Register, utilizing the address bus.
§
CAS Latency is always set to 2, Burst type is always
sequential, and Burst length is set to 8 for USB Fifo read
tasks and to Full-Page for all other tasks. Only the USB
Fifo read task employs Auto Precharge. All other tasks
(Read and Write) perform a PALL command during task
command sequence.
The following table specifies the registers that are used to support SDRAM:
SDRAM and Memory Buffer Setup Registers
Register
Address
18
Register
Name
Function
DRM_CONT
d0:
REF
Default
Value
00H
'0' = 8.2 ms refresh rate.
'1' = 16 ms refresh rate.
d1:
SDRAM_EN.
d2:
RES_UR Restart video out buffer read
logic.
d3:
RES_FDL Restart video-frame-delay
logic.
d4:
RES_VDW Restart video out buffer
write logic.
d5-d7: reserved.
19
DRM_PRM1
d0-d3: Bits 16 to 19 of FDL_LAST_WORD.
00H
d4-d7: Reserved.
20
DRM_PRM2
d0-d3: Bits 8 to 11 of FDL_1ST_LINE.
00H
d4-d7: Reserved.
21
DRM_PRM3
d0-d3: Bits 8 to 11 of VDW_1ST_LINE.
00H
d4-d7: Bits 8 to 11 of VDW_LAST_LINE.
SDRAM Control and Interface
9 -3
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Register
Address
Register
Name
Function
Default
Value
22
DRM_PRM4
d0-d7: Bits 0 to 7 of FDL_1ST_LINE.
00H
23
DRM_PRM5
d0-d7: Bits 0 to 7of FDL_LAST_WORD.
00H
24
DRM_PRM6
d0-d7: Bits 8 to 15 of FDL_LAST_WORD.
00H
25
DRM_PRM7
d0-d7: Bits 0 to 7 of VDW_1ST_LINE.
00H
26
DRM_PRM8
d0-d7: Bits 0 to 7 of VDW_LAST_LINE.
00H
Video Setup and Control Registers
Register
Address
Register
Name
Function
Default
Value
48
BUF_THR
d7-d0: Threshold for buffer space Frame-Drop
decision (given in units of 2 KBytes).
00H
49
DVI_YUV
d2-d0: Code for YUV re-order processor.
00H
d4-d3: BUF_THR[9..8] Extension for 16 Mbit
SDRAM.
9-4
d6:
SLOW_CLK12 '1' Select 12 MHz for
Horizontal blank.
d7:
SLOW_CLK16 '1' Select 16 MHz for
Horizontal blank.
d5:
'0' reserved.
SDRAM Control and Interface
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CLK48 Output
Register
Address
0
Register
Name
Function
PWR_REG
d0:
WD_EN: '1' Enables USB Watch-Dog
timer.
d1:
SSP ND_EN: '0' Enables SuspendResume logic.
d2:
RES2
'0' Restarts End-Point #2 logic.
'1' Releases.
d3:
CLK48_EN - '1' Enables 48 MHz at
CLK48 output pin.
d4:
EP234_EN - ‘1’Enables SPO output in
USB Mode.
d5:
PWR_VID - '1' Video-logic Power-On.
d6:
reserved.
d7:
E2_EN - '1' Enables EEPROM R/W.
SDRAM Control and Interface
Default
Value
00H
9 -5
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10 CAMERA CONTROL SERIAL PORT
The ZR36506 has a dedicated Programmable Serial Port intended to be used for camera control.
This port has several modes of operation, where the ZR36506 is always the bus-master (one of
the more useful modes is IICC). The programmable serial port is controlled by the host computer
via the following registers of the ZR36506 register bank: SER_MODE, SER_ADRS,
SER_CONT, SER_DAT1, SER_DAT2, SER_DAT3, and SER_DAT4.
Camera control uses 3 dedicated pins on the ZR36506:
§ IICCK is an Open Drain output pin, used to drive the serial port clock signal. It is supposed
to be connected to an external 3.3-10KΩ Pull-Up resistor to 3.3.
§ IICDT is an Open-Drain bi-directional pin, used to send and receive the serial port data. It is
supposed to be connected to an external 3.3-10KΩ Pull-Up resistor to 3.3.
§ SENS is an Open Drain output pin, used as a serial control strobe signal in some modes of
operation. It is supposed to be connected to an external 3.3-10KΩ P ull-Up resistor to 3.3.
There are 6 modes of operation available to the camera control port. These are listed in the
following table, and described in more detail in the following paragraphs:
Mode
Number
Mode Name
Description
0
Soft
Bit-level Software controlled mode.
1
SIO
Serial clocked I/O.
2
IIC LRACK
IICC with Last Byte Read Acknowledged.
3
IIC LRNACK
IICC with Last Byte Read Not Acknowledged.
4
CAM1
Camera 1 - refer to timing diagram.
5
CAM2
Camera 2 - refer to timing diagram.
Modes number 1-5 are referred to as automatic modes: in these modes, the host computer only
needs to write the data bytes (and, in some of them, the device address byte) in certain registers
(SER_DAT1 to SER_DAT4, and SER_ADRS), and initiate a transfer request. Similarly, the host
computer can read received data from the same registers.
Camera Control Serial Port
10 -1
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The SER_MODE register has some specific bits that can turn the automatic modes into more
flexible serial data formats. These register bits are:
§ CLK_RATE
Writing '0' to this bit will select a 93.75 KHz clock at the IICCK output. Writing '1' to this
bit will select a 1.5 MHz clock at the IICCK output.
§ CLK_POL
Writing '0' to this bit will select the normal polarity at the IICCK output. Writing '1' to this
bit will select an inverted polarity at the IICCK output.
§ VSYNC
Writing '0' to this bit will select an immediate transfer. Writing '1' to this bit will delay startof-transfer to camera blank period.
Another register that is used by the automatic modes is the SER_CONT register. This register is
used by the host computer to control the serial port machine. The SER_CONT register consists
of the following control bits:
§ SER_LEN
This field contains a 3-bit binary integer that specifies the number of data bytes that the host
wishes to transfer in the serial transaction (the address byte is not counted). The range of
this parameter is 0 to 4.
