MITEL VP5311BCGGP1N

VP5311B/VP5511B
NTSC/PAL Digital Video Encoder
Advance Information
Supersedes DS4575 1.5 May 1997 version
The VP5311/VP5511 converts digital Y, Cr, Cb, data
into analog NTSC/PAL composite video and S-video signals.
The outputs are capable of driving doubly terminated 75
ohm loads with standard video levels.
The device accepts data inputs complying with CCIR
Recommendation 601 and 656. The data is time multiplexed
on an 8 bit bus at 27MHz and is formatted as Y, Cr, Y, Cb
(i.e. 4:2:2). The video blanking and sync information from
REC 656 is included in the data stream when the VP5311/
VP5511 is working in slave mode.
The output pixel rate is 27MHz and the input pixel rate
is half this frequency, i.e. 13.5MHz.
All necessary synchronisation signals are generated
internally when the device is operating in master mode. In
slave mode the device will lock to the TRS codes or the HS
and VS inputs.
The rise and fall times of sync, burst envelope and
video blanking are internally controlled to be within
composite video specifications.
Three digital to analog converters (DACs) are used to
convert the digital luminance, chrominance and composite
data into true analog signals. An internally generated
reference voltage provides the biasing for the DACs.
FEATURES
■ Converts Y, Cr, Cb data to analog composite video and
S-video
■ Supports CCIR recommendations 601 and 656
■ All digital video encoding
■ Selectable master/slave mode for sync signals
■ Switchable chrominance bandwidth
■ Switchable pedestal with gain compensation
■ SMPTE 170M NTSC or CCIR 624 PAL compatible
outputs
■ GENLOCK mode
■ Line 21 Closed Caption encoding
■ I2C bus serial microprocessor interface
■ VP5311B supports Macrovision anti-taping format Rev.
6.1, in PAL and Rev. 7.01 in NTSC.
APPLICATIONS
■
■
■
■
■
■
Digital Cable TV
Digital Satellite TV
Multi-media
Video games
Karaoke
Digital VCRs
ORDERING INFORMATION
VP5311B/CG/GP1N
VP5511B/CG/GP1N
DS4575 - 2.2 October 1998
PIN 64
PIN 1
GP64
Figure 1 Pin connections (top view)
PIN
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
FUNCTION
VDD
GND
D0 (VS I/O)
D1 (HS I/O)
D2 (FC0 O/P)
D3 (FC1 O/P)
D4 (FC2 O/P)
D5
D6 (SCSYNC I/P)
D7 (PALID I/P)
GND
VDD
GND
GND
PXCK
VDD
CLAMP
COMPSYNC
GND
VDD
TDO
TDI
TMS
TCK
GND
SA1
SA2
SCL
VDD
SDA
GND
VDD
PIN
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
FUNCTION
VDD
RESET
REFSQ
GND
VDD
GND
PD7
PD6
PD5
PD4
PD3
PD2
PD1
PD0
GND
VDD
AGND
VREF
DACGAIN
COMP
AVDD
LUMAOUT
AGND
COMPOUT
AGND
CHROMAOUT
AVDD
N/C
N/C
AVDD
AVDD
N/C
VP5311B/VP5511B
ELECTRICAL CHARACTERISTICS
Test conditions (unless otherwise stated): As specified in Recommended Operating Conditions
DC CHARACTERISTICS
Parameter
Conditions
Digital Inputs TTL compatible (except SDA, SCL)
Input high voltage
Input low voltage
Digital Inputs SDA, SCL
Input high voltage
Input low voltage
Input high current
Input low current
Digital Outputs CMOS compatible
Output high voltage
Output low voltage
Digital Output SDA
Output low voltage
Symbol
Min.
VIN
VIL
2.0
VIH
0.7 VDD
Typ.
Max.
Units
0.8
V
V
V
VIN = VDD
VIL
IIH
0.3 VDD
10
V
µA
VIN = VSS
IIL
-10
µA
IOH = -1mA
IOL = +4mA
VOH
VOL
0.4
V
V
IOL = +6mA
VOL
0.6
V
Max.
Units
±1.5
±1
±5
LSB
LSB
%
3.7
ELECTRICAL CHARACTERISTICS
Test conditions (unless otherwise stated): As specified in Recommended Operating Conditions
DC CHARACTERISTICS DACs
Parameter
Symbol
Accuracy (each DAC)
Integral linearity error
Diffential linearity error
DAC matching error
Monotonicity
LSB size
Internal reference voltage
Internal reference voltage output impedance
Reference Current (VREF/RREF) RREF = 769Ω
DAC Gain Factor (VOUT = KDAC x IREF x RL), VOUT = DAC code 511
Peak Glitch Energy (see fig.3)
Min.
Typ.
INL
DNL
guaranteed
µA
V
Ω
mA
66.83
1.050
27k
1.3699
24.93
50
pV-s
CVBS, Y and C - NTSC (pedestal enabled)
Maximum output, relative to sync bottom
White level relative to black level
Black level relative to blank level
Blank level relative to sync level
Colour burst peak - peak
DC offset (bottom sync)
33.75
17.64
1.40
7.62
7.62
0.40
mA
mA
mA
mA
mA
mA
CVBS, Y and C - PAL
Maximum output
White level relative to black level
White level relative to sync level
Black level relative to sync level
Colour burst peak - peak
DC offset (bottom sync)
34.15
18.71
26.73
8.02
8.02
0.00
mA
mA
mA
mA
mA
mA
VREF
ZR
IREF
KDAC
Note: All figures are for: RREF = 769Ω RL = 37.5Ω. When the device is set up in NTSC mode there is a +0.25% error in the PAL
levels. If RL = 75Ω then RREF = 1538Ω.
ABSOLUTE MAXIMUM RATINGS
Supply voltage
VDD, AVDD
Voltage on any non power pin
Ambient operating temperature
Storage temperature
2
-0·3 to 7·0V
-0·3 to VDD+0·3V
0 to 70°C
-55°C to 150°C
Note: Stresses exceeding these listed under Absolute
Maximum Ratings may induce failure. Exposure to Absolute
Maximum Ratings for extended periods may reduce
reliability. Functionality at or above these conditions is not
implied.
VP5311B/VP5511B
RECOMMENDED OPERATING CONDITIONS
Parameter
Symbol
Power supply voltage
Power supply current (including analog outputs)
Input clock frequency
SCL clock frequency
Analog video output load
DAC gain resistor
Ambient operating temperature
Min.
VDD, AVDD
4.75
IDD
PXCK
-50ppm
fSCL
0
Typ.
Units
Max.
5.25
5.00
150
27.00 +50ppm
500
37.5
769
70
V
mA
MHz
kHz
Ω
Ω
°C
VIDEO CHARACTERISTICS
Parameter
Symbol
Typ.
Min.
Luminance bandwidth
Chrominance bandwidth (Extended B/w mode)
Chrominance bandwidth (Reduced B/w mode)
Burst frequency (NTSC)
Burst frequency (PAL-B, D,G,H,I)
Burst frequency (PAL-N Argentina)
Burst cycles (NTSC )
Burst cycles (NTSC and PAL-B, D, G, H,I)
Burst envelope rise / fall time (NTSC and PAL-N)
Burst envelope rise / fall time (NTSC and PAL-B, D, G, H,I)
Analog video sync rise / fall time (NTSC and PAL-N)
Analog video blank rise / fall time (NTSC and PAL-B, D, G, H,I)
Differential gain
Differential phase
Signal to noise ratio (unmodulated ramp)
Chroma AM signal to noise ratio (100% red field)
Chroma PM signal to noise ratio (100% red field)
Hue accuracy
Colour saturation accuracy
Residual sub carrier
Luminance / chrominance delay
5.5
1.3
650
3.57954545
4.43361875
3.58205625
9
10
300
300
145
245
1.5
0.5
-61
-56
-58
-60
10
Max.
-61
-56
-58
2.5
2.5
Units
MHz
MHz
kHz
MHz
MHz
MHz
Fsc cycles
Fsc cycles
ns
ns
ns
ns
% pk-pk
° pk-pk
dB
dB
dB
%
%
dB
ns
ESD COMPLIANCE
Pins
Test
All pins
Human body model
2kV on 100pF through 1k5Ω
All pins
Machine model
200V on 200pF through 0Ω & 500nH
Test Levels
Notes
Meets Mil-Std-883 Class 2
3
VP5311B/VP5511B
SDA
SCL
SA1
SA2
SET-UP
REGISTERS
I2C INTERFACE
ANTI-TAPING
CONTROL
CLOSED
CAPTION
CLAMP
RESET
+
VIDEO TIMING GENERATOR
COMPSYNC
LUMA OUT
SYNC
BLANK
INSERT
Y
+
INTERPOLATOR
INPUT
DEMUX
&
8
LUMA
DAC
+
PD7-0 CHROMA
INTERP
COMP
DAC
CHROMA
LOW -PASS
FILTER
Cb
D7-0
OUT
Cr
INTERPOLATOR
CHROMA
DAC
MODULATOR
CHROMA OUT
PXCK
8
COMP
GENERAL
PURPOSE PORT
DIGITAL
PHASE COMP
COLOUR SUBCARRIER
GENERATOR
DACGAIN
VREF
TDI
REFSQ
DAC
REF
JTAG.
TDO
COMP
TMS TCK
Figure 2 Functional block diagram of the VP5311B, the VP5511B is identical except there is no Anti-Taping Control
V
W
H
Peak Glitch Area = H x W/2
t(ps)
The glitch energy is calculated by measuring the area under the voltage
time curve for any LSB step, typically specified in picoVolt-seconds (pV-s)
Figure 3 Glitch Energy
4
VP5311B/VP5511B
PIN DESCRIPTIONS
Pin Name
Pin No.
Description
PD0-7
39 - 46
8 Bit Pixel Data inputs clocked by PXCK. PD0 is the least significant bit, corresponding to Pin
46. These pins are internally pulled low.
D0-7
3 - 10
8 Bit General Purpose Port input/output. D0 is the least significant bit, corresponding to Pin 3.
These pins are internally pulled low.
PXCK
15
27MHz Pixel Clock input. The VP5311 internally divides PXCK by two to provide the pixel
clock.
CLAMP
17
The CLAMP output signal is synchronised to COMPSYNC output and indicates the position of
the BURST pulse, (lines 10-263 and 273-525 for NTSC; lines 6-310 and 319-623 for PALB,D, G,I,N(Argentina)).
COMPSYNC
18
Composite sync pulse output. This is an active low output signal.
TDO
21
JTAG Data scan output port.