§ SER_DIR
Writing '0' to this bit selects a write operation (host to camera). Writing '1' to this bit selects
a read operation (camera to host).
§ SER_GO / SER_BUSY
This is used as both a command and a status bit. Writing '1' to this bit will initiate a serial
transfer request. The serial transfer will either start immediately or wait until the vertical
blank time interval is detected at the camera video signal (depends on the VSYNC bit). The
SER_GO / SER_BUSY bit will remain '1' until the end of the transaction, to indicate to the
host computer when a new transaction may be initiated.
§ NACK_RCV
This is a read-only bit and is used in modes 2 and 3 only (IICC modes). The ZR36506, after
completing a serial transfer in this mode, reports to the host computer via this bit whether or
not all transmitted bytes were acknowledged by the camera (this includes the address byte
and all data bytes that were sent from the host to the camera). A '0' in this bit indicates all
ACK, and a '1' indicates a NACK for one or more bytes.
§ NO_STOP
This bit is used in modes 2 and 3 only (IICC modes) and enables multiple transactions
inside a single START / STOP frame. When set to '1', it informs the serial machine to omit
the STOP pattern at the end of the following transaction. Combined with the CONTINUE
bit, this enables the software driver to perform long transactions (i.e. for downloading the
Gamma-Correction table into camera DSP).
10 -2
Camera Control Serial Port
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§ CONTINUE
This bit is used in modes 2 and 3 only (IICC modes), and enables multiple transactions
inside a single START / STOP frame. When set to '1', it informs the serial machine to
prepare for multiple transaction mode. It will never affect the following transaction, but the
one coming after it, which will not contain a START pattern.
The following pages specify all 6 modes of operation for the camera-control serial port.
Soft Mode: (MODE=0)
This mode is selected when the MODE field (d7-d4) of the SER_MODE register is set to 0. In
this mode the host computer may access the serial port pins directly in order to enable control of
cameras that are not supported by the other automatic modes.
In Soft mode, the value of the CLK_OUT bit (d0) is reflected in the IICCK output pin. A write
operation to the DAT_IO bit (d1) sets the value of the IICDT pin. A read operation from the
same DAT_IO bit reads the actual voltage level at the IICDT pin. The value of the SENS_OUT
bit (d2) is reflected in the SENS output pin.
SIO Mode: (MODE=1)
This is the Serial Clocked I/O automatic mode, and is selected when the MODE field (d7-d4) of
the SER_MODE register is set to 1. The following waveform describe the SIO mode:
IICCK
IICDT
x
D7
D6
D5
D4
D3
D2
D1
D0
x
SENS
NOTE: In both Read and Write sequence, data is sampled in the up-going edge of the clock IICCK.
IICCK
IICDT
SENS
Byte 1
Byte 2
Byte 4
NOTE: In the SIO mode 1 to 4 bytes are written or read.
Camera Control Serial Port
10 -3
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IIC LRACK Mode: (MODE=2)
This is the IIC LRACK (Last Read Acknowledged) automatic mode, and is selected when the
MODE field (d7-d4) of the SER_MODE register is set to 2. In this mode, the IICCK frequency
is set to 93.75 KHz.
IICCK
IICDT
x
D7
D6
D5
D4
D3
D2
D1
D0
Ack
NOTE: In both Read and Write sequence, data should be stable during the '1' state of the clock IICCK.
D7-D0 are sent by transmitter, Ack is sent by receiver.
Start
IICCK
IICDT
Stop
Write ADDRESS
R/W Byte 1
R/W Byte 4
NOTE: Start is defined when the IICDT turns from '1' to '0' while the IICCK is '1'. Stop is defined when
the IICDT turns from '0' to '1' while the IICCK is '1'. The Address byte is written like any other byte.
IICCK
IICCK
Stop
IICDT
Ack
End of Write sequence
Stop
IICDT
Ack
End of Read sequence
In this mode, the host defines the camera address byte and the data bytes to be written to the
camera in the appropriate registers. The ZR36506 then sends these bytes automatically.
Similarly, the ZR36506 may read data bytes from the camera. The ZR36506 acknowledges the
last byte read like all other bytes.
By using the NO_STOP and CONTINUE bits, a concatenation of multiple IICC transactions is
possible, in order to send or receive more than 4 bytes in a single START / STOP frame.
Additionally, by using these control bits, write/read operations may be combined with a single
STOP pattern at the end. Note that the SER_LEN parameter may be set to 0 to further support
the concatenation operation mode.
10 -4
Camera Control Serial Port
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IIC LRNACK Mode: (MODE=3)
This is the IIC LRNACK (Last Read Not Acknowledged) automatic mode, and is selected when
the MODE field (d7-d4) of the SER_MODE register is set to 3. In this mode, the IICCK
frequency is set to 93.75 KHz.
In this mode, the host defines the camera address byte and the data bytes to be written to the
camera in the appropriate registers. The ZR36506 then sends these bytes automatically.
Similarly, the ZR36506 may read data bytes from the camera. The ZR36506 does not
acknowledge the last byte read from camera. This is done as a signaling to the camera that no
more bytes are needed. The waveforms for this mode of operation are specified be low.
IICCK
IICDT
x
D7
D6
D5
D4
D3
D2
D1
D0
Ack
NOTE: In both Read and Write sequence, data should be stable during the '1' state of the clock IICCK.
D7-D0 are sent by transmitter, Ack is sent by receiver.
Start
Stop
IICCK
IICDT
Write ADDRESS
R/W Byte 1
R/W Byte 4
NOTE: Start is defined when the IICDT turns from '1' to '0' while the IICCK is '1'. Stop is defined when
the IICDT turns from '0' to '1' while the IICCK is '1'. The Address byte is written like any other byte.
IICCK
IICCK
Stop
IICDT
Ack
End of Write sequence
Stop
IICDT
Nack
End of Read sequence
In this mode, the host defines the camera address byte and the data bytes to be written to the
camera in the appropriate registers. The ZR36506 then sends these bytes automatically. The
ZR36506 may also read data bytes from the camera. The ZR36506 does not acknowledge the
last byte read (NACK).
By using the NO_STOP and CONTINUE bits, concatenation of multiple IICC transactions is
possible, in order to send or receive more than 4 bytes in a single START / STOP frame.
Additionally, by using these control bits, write/read operations may be combined with a single
STOP pattern at the end. Note that the SER_LEN parameter may be set to 0 to further support
the concatenation operation mode.
Camera Control Serial Port
10 -5
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CAM1 Mode: (MODE=4)
This mode is selected when the MODE field (d7-d4) of the SER_MODE register is set to 4.
In this mode, the IICCK frequency must not exceed 10 MHz.
Three signals are used: IICCK, IICDT and SENS. The host defines the desired camera register
address byte and a single data byte to be written to that register in the appropriate ZR36506
registers. The ZR36506 first sends the address and then the data automatically. Similarly, the
ZR36506 may read a data byte from any given camera register. The waveforms for the CAM1
mode are specified in the following diagram. Note that every byte transfer has its own start
condition, which indicates one of 3 possibilities: Address Write, Data Write, or Data Read.
IICCK
0
IICDT
0
A7
A6
A5
A4
A3
A2
A1
A0
D6
D5
D4
D3
D2
D1
D0
SENS
Start Address Write
IICCK
IICDT
0
1
D7
SENS
Start Data Write
IICCK
IICDT
1
0
SENS
D7
D6
D5
D4
D3
D2
D1
D0
Note: NT1004 relieses data signal (IICDT='1') at this point
Start Data Read
Register Write operation:
Address Write
Data Write
Register Read operation:
Address Write
Data Read
NOTE: A transaction consists of Address Write, followed by Data Write or Data Read.
10 -6
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CAM2 Mode: (MODE=5)
This mode is selected when the MODE field (d7-d4) of the SER_MODE register is set to 5. In
this mode, the IICCK frequency must not exceed 10 MHz.
Only two signals are used: IICCK and IICDT. The host defines the desired camera register
address byte and a single data byte to be written to that register in the appropriate ZR36506
registers. The ZR36506 first sends the address and then the data automatically. Note that in this
mode, both address and data consist of 7 bits only. There is no way to read data from the camera.
The waveforms for the CAM2 mode are specified in the following diagram. Note that every byte
transfer has its own transfer start signaling (which is identical for both address and data),
followed by an Address Write condition or a Data Write condition.
IICCK
0
1
IICDT
A6
A5
A4
A3
A2
A1
A0
D4
D3
D2
D1
D0
Address Write
Transfer start
IICCK
0
IICDT
0
D6
D5
Data Write
Transfer start
Register Write operation:
Address Write
Data Write
NOTE: Data is sampled on the down-going edge of the clock IICCK. A transaction consists of Address
Write, followed by Data Write.
Camera Control Serial Port
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11 EXTERNAL EEPROM
The ZR36506 provides a full USB compliant solution without the need for an external EEPROM
(USB Vendor ID is pin programmable). When Unicode names are required, the ZR36506 may
use an external 3.3 V 2 Kbyte Serial EEPROM as an optional source for USB descriptors. There
are several vendors that produce these 8-pin EEPROM chips, which are pin-to-pin compatible.
Normally, the external EEPROM will only be read in a working device (soon after USB
insertion). The ZR36506 supports on-board EEPROM programming, which can be used to alter
some USB descriptors - especially the product serial number. The ZR36506 register bank
includes special registers to perform a byte Read or Write operation to a given address of the
EEPROM.
In addition to the USB Descriptors data, the external EEPROM may contain some assembler
code segments for the V8. These code segments are used as modification patches to override the
original internal V8 software.
EEPROM Data Structure
The EEPROM contains the device descriptor, up to 4 configuration descriptors, and up to 15
string descriptors in up to 7 different languages. The following diagram specifies the block
structure of the EEPROM data:
EEPROM
ADDRESS (hex)
000
EEPROM
CONTENT
SUPPORTED
UNICODE
LANGUAGES
TABLE
The first byte in this table is the total
number of bytes in the table. The second
byte is the "STRING" code of the USB
standard. This is followed by a list of up to
7 valid codes of Unicode languages .
< 010
010
TABLE OF
DESCRIPTOR
POINTERS
don't care
8*k
TABLE OF
DESCRIPTORS
Each pointer consists of 2 bytes: The first
one identifies the descriptor, and the
second contains the 8 most significant bits
of the address where the descriptor starts.
The end of this table is identified by the
value 0x00 instead of a valid descriptor
identifier.
Each pointer in this table has its descriptor
in the TABLE OF DESCRIPTORS.
0 to 7 bytes skipped, because next table
must start in a 8*k address.
Each descriptor must start in a 8*k
address. DEVICE and STRING descriptors
are the same as specified in the USB standard. In CONFIGURATION
descriptors, the first 2 bytes contain a 16 bit unsigned value for the number of bytes
that the descriptor contains, and all the
other bytes of the descriptor are as
specified in the USB-standard (this is
because this type of descriptors actually
consist of a tree of small USB-descriptors,
and can result in a more than 255 byte
vector).
Each descriptor must have an identifier
and a pointer in the TABLE OF
DESCRIPTOR POINTERS.
V8 Downloadable
Code
< 2048
External EEPROM
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V8 Downloadable Code
The serial EEPROM in the ZR36506 application contains two files of data:
§ USB descriptor data.
§ Standalone mode application parameters and V8 downloadable data code.
Refer to the following diagram for EEPROM general data structure:
serial EEPROM - 2KB
0x000:
USB Descriptors data
tables
(as specified above)
block#1:
length#1
LSB(DownloadAddrs#1)
MSB(DownloadAddrs#1)
(length#1 bytes)
block#2:
length#2
LSB(DownloadAddrs#2)
MSB(DownloadAddrs#2)
block#n:
End of Data indicator:
0x7FE:
0x7FF:
11 -2
0x00
LSB(block#1)
MSB(block#1)
Block #1 of
data to be
downloaded by
V8
Block #2 of
data to be
downloaded by
V8
Block #n of data
End of data
Download
Data Locator
External EEPROM
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In order to download all data blocks from EEPROM, the V8 Software will perform the following
steps:
1.