TDI
22
JTAG Data scan input port.
TMS
23
JTAG Scan select input.
TCK
24
JTAG Scan clock input.
SA1
26
Slave address select.
SA2
27
Slave address select.
SCL
28
Standard I2C bus serial clock input.
SDA
30
Standard I2C bus serial data input/output.
RESET
34
Master reset. This is an asynchronous, active low, input signal and must be asserted for a
minimum 200ns in order to reset the VP5311.
REFSQ
35
Reference square wave input used only during Genlock mode.
VREF
50
Voltage reference output. This output is nominally 1·055V and should be decoupled with a
100nF capacitor to GND.
DAC GAIN
51
DAC full scale current control. A resistor connected between this pin and GND sets the
magnitude of the video output current. An internal loop amplifier controls a reference current
flowing through this resistor so that the voltage across it is equal to the Vref voltage.
COMP
52
DAC compensation. A 100nF ceramic capacitor must be connected between pin 52 and pin
53.
LUMAOUT
54
True luminance, composite and chrominance video signal outputs. These are high
COMPOUT
56
impedance current source outputs. A DC path to GND must exist from each of these pins.
CHROMAOUT
58
NOT USED
60, 61, 64
VDD
1, 12, 16,
Positive supply input. All VDD pins must be connected.
20, 29,
32, 33,
37, 48
AVDD
53, 59
Analog positive supply input. All AVDD pins must be connected.
62, 63
GND
2, 11, 13,
Negative supply input. All GND pins must be connected.
14, 19,
25, 31,
36, 38, 47
AGND
49, 55, 57
Negative supply input. All AGND pins must be connected.
All other pins are N/C and should not be connected.
5
VP5311B/VP5511B
REGISTERS MAP
See Register Details for further explanations.
ADDRESS REGISTER
NAME
hex
DEFAULT
hex
7
6
5
4
3
2
1
0
R/W
BAR
RA7
RA6
RA5
RA4
RA3
RA2
RA1
RA0
W
00
01
02
03
PART ID2
PART ID1
PART ID0
REV ID
ID17
ID0F
ID07
REV7
ID16
ID0E
ID06
REV6
ID15
ID0D
ID05
REV5
ID14
ID0C
ID04
REV4
ID13
ID0B
ID03
REV3
ID12
ID0A
ID02
REV2
ID11
ID09
ID01
REV1
ID10
ID08
ID00
REV0
R
R
R
R
13
66
58
05
04
05
06
07
08
09
0A
0B
0C
0D
GCR
VOCR
HANC
ANCID
SC_ADJ
FREQ2
FREQ1
FREQ0
SCHPHM
SCHPHL
AN7
SC7
FR17
FR0F
FR07
SCH7
YCDELAY RAMPEN
CLAMPDIS CHRBW SYNCDIS
DFI2
DFI1
AN5
AN4
AN6
SC5
SC4
SC6
FR15
FR14
FR16
FR0D
FR0C
FR0E
FR05
FR04
FR06
SCH5
SCH4
SCH6
SLH&V
BURDIS
DFI0
AN3
SC3
FR13
FR0B
FR03
SCH3
CVBSCLP
LUMDIS
Reserved
AN2
SC2
FR12
FR0A
FR02
SCH2
VFS1
CHRDIS
Reserved
AN1
SC1
FR11
FR09
FR01
SCH1
VFS0
PEDEN
ACTREN
PARITY
SC0
FR10
FR08
FR00
SCH8
SCH0
R/W
R/W
*
R/W
R/W
R/W
R/W
R/W
R/W
R/W
00
00
00
00
9C
87
C1
F1
00
00
0E to 1F
Reserved
20
21
22
23 to EF
F0
F1
F2
F3
F4
F0 to F7
F8
F9
FB
FC
FD
FE
FF
GPPCTL
GPPRD
GPPWR
Not used
CCREG1
CCREG2
CCREG3
CCREG4
CC_CTL
Reserved
HSOFFL
HSOFFM
SLAVE1
SLAVE2
TEST1
TEST2
GPSCTL
CTL7
RD7
WR7
CTL6
RD6
WR6
CTL5
RD5
WR5
CTL4
RD4
WR4
CTL3
RD3
WR3
CTL2
RD2
WR2
CTL1
RD1
WR1
CTL0
RD0
WR0
W
R
W
FF
00
-
F1W1D6
F1W2D6
F2W1D6
F2W2D6
-
F1W1D5
F1W2D5
F2W1D5
F2W2D5
-
F1W1D4
F1W2D4
F2W1D4
F2W2D4
-
F1W1D3
F1W2D3
F2W1D3
F2W2D3
F2ST
F1W1D2
F1W2D2
F2W1D2
F2W2D2
F1ST
F1W1D1
F1W2D1
F2W1D1
F2W2D1
F2EN
F1W1D0
F1W2D0
F2W1D0
F2W2D0
F1EN
R/W
R/W
R/W
R/W
R/W
00
00
00
00
00
HSOFF3
HSOFF4
SL_HS1
F_SWAP
HCNT3
HCNT4
RESERVED
FOR
RESERVED
FOR
NOLOCK PALIDEN
HSOFF2
SL_HS0
HCNT2
TEST
TEST
TSURST
HSOFF1
HSOFF9
HCNT9
HCNT1
HS0FF0
HSOFF8
HCNT8
HCNT0
7E
00
00
00
CHRMCLIP
TRSEL
R/W
R/W
R/W
R/W
R/W
R/W
R/W
HSOFF5
VSMODE
HCNT5
REGISTER
REGISTER
FSC4SEL GENDITH GENLKEN
HSOFF7
NCORSTD
HCNT7
HSOFF6
VBITDIS
HCNT6
00
Table.1 Register map
NOTE * For register HANC, bits 3, 4 and 5 are read only. Bits 1 and 2 are reserved. N/A = not applicable.
For register PART ID0 the VP551 value is AB
NTSC (default)
PAL-B, G, H, I
Field
field freq. Hz
59.94
525
50
625
PAL-N (Argentina)
625
Standard
Lines/
50
SC_ADJ
Number of Horizontal Subcarrier
fSC/fH
register
pixels/line freq. kHz.
freq. kHz.
hex
at 27MHz
fSC
fH
15.734266 3.57954545
1716
(455/2)
xx
15.625000 4.43361875 (1135/4+1/625)
1728
9C
15.625000 3.58205625 (917/4+1/625)
1728
57
FREQ2-0
registers hex
87 C1 F1
A8 26 2B
87 DA 51
Table.2 Line, field and subcarrier standards and register settings
xx = don’t care.
The calculation of the FREQ register value is according to the following formula:FREQ = 226 x fSC/PXCK hex, where PXCK = 27.00MHz
NTSC value is rounded UP from the decimal number. PAL-B, D, G, H, I and N (Argentina) are rounded DOWN. The SC_ADJ
value is derived from the adjustment needed to be added after 8 fields to ensure accuracy of the Subcarrier frequency. Note the
SC_ADJ value of 9C required for PAL-B, D, G, H, I, is different to the default state of the register.
In NTSC the NCO is reset at the end of every line, this can be disabled by setting the NCORSTD bit in SLAVE1, this allows the
VP5311 to cope with line lengths that are not exactly as specified in REC656.
6
VP5311B/VP5511B
REGISTER DETAILS
PEDEN
BAR
RA7-0
Base register
Register address.
PART ID 2-0
ID17-00
Part number
Chip part identification (ID) number.
REV ID
REV7-0
Revision number
Chip revision ID number.
GCR
YCDELAY
Global Control
Luma to Chroma delay.
High = 37ns luma delay, this may be
used to compensate for group delay in
external filters.
Low = normal operation (default).
RAMPEN
Modulated ramp enable.
High = ramp output for differential phase
and gain measurements. A 27MHz clock
must be applied to PXCK pin.
Low = normal operation (default).
1 = Slave to HS and VS inputs
1 = Enables clamp on composite output,
to prevent flatenning of chroma peak
throughs
SL_HS_VS
CVBSCLMP
VFS1-0
CHRBW
SYNCDIS
Ancillary data ID
Ancillary data ID
Parity bit (odd)
Only ancillary data in REC 656 data
stream with the same ID as this byte will
be decoded by the VP5311/VP5511 to
produce H and V synchronisation and
FIELD COUNT.
SC_ADJ
SC7-0
Sub Carrier Adjust
Sub carrier frequency seed value, see
table 2.
FREQ2-0
FR17-00
Sub carrier frequency
24 bit Sub carrier frequency programmed
via I2C bus, see table 2. FREQ2 is the
most significant byte (MSB).
SCHPHM-L
SCH9-0
Video Output Control
High = Clamp signal disable
Low = normal operation with clamp signal
enabled (default).
Sub carrier phase offset
9 bit Sub carrier phase relative to the
50% point of the leading edge of the
horizontal part of composite sync.
SCHPHM bit 0 is the MSB. The nominal
value is zero. This register is used to
compensate for delays external to the
VP5311/VP5511.
GPPCTL
CTL7-0
General purpose port control
Each bit controls port direction
Low = output
High = input
Chroma bandwidth select.
High = ±1·3MHz.
Low = ±650kHz (default)
GPPRD
RD7-0
General purpose port read data
I2C bus read from general purpose port
(only INPUTS defined in GPPCTL)
GPPWR
WR7-0
General purpose port write data
I2C bus write to general purpose port
(only OUTPUTS defined in GPPCTL)
CCREG1
F1W1D6-0
Closed Caption register 1
Field one (line 21), first data byte
CCREG2
F1W2D6-0
Closed Caption register 2
Field one (line 21), second data byte
CCREG3
F2W2D6-0
Closed Caption register 3
Field two (line 284), first data byte
CCREG4
F2W2D6-0
Closed Caption register 4
Field two (line 284), second data byte
Video format select
NTSC (default)
PAL-B, D, G,H,I,N(Argentina)
Reserved
Reserved
High = Sync disable (in composite video
signal). COMPSYNC is not affected.
Low = normal operation with sync
enabled (default).
BURDIS
High = Chroma burst disable.
Low = normal operation, with burst
enabled (default).
LUMDIS
High = Luma input disable - force black
level with synchronisation pulses maintained.
Low = normal operation, with Luma input
enabled (default).
CHRDIS
HANC
Horizontal Ancillary Data Control
DFI2-0(read only)Digital Field Identification, 000=Field1
ANCTREN
Ancillary timing reference enable. When
High use FIELD COUNT from ancillary
data stream. When low, data is ignored.