Load two bytes from EEPROM to temporary space in SRAM, starting from EEPROM
address 0x7FE. This 16-bit value – denoted by block#1 - will be the Data Locator pointer.
2.
Use the Data Locator pointer block#1 to define the start address of the first data block to be
downloaded. Read 3 bytes from this EEPROM address into a temporary space in SRAM.
The first byte defines the total number of bytes in block#1 that should be downloaded, and
is denoted by length#1. The other two bytes define a 16-bit start address in the V8 address
space for the whole block to be downloaded to. This parameter is denoted by
DownloadAddrs#1 and normally points to some byte address in the internal SRAM.
3.
Download length#1 bytes from EEPROM address block#1 +3 to given address
DownloadAddrs#1 in SRAM (or to any other destination in this address).
4.
Repeat steps 2 and 3 to download all the other blocks from EEPROM to destination
addresses. The address of the beginning of the new block always follows the end of the last
block. End the download process if the first byte of the “new” block is 0x00 – which
denotes End of Data.
Supported UNICODE Language Table:
This table is used as the "string" of index 0, which is defined in the USB-Standard. This "string"
is actually a list of all the LANGIDs that are supported by the device. The first two bytes in this
table are needed for the standard format of USB String descriptors.
EEPROM
Address
(Hex)
EEPROM
Data
(Hex)
Description
000
blength
Number of bytes in this table (4-16). This is needed for the
standard format of USB String descriptors.
001
STRING
descriptor
type (=03)
Code of STRING descriptor type (=03). This is needed for the
standard format of USB String descriptors.
002
LANGID#1
(LSB)
Bits 7-0 of Language-Identifier of language #1.
003
LANGID#1
(MSB)
Bits 15-8 of Language-Identifier of language #1.
004
LANGID#2
(LSB)
Optional. Bits 7-0 of Language-Identifier of language #2.
External EEPROM
This language must be supported, and it is also used as the
default language if the host specifies a language that is not
included in this list.
Must contain FF if not used.
11 -3
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EEPROM
Address
(Hex)
EEPROM
Data
(Hex)
005
LANGID#2
(MSB)
Optional .Bits 15-8 of Language-Identifier of language #2.
LANGID#3
(LSB)
Optional. Bits 7-0 of Language-Identifier of language #3.
LANGID#3
(MSB)
Optional.Bits 15-8 of Language-Identifier of language #3.
LANGID#4
(LSB)
Optional. Bits 7-0 of Language-Identifier of language #4.
LANGID#4
(MSB)
Optional.Bits 15-8 of Language-Identifier of language #4.
LANGID#5
(LSB)
Optional. Bits 7-0 of Language-Identifier of language #5.
LANGID#5
(MSB)
Optional.Bits 15-8 of Language-Identifier of language #5.
LANGID#6
(LSB)
Optional. Bits 7-0 of Language-Identifier of language #6.
LANGID#6
(MSB)
Optional.Bits 15-8 of Language-Identifier of language #6.
LANGID#7
(LSB)
Optional. Bits 7-0 of Language-Identifier of language #7.
LANGID#7
(MSB)
Optional.Bits 15-8 of Language-Identifier of language #7.
006
007
008
009
00A
00B
00C
00D
00E
00F
11 -4
Description
Must contain FF if not used.
Must contain FF if not used.
Must contain FF if not used.
Must contain FF if not used.
Must contain FF if not used.
Must contain FF if not used.
Must contain FF if not used.
Must contain FF if not used.
Must contain FF if not used.
Must contain FF if not used.
Must contain FF if not used.
External EEPROM
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Table of Descriptor Pointers
This table is used by the ZR36506 to locate the start address of a given descriptor. Each item in
this table consists of a Descriptor Identifier byte (first byte), and EEPROM address (second byte
- contains only 8 most significant bits of address. The other 3 bits always equal '000').
EEPROM
Address
(Hex)
EEPROM
Data
(Hex)
010
DDI (=40)
Device-Descriptor Identifier code (=40). This descriptor
must exist in EEPROM.
011
DD address
Device-Descriptor address in this EEPROM (in this
table, units are in 8-byte steps for address pointers).
012
CDI#0
(=20)
Configuration-Descriptor Identifier # 0 code (=20). This
descriptor must exist in EEPROM.
Description
bits 7-2: '001000' (code of Configuration-Descriptor).
bits 1-0: '00' (Configuration Index).
013
CD#0
address
Configuration-Descriptor #0 address.
CDI#1
(=21)
Optional. Configuration-Descriptor Identifier # 1 code.
CD#1
address
Optional. Configuration-Descriptor #1 address.
CDI#2
(=22)
Optional. Configuration-Descriptor Identifier # 2 code.
CD#2
address
Optional. Configuration-Descriptor #2 address.
CDI#3
(=23)
Optional. C onfiguration-Descriptor Identifier # 3 code.
CD#3
address
Optional. Configuration-Descriptor #3 address.
SDI#1,0
(=90)
String-Descriptor Identifier Lang#1 Indx#0 (=90).
This descriptor is actually the first table in EEPROM.
bit 7:
'1'.
bits 6-4: '001' (Language number in language-table).
bits 3-0: '0000' (String Index).
External EEPROM
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EEPROM
Address
(Hex)
11 -6
EEPROM
Data
(Hex)
Description
SDI#1,0
address
(=00)
String-Descriptor #1,0 address (=00).
SDI#2,0
(=A0)
String-Descriptor Identifier Lang#2 Indx#0 (=A0). This
descriptor is actually the first table in EEPROM.
SDI#2,0
address
(=00)
String-Descriptor #1,0 address (=00).
SDI#3,0
(=B0)
String-Descriptor Identifier Lang#3 Indx#0 (=B0). This
descriptor is actually the first table in EEPROM.
SDI#3,0
address
(=00)
String-Descriptor #3,0 address (=00).