ANCID
AN7-1
AN0
VFS1 VFS0
0
0
0
1
1
0
1
1
VOCR
CLAMPDIS
High = Pedestal (set-up) enable a
7·5 IRE pedestal on lines 23-262 and
286-525. Valid for NTSC
High = Chroma input disable - force
monochrome.
Low = normal operation, with Chroma
input enabled (default).
7
VP5311B/VP5511B
CCCTL
F1ST
F2ST
Closed Caption control register
Field one (line 21) status
High = data has been encoded
Low = new data has been loaded to
CCREG1-2
Field two (line 284) status
High = data has been encoded
Low = new data has been loaded to
CCREG3-4
F1EN
Closed Caption field one (line 21)
High = enable
Low = disable (default)
F2EN
Closed Caption field two (line 284)
High = enable
Low = disable (default)
HSOFFM-L
HSOFF9-0
HS offset
This is a 10 bit number which allows the
user to offset the start of digital data input
with reference to the pulse HS.
SLAVE1
NCORSTD
H &V Slave mode control register
1 = NCO Line Reset Disable (NTSC only)
VBITDIS
0 = Video blanked when Rec601 V bit set
1 = V bit is ignored
The odd and even fields are swapped
Selects pixel sample (1 to 4)
As HCNT7-0 but MSBs
H &V Slave position register
Adjusts for delay at which pixel data
occurs relative to HS
F_SWAP
SL_HS1-0
HCNT9-8
SLAVE2
HCNT7-0
GPSCTL
FSC4SEL
GPS Control
When high, REFSQ = 4xFSC and GPP
bit D6 is forced to become an input for a
SCSYNC signal (high = reset), which
provides a synchronous phase reset for
FSC divider. Low = normal operation with
REFSQ = 1xFSC. (default).
GENDITH
1 = Gen lock dither added.
GENLKEN
High = enable Genlock to REFSQ signal
input.
Low = internal subcarrier generation
(default).
NOLOCK
Genlock status bit (read only)
Low = Genlocked.
High = cannot lock to REFSQ. This bit is
cleared by reading and set again if lock
cannot be attained.
PALIDEN
8
High = enable external PAL ID phase
control and GPP bit D7 is forced to
become an input for PAL ID switch signal,
(GPP bit D7 - Low = +135°,
High = -135°).
Low = normal operation, internal PAL ID
phase switch is used (default).
TSURST
High = chip soft reset. Registers are NOT
reset to default values.
Low = normal operation (default).
CHRMCLIP
High = enable clipping of chroma data
when luma goes below black level and is
clipped.
Low = no chroma clipping (default).
TRSEL
High = master mode, GPP bits D0 - 4 are
forced to become a video timing port with
VS, HS and FIELD outputs.
Low = slave mode, timing from REC656.
I2C BUS CONTROL INTERFACE
I2C bus address
A6
A5
A4
A3
A2
A1
A0
0
0
0
1
1
SA2
SA1
R/ W
X
The serial microprocessor interface is via the bidirectional port consisting of a data (SDA) and a clock (SCL)
line. It is compatible to the Philips I2C bus standard (Jan. 1992
publication number 9398 393 40011). The interface is a slave
transmitter - receiver with a sub-address capability. All
communication is controlled by the microprocessor. The SCL
line is input only. The most significant bit (MSB) is sent first.
Data must be stable during SCL high periods.
A bus free state is indicated by both SDA and SCL lines
being high. START of transmission is indicated by SDA being
pulled low while SCL is high. The end of transmission,
referred to as a STOP, is indicated by SDA going from low to
high while SCL is high. The STOP state can be omitted if a
repeated START is sent after the acknowledge bit. The
reading device acknowledges each byte by pulling the SDA
line low on the ninth clock pulse, after which the SDA line is
released to allow the transmitting device access to the bus.
The device address can be partially programmed by the
setting of the pins SA1 and SA2. This allows the device to
respond to one of four addresses, providing for system
flexibility. The I2C bus address is seven bits long with the last
bit indicating read / write for subsequent bytes.
The first data byte sent after the device address, is the
sub-address - BAR (base address register). The next byte will
be written to the register addressed by BAR and subsequent
bytes to the succeeding registers. The BAR maintains its data
after a STOP signal.
NTSC/PAL Video Standards
Both NTSC (4-field, 525 lines) and PAL (8-field, 625 lines)
video standards are supported by the VP5311/VP5511. All
raster synchronisation, colour sub-carrier and burst
characteristics are adapted to the standard selected. The
VP5311/VP5511 generates outputs which follow the
requirements of SMPTE 170M and CCIR 624 for PAL signals.
The device supports the following:
NTSC,
PAL B, D, G, H, I, N (Argentina).
VP5311B/VP5511B
Video Blanking
The VP5311/VP5511 automatically performs standard
composite video blanking. Lines 1-9, 264-272 inclusive, as
well as the last half of line 263 are blanked in NTSC mode. In
PAL mode, lines 1-5, 311-318, 624-625 inclusive, as well as
the last half of line 623 are blanked.
The V bit within REC656 defines the video blanking when
TRSEL (bit 0 of GPSCTL register) is set low. When in
MASTER mode with TRSEL set high the video encoder is still
enabled. Therefore if these lines are required to be blank they
must have no video signal input.
Interpolator
The luminance and chrominance data are separately
passed through interpolating filters to produce output
sampling rates double that of the incoming pixel rate. This
reduces the sinx/x distortion that is inherent in the digital to
analog converters and also simplifies the analog
reconstruction filter requirements.
Digital to Analog Converters
The VP5311/VP5511 contained three 9 bit digital to
analog converters which produce the analog video signals.
The DACs use a current steering architecture in which bit
currents are routed to one of two outputs; thus the DAC has
true and complementary outputs. The use of identical current
sources and current steering their outputs means that
monotonicity is guaranteed. An on-chip voltage reference of
1.050V provides the necessary biasing. However, the
VP5311/VP5511 may be used in applications where an
external 1V reference is provided on the VREF pin, to adjust
the video levels. In this case, the external reference should be
temperature compensated and provide a low impedance
output.
The full-scale output currents of the DACs is set by an
external 769Ω resistor between the DACGAIN and GND pins.
An on-chip loop amplifier stabilises the full-scale output
current against temperature and power supply variations.
The analog outputs of the VP5311/VP5511 are capable of
directly driving doubly terminated 75Ω load then the
DACGAIN resistor is simply doubled.
Luminance, Chrominance and Composite Video Outputs
The Luminance video output (LUMAOUT pin 54) drives a
37.5Ω load at 1.0V, sync tip to peak white. It contains only the
luminance content of the image plus the composite sync
pulses. In the NTSC mode, a set-up level offset can be added
during the active video portion of the raster.
The Chrominance video output (CHROMAOUT pin 58)
drives a 37.5Ω load at levels proportional in amplitude to the
luma output (40 IRE pk-pk burst). This output has a fixed offset
current which will produce approximately a 0.5V DC bias
across the 37.5Ω load. Burst is injected with the appropriate
timing relative to the luma signal.
The composite video output (COMPOUT pin 56) will also
drive a 37.5Ω load at 1.0V, sync tip to peak white. It contains
both the luminance and chrominance content of the signal
plus the composite sync pulses.
The CVBS DAC output clipping feature limits the digital
data going into the DAC so that if it goes outside the range it
is limited to the maximum or minimum (511 or 000). This
feature is permanently enabled.
CVBSCLP in register GCR. When set to a '1' this bit
enables an envelope prediction circuit that establishes if the
chroma and luma added together is likely to go outside the
CVBS DAC limits. If it is, then a smooth rounding of the
chroma peaks is made to stop this happening. This prevents
any high frequency components being produced as with the
clipping function which will produce flat peaks. In practice
there will be some loss of saturation in the colour.
Output sinx/x compensation filters are required on all
video output, as shown in the typical application diagram, see
figs. 8 & 9.
Video Timing - Slave sync mode
The VP5311/VP5511 has an internal timing generator
which produces video timing signals appropriate to the mode
of operation. In the default (power up) slave mode, all timing
signals are derived from the input clock, PXCK, which must be
derived from a crystal controlled oscillator. Input pixel data is
latched on the rising edge of the PXCK clock.
The video timing generator produces the internal blanking
and burst gate pulses, together with the composite sync
output signal, using timing data (TRS codes) from the
Ancillary data stream in the REC656 input signal, (when
TRSEL (bit 0 of GPSCTL register) is set low).
HCNT
To ensure that the incoming data is sampled correctly a 10
bit binary number (HCNT) has to be programmed into the
SLAVE1 and 2 registers. This will allow the device's internal
horizontal counter to align with the video data, each bit
represents one 13.5MHz cycle. To calculate this use the
formula below:
NTSC
HCNT = SN + 119 (SN = 0 - 738)
HCNT = SN + 739 (SN = 739 - 857)
PAL
HCNT = SN + 127 (SN = 0 - 738)
HCNT = SN + 737 (SN = 737 - 863)
where SN is Rec. 656/601 sample number on which the
negative edge of HSYNC occurs.
SL_HS
A further adjustment is also required to ensure that the
correct Cr and Cb sample alignment. The bits SL_HS1-0
allows for four sampling positions in the CbYCrY sequence,
failure to set this correctly will mean corruption of the colour or
colour being interpreted as luma.
F_SWAP
If the field synchronisation is wrong it can be swapped by
setting this bit.
V_SYNC
When set to a '1' this bit allows an odd/even square wave
to provide the field synchronisation.
Example
NTSC
HSYNC occurs on Rec656 sample 721 (end of active
video), then;
HCNT = 721 + 119 = 839 = 348 Hex
SL_HS = 10 (for correct sample)
to set slave mode send .04w08pzfbw48pzffw01
9
VP5311B/VP5511B
this sets registers as follows:
reg
04
fb
ff
data
08
0b
01
Note: HSOFF should always be zero when using slave mode.
Video Timing - Master sync mode
When TRSEL (bit 0 of GPSCTL register) is set high, the
VP5311 operates in a MASTER sync mode, all REC656
timing reference codes are ignored and GPP bits D0 - 4
become a video timing port with VS, HS and FIELD outputs.
The PXCK signal is, however, still used to generate all internal
clocks. When TRSEL is set high, the direction setting of bits 4
- 0 of the GPPCTL register is ignored.
VS is the start of the field sync datum in the middle of the
equalisation pulses. HS is the line sync which is used by the
preceding MPEG2 decoder to define when to output digital
video data to the VP5311. The position of the falling edge of
HS relative to the first data Cb0, can be programmed in
HSOFFM-L registers, see fig. 4.