SDI#4,0
(=C0)
String-Descriptor Identifier Lang#4 Indx#0 (=C0). This
descriptor is actually the first table in EEPROM.
SDI#4,0
address
(=00)
String-Descriptor #4,0 address (=00).
SDI#5,0
(=D0)
String-Descriptor Identifier Lang#5 Indx#0 (=D0). This
descriptor is actually the first table in EEPROM.
SDI#5,0
address
(=00)
String-Descriptor #5,0 address (=00).
SDI#6,0
(=E0)
String-Descriptor Identifier Lang#6 Indx#0 (=E0). This
descriptor is actually the first table in EEPROM.
SDI#6,0
address
(=00)
String-Descriptor #6,0 address (=00).
SDI#7,0
(=F0)
String-Descriptor Identifier Lang#7 Indx#0 (=F0). This
descriptor is actually the first table in EEPROM.
SDI#7,0
address
(=00)
String-Descriptor #7,0 address (=00).
External EEPROM
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EEPROM
Address
(Hex)
EEPROM
Data
(Hex)
SDI#n1,m1
Description
Optional. String-Descriptor Identifier Lang#n1
Indx#m1.
bit 7:
'1.'
bits 6-4: n1 (Language number in language-table).
bits 3-0: m1 (String Index).
SDI#n1,m1
address
Optional. String-Descriptor #n1,m1 address.
SDI#n2,m2
Optional. String-Descriptor Identifier Lang#n2
Indx#m2.
SDI#n2,m2
address
Optional. String-Descriptor #n1,m1 address.
SDI#nk,mk
Optional . String-Descriptor Identifier Lang#nk
Indx#mk.
SDI#nk,mk
address
Optional. String-Descriptor #nk,mk address.
EOT (=00)
End-Of-Table code (=00).
Table of Descriptors
This table contains the DEVICE descriptor, all CONFIGURATION descriptors, and all STRING
descriptors. DEVICE and STRING descriptors are organized exactly as specified in the USB
standard. CONFIGURATION descriptors start with a word (= 2 bytes - LSB first, then MSB)
that specifies the number of total bytes in the descriptor (excluding the first 2 bytes), followed by
the descriptor's body, which is organized exactly as specified in the USB standard.
§
The Supported Unicode Languages Table is also used as
STRING descriptor #0 for all languages.
§
There is one and only one DEVICE descriptor, which is
always 18 bytes long.
§
A descriptor always starts at an 8*k address of the
EEPROM (the 3 least significant bits of the address are
'000'). This means that there can be up to 7 unused
bytes between any two descriptors in the table.
External EEPROM
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EEPROM Access Registers
EEPROM access via the ZR36506 registers is enabled when the E2_EN bit in the PWR_REG
register is set. The following registers are used for EEPROM access:
Parameter
Register Address Usage
E2_EN
Reg.0/d7 E2_EN
Enable EEPROM access.
0:
Default after Reset. EEPROM access
disabled.
1:
Enable EEPROM Read and Write (1) .
EE_DATA [7..0]
Reg.14 EE_DATA
Data Byte to be written to EEPROM. Also,
last Data Byte that was read from EEPROM.
EE_LSBAD [7..0]
Reg.15 EE_LSBAD
8 Least Significant bits of byte address in
EEPROM to be accessed.
EE_MSBAD [10..8]
Reg.16/d2-d0
3 Most Significant bits of byte address in
EEPROM to be accessed.
EE_DIR
Reg.16/d3 EE_DIR
Select EEPROM access direction:
EE_GO/EE_BUSY
11 -8
Reg.16/d4 EE_GO/
EE_BUSY
0:
Select Write operation to EEPROM.
1:
Select Read operation from
EEPROM.
This is used as both a command and a status
bit. Writing '1' to this bit will initiate a byte
Read or Write. The EE_GO/EE_BUSY bit
will remain '1' till the end of operation, to
indicate to the host computer when a
EEPROM access can begin.
§
A Write operation to the EEPROM requires the EEPROM
WP pin to be grounded.
§
A Write operation requires additional 10 milliseconds in
the EEPROM internal circuits.
External EEPROM
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EEPROM Control Signals
The SCL/PWR0 and SDA pins of the ZR36506 are the EEPROM control signals. The
SCL/PWR0 is used as the clock output, and the SDA signal is used as the data I/O.
If an external EEPROM does not exist (EEPROM = '0'), the ZR36506 automatically uses its
internal ROM for USB descriptors. In this case, the ZR36506 relates to hard-coding of the pins
SCL/PWR0 and PWR1 to determine the current-consumption parameter for the configuration
descriptor. The following table summarizes these two modes of operation:
Internal ROM Mode
External EEPROM Mode
EEPROM pin connected to GND.
EEPROM pin connected to 10 Kbyte
Pull-Up resistor (3.3 V to 5.0 V).
SCL/PWR0 and PWR1 pins are hardcoded to determine device current
consumption for ConfigurationDescriptor:
PWR1
=====
0
0
1
1
SCL/PWR0 Current
======== ======
0
200mA
1
300mA
0
400mA
1
500mA
External Serial 2 K * 8 EEPROM is
connected:
SDA/EEPROM connected to Serial-Data
(SDA).
SCL/PWR0 connected to Serial-Clock
(SCL).
The following timing diagrams and table specify the EEPROM control waveforms that the
ZR36506 generates:
tSU:STA
tHD:STA
tSU:STO
SCL
SDA
Start/Stop Timings
External EEPROM
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tHIGH
tLOW
SCL
tHD:DI
tHD:DO
SDA OUT
tSU:DO
Dn
Dn+1
tSU:DI
SDA IN
Data Valid
Data Valid
Data Timings
Symbol Parameter
11 -1 0
Min
Max
Unit
tSU:STA
START condition setup time
5300
-
ns
tHD:STA
START condition hold time
5300
-
ns
tSU:STO
STOP condition setup time
5300
-
ns
tHIGH
Clock high time
5300
-
ns
tLOW
Clock low time
5300
-
ns
tSU:DO
Data output setup time
2500
2670
ns
tHD:DO
Data output hold time
2500
2670
ns
tSU:DI
Data input setup time
20
-
ns
tHD:DI
Data input hold time
0
-
ns
External EEPROM
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12 ZR36506 USB
AND STATUS
REGISTERS
The ZR36506 has some registers that allow the software driver to directly read and affect some
USB device parameters. These are specified in the following table:
Register
Address
Usage
CONFIG_REG
Reg.1
CONFIG_ REG
Read Only register. Contains the Device
Configuration number.