HS offset
The position of the falling edge of HS relative to the first
data Cb0, can be programmed in HSOFFM-L registers, see
figure 4, this is called the pipeline delay and may need
adjusting for a particular application. This is done by
programming a 10 bit number called HSOFF into the
HSOFFM and HSOFFL registers, HSOFFM being the most
significant two bits and HSOFFL the least significant eight bits.
A default value of 07EH is held in the registers.
The value to program into HSOFF can be looked up in
tables 3 &4:
NCK
HSOFF
Comment
0 to 120
126 to 6
HS normal (64 cks)
121 to 138
863 to 801
HS pulse shortened*
184 to 857
800 to 127
HS normal (64 cks)
Table.3 for NTSC
NCK
HSOFF
Comment
0 to 131
137 to 6
HS normal (64 cks)
132 to 194
869 to 807
HS pulse shortened*
195 to 863
806 to 138
HS normal (64 cks)
Table.4 for PAL-B, D, G, H, I, N
where NCK = number of 13.5MHz clock cycles between the
falling edge of HS and Cb0 (first data I/P on PD7-0) see fig. 4.
Decreasing HSOFF advances the HS pulse (numbers are in
decimal).
*HS pulse shortened means that the width of the pulse will be
less than the normal 64 13.5MHz clock cycles.
The interruption in the sequence of values is because the HS
signal is jumping across a line boundary to the previous line as
the offset is increased. The register default value is 7EH and
this sets Nck to 0, ie. the HS negative edge and Cb0 are coincident in NTSC mode.
10
Genlock using REFSQ input
The VP5311 can be Genlocked to another video source by
setting GENLKEN high (in GPSCTL register) and feeding a
phase coherent sub carrier frequency signal into REFSQ.
Under normal circumstances, REFSQ will be the same
frequency as the sub carrier. But by setting FSC4SEL high (in
GPSCTL register), a 4 x sub carrier frequency signal may be
input to REFSQ. In this case, the Genlock circuit can be reset
to the required phase of REFSQ, by supplying a pulse to
SCSYNC (pin 9). The frequency of SCSYNC can be at sub
carrier frequency, but once per line, or once per field could be
adequate, depending on the application. When GENLKEN is
set high, the direction setting of bit 6 in the GPPCTL register
is igonred.
PALID Input
When in Genlock mode with GENLKEN set high (in
GPSCTL register), the VP5311 requires a PAL phase
identification signal, to define the correct phase on every line.
This is supplied to PALID input (pin 10), High = -135° and low
= +135°. The signal is asynchronous and should be changed
before the sub carrier burst signal. PALID input is enabled by
setting PALIDEN high (in GPSCTL register). When
GENLKEN is high, the direction setting of bit 7 of the GPPCTL
register is ignored
Master Reset
The VP5311/VP5511 must be initialised with the RESET
pin 34. This is an asynchronous active low signal and must be
active for a minimum of 200ns in order for the VP5311/
VP5511 to be reset. The device resets to line 64, start of
horizontal sync (i.e. line blanking active). There is no on-chip
power on reset circuitry.
Line 21 coding
Two bytes of data are coded on the line 21 of each field,
see figure 7. In the NTSC Closed Caption service, the default
state is to code on line 21 of field one only. An additional
service can also be provided using line 21 (284) of the second
field. The data is coded as NRZ with odd parity, after a clock
run-in and framing code. The clock run-in frequency =
0.5034965MHz which is related to the nominal line period, D
= H / 32.
D = 63.55555556 / 32µs
Two data bytes per field are loaded via I2C bus registers
CCREG1-4. Each field can be independently enabled by
programming the enable bits in the control register (CC_CTL).
The data is cleared to zero in the Closed Caption shift
registers after it has been encoded by the VP5311/VP5511.
Two status bit are provided (in CC_CTL), which are set high
when data is written to the registers and set low when the data
has been encoded on the Luma signal. The data is cleared to
zero in the Closed Caption shift registers after it has been
encoded by the VP5311/VP5511. The next data bytes must
be written to the registers when the status bit goes high,
otherwise the Closed Caption data output will contain Null
characters. If a transmission slot is missed (ie. no data
received) the encoder will send Null characters. Null
characters are invisible to a closed caption reciever. The MSB
(bit 7) is the parity bit and is automatically added by the
encoder.
VP5311B/VP5511B
PXCK Input (27MHz)
t SU; PD
HS
Nck=2
t HD; PD
Nck=0
Cb0
Y0
Cr0
Y1
Cb1
Y2
Cr1
Y3
Pixel Data Input (PD[7,0])
Figure 4 REC 656 interface with HS output timing
2:1 mux
REFSQ
fSC
0
Divide by 4
Synchronous
Counter
1
Input to
Genlocking
Block
Q
RESET
FSC4_SEL
SC_SYNC
(register bit)
1/ f SC_SYNC
t PWH; SC_SYNC
REFSQ
tSU; SC_SYNC
t HD; SC_SYNC
SC_SYNC
Q
Figure 5 REFSQ and SC_SYNC input timing
Pixel Data Input (PD[7,0\)
Sample Number
1439 1440 1441 1442 1443 1444 1445 1446 1447 1448 1449 1450
Y719 $FF
$00
$00
$XY
ANCILLARY DATA...
EAV SEQUENCE
t SU; PD
t HD; PD
t PWL; PXCK
PXCK Input (27MHz)
t PWH; PXCK
t DUR; PAL_ID
t SU; PAL_ID
t HD; PAL_ID
PAL_ID Stable
Input (PAL_ID)
Figure 6 PAL_ID input timing
11
VP5311B/VP5511B
TIMING INFORMATION
Symbol
Conditions
Parameters
Min.
Units
Max.
27.0
fPXCK
Master clock frequency (PXCK input)
Typ.
MHz
PXCX pulse width, HIGH
tPWH; PXCK
10
ns
PXCX pulse width, LOW
tPWL; PXCK
14.5
ns
PXCX rise time
10% to 90% points
tRP
TBD
ns
PXCX fall time
90% to 10% points
tFP
TBD
ns
PD7-0 set up time
tSU;PD
10
ns
PD7-0 hold time
tHD;PD
5
ns
SC_SYNC set up time
tSU;SC_SYNC
10
ns
SC_SYNC hold time
tHD;SC_SYNC
0
ns
PAL_ID set up time
tSU;PAL_ID
10
ns
PAL_ID hold time
tHD;PAL_ID
0
ns
PAL_ID duration
tDUR;PAL_ID
9
PXCX
periods
Output delay
PXCK to COMPSYNC
tDOS
25
ns
PXCK to CLAMP
Note: Timing reference points are at the 50% level. Digital C LOAD <40pF.
H
C
B
A
1
D
START BITS
CLOCK RUN-IN
HSYNC COLOUR BURST
13
E
DATA BYTE 1
DATA BYTE 2
50
P
P
0
S1
-40
IRE
S2
S3 BIT0 BIT1 BIT2 BIT3 BIT4 BIT5 BIT6 BIT7 BIT0 BIT1 BIT2 BIT3 BIT4 BIT5 BIT6 BIT7
0 1 0 0 0 0 1 1
FRAME CODE
Figure 7 Closed Capation format
12
P = Parity Bit
VP5311B/VP5511B
Interval
Description
Encoder minimum
Encoder nominal
Encoder maximum
10.500µs
10.750µs
A
H-sync to clock run-in
B
Clock run-in 2, 3
6.5D (12.910µs)
C
Clock run-in to third start bit 3
2.0D (3.972µs)
D
Data bit 1, 3
1.0D (1.986µs)
10.250µs
characters 4
E
Data
H
Horizontal line 1
16.0D (31.778µs)
32.0D (63.556)
Rise / fall time of data bit transitions 5
0.240µs
0.288µs
48 IRE
50 IRE
52 IRE
Data bit low (logic level zero) 6
Clock run-in minimum
0 IRE
0 IRE
2 IRE
Data bit differential (high - low)
Clock run-in differential (max. - min)
48 IRE
50 IRE
52 IRE
Data bit high (logic level
Clock run-in maximum
one) 6
Table. 5 Closed Caption data timing. (source EIA R - 4.3 Sept 16 1992)
Notes
1. The Horizontal line frequency f H is nominally 15734.26Hz ±0.05Hz. Interval D shall be adjusted to D = 1/(f H x 32) for the
instantaneous f H at line 21.
2. The clock run-in signal consists of 7.0 cycles of a 0.5034965MHz (1/D) sine wave when measured from the leading to trailing
0 IRE points. The sine wave is to be symmetrical about the 25 IRE level.
3. The negative going midpoints (half amplitude) of the clock run-in shall be coherent with the midpoints (half amplitude) of the
Start and Data bit transitions.
4. Two characters, each consisting of 7 data bits and 1 odd parity bit.
5. 2 T Bar, measured between the 10% and 90% amplitude points.
6. The clock run-in maximum level shall not differ from the data bit high level by more than ±1 IRE. The clock run-in minimum
level shall not differ from the data bit low level by more than ±1 IRE.
13
VP5311B/VP5511B
FERRITE
+5V
BEAD
VDD
10nF
2k2Ω
I2C
BUS
VDD, AVDD
28
54
SCL
LUMA
30
SDA
26
COMP 52
SA1
27 SA2
SCL
SDA
SA1
SA2
VIDEO IN
39-46
8
35
REFSQ
15
PXCK
3-10
GPP
CLAMP
COMP
SYNC
34
17
18
OUTPUT
FILTER
LUMA OUT
100µF
+5V
PD0-7
58
CHROMA
REFSQ
DACGAIN 51 769Ω
OUTPUT
FILTER
CHROMA OUT
PXCK
D0-7
8
RESET
GND
100µF
2k2Ω
AT EVERY
VDD PIN
VREF
50
VREF
100nF
RESET
COMP 56
OUT
OUTPUT
FILTER
COMP OUT
CLAMP
COMP
SYNC
GND, AGND
GND
Figure 8 Typical application diagram, SLAVE mode. (Output filter - see Fig.9)
15pF
1.0µH
470pF
220pF
75Ω
EXT
75Ω
GND
Figure 9 Output reconstruction filter
14
VP5311B/VP5511B
Note:
The VP5311 is only available to customers with a valid and existing authorisation to purchase issued by MACROVISION
CORPORATION.
This device is protected by U.S. patent numbers 4631603, 4577216 and 4819098 and other intellectual property rights. Use of
the Macrovision anticopy process in the device is licensed by Macrovision for non-commercial, home and limited exhibition uses
only. Reverse engineering or disassembly is prohibited.
15
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