ADRS_REG
Reg.2/d6-d0
ADRS_REG
Read Only register. Contains the Device
Address.
ALTER_REG
Reg.3/d3-d0
ALTER_REG
Read Only register. Contains the Alternate
setting for End-Point #2 (video bandwidth).
Regarding this value as a binary number in
the range [1,15], the number of bytes sent in
the Isochronous pipe of EP2 in every
millisecond is:
Parameter
N = (16-ALTER_REG)*64 - 1
USB Bandwidth = (16-ALTER_REG)*0.5
Mbit/sec
NEW_ALT
Reg.4/d3-d0
New Alternate setting for End-Point #2,
FORCE_ALTE (video bandwidth), to replace the original
R_REG
setting. This can be used to lower the actual
used bandwidth temporarily, without
notifying the Operating System.
FORCE_ALT
Reg.4/d7
Force New Alternate.
FORCE_ALTE
0:
Use original setting.
R_REG
1:
Select NEW_ALT value.
VFRM_BLNK
Reg.5/d0
Read Only register.
STATUS_REG
0:
Valid region of input video frame.
1:
Blank or unused region of input video
frame.
.
ZR36506 USB and Status Registers
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Parameter
EE_CLK_FORCE
[2..0]
Register
Address
Reg.16/d7-d5
EE_CONT
Usage
Read Only register.
These 3 bits reflect the logical level of the
following pins of the ZR36506:
EE_CLK_FORCE [0] = SCL/PWR0 pin.
EE_CLK_FORCE [1] = PWR1 pin.
EE_CLK_FORCE [2] = SDA pin.
WD_EN &
WD_COUNT[7..0]
12 -2
Reg.0/d0
Reg.53/d7-d0
Some USB host controllers may start an
Isochronous IN transaction too long after the
SOF (Start of USB Frame point). This means
that long IN transactions may exceed the
1 mS time interval of the USB frame, and
cause the USB host controller to disconnect
the device. The ZR36506 uses an internal
Watch Dog timer to eliminate such problems.
The Watch Dog operates if the WD_EN
control bit is set to '1'. It then starts to count
686 uS after the SOF pattern, and terminates
any Isochronous transaction automatically
when reaching the value of the WD_COUNT
register. Every one count is equivalent to
1.33 uS. Note that the value of WD_COUNT
should be no more than 0xE9 in order to take
any effect.
ZR36506 USB and Status Registers
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13 PROGRAMMABLE I/O PINS AND
48 MHZ OUTPUT PIN
The ZR36506 has two programmable I/O pins for general purpose usage. These are IO-1 and IO2 pins, which are Open-Drain.
Each of these pins - if used - must be connected to an external Pull-Up resistor to 3.3-5.0 V (if
not used, it can be tied to GND). The external Pull-Up resistor should be in the range of 1-10
KΩ.
To use these pins as inputs, the host computer should write '1' to the appropriate bit in the
IOPIN_REG register (in the ZR36506 register bank) - these are the IO_1 and IO_2 bits,
respectively. In this condition, the voltage level presented on the IO-1 or IO-2 pin may be read
by the host computer via the appropriate bit ('0' represents <0.8 V, '1' represents > 2.0 V).
To use these pins as outputs, the host computer should write the output value to the appropriate
bit in the IOPIN_REG register; In this condition, and assuming that no external device forces the
voltage level presented on the IO-1 or IO-2 pin, the written value will be reflected ('0' will
generate 0 V, '1' will generate 3.3-5.0 V).
Upon a Power On Reset or a USB-Reset operation, the IO-1 and IO-2 pins are cleared to '0'. In
Suspend mode, these pins are temporarily set to High-z.
The ZR36506 provides a 48 MHz clock output for SDRAM interface and general purpose usage.
The pin CLK48 is dedicated to this, and is enabled when the CLK48_EN bit is set to '1'
(Reg.0/d3). When disabled, the output level in this pin is constant '0'.
The 48 MHz output is 50% duty cycle with 1 nS jitter, and is derived from the external 12 MHz
crystal (an internal analog PLL is used).
Programmable I/O Pins and 48 MHz Output Pin
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14 AUDIO CHANNEL
The audio channel in the ZR36506 is based on a serial 64 – 512 Kbit/s data stream from the
ZR36506 to the host computer (USB Isochronous mode is used for this stream). The 64 – 512
Kbit/s stream comes from an 8,000 / 16,000 S/sec 16 / 8-bit audio sample at the external audio
Codec(s). Two external Codecs should be used for Stereo mode recordings. The 8 / 16 KHz
sampling clock is derived from the 12 MHz external crystal.
The ZR36506 pins for the external Codec interface are BCLK, FS_L, FS_R, and DAT_IN.
The following table specifies the AUDIO_CONT register (Register address = 50):
Bit #
0
1
3-2
4
5
7-6
Name
Description
E_A
'0':
Disables Audio channel. Set FS_L and FS_R outputs to
constant '0'.
If E_B is also '0', BCLK is set to constant '0'.
'1':
Enable Audio channel.
'0':
Disable Bulk Data input. Set BLK_FULL output to
constant '0'.
If E_A is also '0', BCLK is set to constant '0'.
'1':
Enable Bulk Data input.
'00':
8-bit per sample.
'01':
12-bit per sample (Occupies 2 bytes. Bits d3-d0 of second
byte are set to '0000').
'10':
14-bit per sample (Occupies 2 bytes. Bits d1-d0 of second
byte are set to '00').
'11':
16-bit per sample.
'0':
Selects Mono mode. FS_L output is active, FS_R output is
constant '0'.
'1':
Selects Stereo mode. Both FS_L and FS_R outputs are
active.
'0':
Set sampling rate to 8,000 Samp/Sec.
'1':
Set sampling rate to 16,000 Samp/Sec.
'00':
BCLK frequency is not defined.
'01':
Select BCLK frequency = 64 KHz.
'10':
Select BCLK frequency = 1.544 MHz.
'11':
Select BCLK frequency = 2.048 MHz.
E_B
BPS
S/M
FS
BK
Audio Channel
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In addition to the AUDIO_CONT register, there is the AUD_PK_LEN register (Register address
= 51), to select the maximum packet size to be sent via the audio Isochronous pipe. This number
is limited to 128, which is the maximum number of bytes that the ZR36506 audio FIFO can
contain. The software driver should set this register to a value that fits the USB descriptor for the
EP#3 maximum packet length (which is 66, if not using an external EEPROM).
Codec Interface
The Codec Interface is Long Frame Sync Timing based. The BCLK frequency may be selected
to be – 2048 KHz, 1536 KHz, or 64 KHz, which enables the designer to use almost any family of
low cost Codecs available on the market.
In the Long Frame Sync Timing modes, the MSb of the "transmitted" data is always expected
soon after the rising edge of the FS_L (or FS_R) signal. The ZR36506 produces a positive pulse
of 2 BCLK cycles in these output pins every 125 us (8 KHz) or every 62.5 us (16 KHz), which
indicates the start of sample as specified in the following waveform diagram:
Txs
BCLK
Tsx
FS_L
FS_R
Txd2
DAT_IN
XX
MSb
LSb
XX
Txd1
The BCLK is derived from the 12 MHz clock on the crystal. This results in a 4.3% jitter at the
BCLK signal.
The following table specifies the minimum and maximum time intervals for the Codec Interface
waveform diagram:
Parameter
Symbol
Min
Max
Unit
Hold Time from BCLK Low to FS_L / FS_R
High
Txs
180
-
ns
Setup Time from FS_L / FS_R High to BCLK
Low
Tsx
180
-
ns
Delay Time to valid data from FS_L / FS_R
Txd1
-
200
ns
Delay Time from BCLK High to DAT_IN valid
Txd2
-
200
ns
Cj
-
4.3
%
Jitter at the Bit Clock signal BCLK
14 -2
Audio Channel
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15 BULK CHANNEL
The Bulk channel in the ZR36506 is capable of transferring serial data from an external source to
the host computer at a bit rate of up to 2 Mbits/sec. It uses a bulk end point (E.P#4), with a
maximum packet length that may be specified by a value of 1 - 64 bytes (the USB standard does
not allow a bulk packet of more than 64 bytes).
The Bulk channel takes advantage of the existing interface for the audio codec. In order to work
simultaneously with the audio channel, the external data source should be able to stop the data
transfer from time to time - as specified in the Bulk waveform diagram.
The ZR36506 pins for the Bulk channel interface are BCLK, DAT_IN, BLK_EN, and
BLK_FULL. The signals FS_L and FS_R should be monitored by the data source logic, in order
to coexist with the audio channel.
The following table specifies the control registers that are used for controlling the Bulk channel:
Control Name
Description
E_B Reg.50/d1
'0':
Disable Bulk Data input. Set BLK_FULL output to
constant '0'.
If E_A is also '0', BCLK is set to constant '0'.
'1':
Enable Bulk Data input.
BLK_PK_LEN [6..0]
Reg.52/d6-d0
This register specifies the maximum number of bytes to be
sent in a single USB Bulk packet. This must be a number
between 0 and 64, and should fit the content of the USB
descriptor (64 if no external EEPROM used).
This register directly affects the bit rate capability of the
Bulk channel. The actual bit rate is also limited by the
BCLK frequency, which may be 64 KHz, 1544 KHz, or
2048 KHz. A bit rate of 2 Mbits/sec may be reached only on
computers that are capable of performing more than one
packet in a USB frame (OHCI).
Bulk Channel
15 -1
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The following waveform diagram specifies the procedure and timings for the ZR36506 Bulk
interface. Note that the input data is sampled on the falling edge of the BCLK clock signal. The
BLK_EN input is set to '1' by the sending device to indicate the beginning of a byte sequence; it
should always turn to '1' before the most significant bit of the first byte, and return to '0' after the
least significant bit of the last byte in sequence. When the BLK_FULL output of the ZR36506
turns '1', the sending device should wait (by switching BLK_EN to '0') until the BLK_FULL
indication returns to '0'.
BCLK
BEh
BEsu
BLK_EN
Dh
DAT_IN
XX
B1[7]
B1[6]
B1[5]
B1[4]
Bn[2]
Bn[1]
Bn[0]
XX
Dsu
If the audio channel is enabled, the sending device should wait at least 16 clock cycles after the
FS_L (or FS_R) pulse before beginning to send its own data. During this time it should keep its
data out signal in the High-z state, so as not to interfere with the audio data.
1
2
3
4
16
BCLK
FS_L
FS_R
BLK_EN
DAT_IN
Keep device data output pin in Hi-Z
XX
audio
audio
BFHsu
audio
audio
audio
B1[7]
B1[6]
B1[5]
BFLsu
BCLK
BLK_FULL
BLK_EN
DAT_IN
15 -2
Bn[1]
Bn[0]
Bn+1[7]
Bn+1[6]
Bulk Channel
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Parameter
Symbol
Min
Max
Unit
Setup Time from BLK_EN High to BCLK Low
BEsu
100
-
ns
Hold Time from BCLK Low to BLK_EN Low
BEh
100
-
ns
Setup Time from DAT_IN valid to BCLK Low
Dsu
100
-
ns
Hold Time from BCLK Low to DAT_IN valid
Dh
100
-
ns
Setup Time from BLK_FULL High to BCLK
High
BFHsu
80
-
ns
Hold Time from BLK_FULL Low to BCLK High
BFLsu
0
-
ns
Cj
-
4.3
%
Jitter at the Bit Clock signal BCLK
Bulk Channel
15 -3
Zoran ZR36506 USBVision – Datasheet
Zoran Proprietary and Confidential
16 SERIAL PIPE OUT INTERFACE
Description
The Serial Pipe Out (SPO) interface is used for compressed video and audio data transfer to
external devices. This interface is used in Standalone mode (when not connected to USB)
The SPO consists of the following signals:
Pin # Pin Name
I/O
Description
11
USB_CLK_OUT
O
12 MHz clock for bit sampling.
10
USB_DAT
O
Serial data output. This signal carries both compressed
video and PCM audio signals.
9
USB_VALID
O
Data-Valid signal.
‘1’
indicates that data is valid.
‘0’
indicates “ignore data signal”.
Switch from ‘0’ to ‘1’ indicates beginning of a new byte.
8
USB_EP2
O
Video Data Select signal.
‘1’
7
USB_EP3
O
Audio Data Select signal.
‘1’
29
IO1
I
indicates video data region.
indicates Audio data region.
Video Data Request.
‘1’
means external device is ready to receive more
data.
‘0’
means external device cannot receive more data
now.
Video and audio data are byte-oriented and always begin with the LSbit. The signal
USB_VALID always returns to ‘0’ between every two subsequent bytes, hence it can be used for
byte synchronization.
The signals USB_EP2 and USB_EP3 indicate whether the data belong to the video or audio
streams respectively. The signal USB_EP2 can also indicate the end of a video frame and the
beginning of the next one. Refer to the waveform diagrams for this indication.
Serial Pipe Out Interface
16 -1
Zoran ZR36506 USBVision – Datasheet
Zoran Proprietary and Confidential
Video Data Output
USB_
CLK_OUT
USB_DAT
xx
D0
D1
D2
D3
D4
D5
D6
D7
xx
xx
USB_VALID
USB_EP2
Audio Data Output
USB_
CLK_OUT
USB_DAT
xx
D0
D1
D2
D3
D4
D5
D6
D7
xx
xx
USB_VALID
USB_EP3
General Timing 1
t1
USB_
CLK_OUT
t2
t3
USB_DAT
USB_VALID
USB_EP2
USB_EP3
General Timing 2
t4
USB_EP2
Vid. data packs (0 bytes).
End of Video frame
Vid. data pack. (63-1023 bytes).
Video frame #N
Vid. data pack.
Video frame #N
t6
Vid. data pack.
Video frame #N+1
t7
Audio data pack.
1-16 bytes
USB_EP3
t5
USB_VALID
Note: One or more empty packets of video type must occur after every video frame
16 -2
Serial Pipe Out Interface
Zoran ZR36506 USBVision – Datasheet
Zoran Proprietary and Confidential
General Timing 3
IO1
Continue until Pack.
end (63-1023 bytes)
USB_EP2
wait for IO1='1'
USB_EP3
Timing Table
Name
Min
Typical
Max
Unit
t1
78
83
88
[ns]
t2
5
7
10
[ns]
t3
37
42
47
[ns]
t4
10
1000
2000
[us]
t5
1
8
16
[us]
t6
200
800
-
[ns]
t7
200
800
1500
[ns]
Serial Pipe Out Interface
16 -3
Zoran ZR36506 USBVision – Datasheet
Zoran Proprietary and Confidential
17 SOFTWARE PACKAGE
Listed below is a description of the software components provided with the ZR36506.
§ WDM Video streaming class MiniDriver
§ MS standard connection and streaming in kernel mode (Capture, Still)
§ MS standard property sets (TV Tuner, Crossbar)
§ MS standard way of exposing data formats.
§ MS standard way of controlling stream flow.
All interfaces are exposed through the DirectShow
architecture. VFW interfaces are also available via a WDM
to VFW mapper, provided by Microsoft.
§ WDM Audio streaming class MiniDriver- streams audio data from the ZR36506 chip.
§ TWAIN Compliant Drivers - The package includes a TWAIN compliant driver for high
resolution still image capture. The GUI of the TWAIN driver displays a live video preview.
The package also includes a TWAIN compliant driver for Digital Camera support.
§ EEPROM Programming Application - An application for programming the ZR36506
EEPROM to contain vendor specific USB Descriptors. It allows the setting of the device
and manufacturer names as well as the serial number for the device.
The drivers are supplied with an INF file for easy
installation. Customization is applied by modifying the
name strings in the INF file.
Software Package
17 -1
Zoran ZR36506 USBVision – Datasheet
Zoran Proprietary and Confidential
18 MECHANICAL SPECIFICATIONS
Mechanical Specifications
18 -1
Zoran ZR36506 USBVision – Datasheet
Zoran Proprietary and Confidential
19 CONTACT INFORMATION
USA
Zoran Corporation
3112 Scott Boulevard,
Santa Clara, CA 95054-3317
ISRAEL
Tel.: +1-408-919-4111
Fax: +1-408-919-4122
CHINA
Zoran China Office
Suite 2507
Electronics Science &
Tech Building
2070 Central Shennan Rd.
Shenzhen, Guangdong,
518031 P.R. China
Tel.: +86-755-378-0319
Fax: +86-755-378-0852
TAIWAN
WEB
Zoran Taiwan Office
4F-1, No. 5, Alley 22
Zoran Microelectronics Ltd.
Advanced Technology Ctr.
P.O. Box 2495
Haifa, 31024 Israel
Tel.: +972-4-8545-777
Fax: +972-4-8551-551
JAPAN
Zoran Japan Office
2-2-8 Roppongi, Minato-ku
Tokyo 106-0032, Japan
Tel.: +81-03-5574-7081
Fax: +81-03-5574-7156
CANADA Zoran Toronto Lab
2175 Queen St. East,
Lane 513, Reikuang Rd.
Taipei, Taiwan R.O.C.
Suite 302
Toronto, Ontario
M4E 1E5 Canada
Tel.: +886-2-2659-9797
Tel.: +1-416-690-3356
Fax: +886-2-2659-9595
Fax: +1-416-690-3363
http://www.zoran.com
http://www.nogatech.com
Contact Information
19 -1
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