INTERSIL HMP8115

HMP8115
NTSC/PAL Video Decoder
April 1998
Features
Description
• (M) NTSC and (B, D, G, H, I, M, N, NC) PAL Operation
- Optional Auto Detect of Video Standard
- ITU-R BT.601 (CCIR601) and Square Pixel Operation
The HMP8115 is a high quality NTSC and PAL decoder with
internal A/D converters. It is compatible with NTSC M, PAL
B, D, G, H, I, M, N, and combination N (NC) video standards.
• Digital Output Formats
- VMI Compatible
- 8-Bit, 16-Bit 4:2:2 YCbCr
- 15-Bit (5,5,5), 16-Bit (5,6,5) RGB
- Linear or Gamma-Corrected
- 8-Bit BT.656
Both composite and S-video (Y/C) input formats are supported. A 2-line comb filter plus a user-selectable chrominance trap filter provide high quality Y/C separation. User
adjustments include brightness, contrast, saturation, hue,
and sharpness.
Data during the vertical blanking interval (VBI), such as
closed captioning, widescreen signalling and teletext, may
be captured and output as BT.656 ancillary data. Closed
captioning and widescreen signalling information may also
be read out via the I2C interface.
• Analog Input Formats
- Three Analog Composite Inputs
- Analog Y/C (S-Video) Input
• “Sliced” VBI Data Capture Capabilities
- Closed Captioning
- Widescreen Signalling (WSS)
- BT.653 System B, C and D Teletext
- NABTS (North American Broadcast Teletext)
- WST (World System Teletext)
Ordering Information
• 2-Line (1H) Comb Filter Y/C Separator
NOTES:
PART NUMBER
HMP8115CN
HMPVIDEVAL/ISA
TEMP.
RANGE (oC)
0 to 70
PACKAGE
PKG. NO.
80 Ld PQFP
Q80.14x20
Evaluation Board: ISA Frame Grabber
• Fast I2C Interface
1. PQFP is also known as QFP and MQFP.
• Two 8-Bit ADCs
2. Evaluation Board and Reference Design descriptions are in the
Applications section.
Applications
• Multimedia PCs
• Video Conferencing
• Video Compression Systems
• Video Security Systems
• LCD Projectors and Overhead Panels
• Related Products
- NTSC/PAL Encoders: HMP815x, HMP817x
- NTSC/PAL Decoders: HMP8112A
• Related Literature
- AN9644: Composite Video Separation Techniques
- AN9716: Widescreen Signalling
- AN9717: YCbCr to RGB Considerations
- AN9728: BT.656 Video Interface for ICs
- AN9738: VMI Video Interface for ICs
CAUTION: These devices are sensitive to electrostatic discharge. Users should follow proper IC Handling Procedures.
http://www.intersil.com or 407-727-9207 | Copyright © Intersil Corporation 1999
1
File Number
4283.5
HMP8115
Table of Contents
PAGE
Introduction. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5
External Video Processing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
ANALOG VIDEO INPUTS. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
ANTI-ALIASING FILTERS. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
S-VIDEO CHROMA GAIN CONTROL . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5
5
5
5
Digitization of Video . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
A/D CONVERSION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
AGC AND DC RESTORATION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
INPUT SIGNAL DETECTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
VERTICAL SYNC AND FIELD DETECTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Y/C SEPARATION. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
INPUT SAMPLE RATE CONVERTER . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
COMB FILTER . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
CHROMA DEMODULATION. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
OUTPUT SAMPLE RATE CONVERTER . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
CLK2 INPUT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5
5
5
6
6
6
6
6
6
6
7
Digital Processing of Video . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
UV TO CbCr CONVERSION. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
DIGITAL COLOR GAIN CONTROL . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
COLOR KILLER . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Y PROCESSING. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
CbCr PROCESSING. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
YCbCr OUTPUT FORMAT PROCESSING . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
RGB OUTPUT FORMAT PROCESSING . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
BUILT-IN VIDEO GENERATION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
7
7
7
7
7
8
8
8
9
Pixel Port Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
9
HSYNC AND VSYNC TIMING . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
FIELD TIMING . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
BLANK AND DVALID TIMING. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
PIXEL OUTPUT PORT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
8-BIT YCbCr OUTPUT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
16-BIT YCbCr, 15-BIT RGB, OR 16-RGB OUTPUT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
8-BIT BT.656 OUTPUT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
9
9
10
11
11
12
14
Advanced Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
CLOSED CAPTIONING . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
WIDESCREEN SIGNALLING (WSS) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
BT.656 ANCILLARY DATA. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
BT.656 CLOSED CAPTIONING AND WIDE SCREEN SIGNALLING . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
TELETEXT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
REAL TIME CONTROL INTERFACE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
15
15
16
17
17
18
20
Host Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
21
HMP8115 Control Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
22
Pinout . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
35
Pin Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
36
Applications Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
PCB LAYOUT CONSIDERATIONS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
EVALUATION BOARD . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
RELATED APPLICATION NOTES . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
38
38
38
38
Electrical Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
40
2
3
C
CLAMP
LOGIC
AND
GAIN
CONTROL
AGC
AND
CLAMP
LOGIC
INPUT
MUX
EXTERNAL
ANTIALIASING
FILTER
C_CAP
GAIN_CTRL
LAGC_CAP
L_CAP
NTSC-PAL3/Y
NTSC-PAL2
NTSC-PAL1
+
+
-
8-BIT
ADC
CLAMP
RESET
INTREQ
MICROPROCESSOR
INTERFACE AND
CONTROL
8-BIT
ADC
DIGITAL COMPARATOR
SYNC LEVEL
BLACK LEVEL
WHITE PEAK LEVEL
DIGITAL COMPARATORS
YIN
EXTERNAL
ANTIALIASING
FILTER
YOUT
Functional Block Diagram
SDA
SCL
INPUT
SAMPLE
RATE
CONVERTER
COLOR
TRAP
FIELD VSYNC
LINE
LOCK
PLL
VSYNC
DETECT
LOCKED
HSYNC
DETECT
COLOR
ADJUST
USER
ADJUST
CHROMA
PLL
COLOR
DEMODULATION
Y/C
SEPARATION
VBI
DETECTION AND
DECODING LOGIC
VBI STATUS BITS
OUTPUT
TIMING
AND
FIFO
OUTPUT
SAMPLE
RATE
CONVERTER
P[15:0]
DVALID
HSYNC
BLANK
VBIVALID
RGB
LOGIC
USER
ADJUST.
HMP8115
Functional Block Diagram (Continued)
CLK
(24.54, 27.0 OR 29.5MHz)
4FSC
CLOCK
HUE
ADJUST
CHROMA
PLL LOOP
FILTER
CHROMA
PLL NCO
FIELD
VSYNC
GENLOCK LOSS
VSYNC
DETECT
CHROMA
PHASE
DETECTOR
HSYNC
DETECT
LINE LOCKED
PLL LOOP FILTER
CLK TO
4FSC RATIO
AGC
ADJUST
LINE LOCKED
NCO
SATURATION
ADJUST
CR[7:0]
C
C,CVBS
DATA
4
INPUT
SAMPLE
RATE
CONVERTER
Y,CVBS
Y DATA
C DATA
LINE
DELAY
COMB
FILTER
CHROMA
DEMODULATOR
U,V
U, V TO CbCr
COLOR
SPACE
CONVERTER
AND COLOR
KILLER
LP FILTER
CbCr
ENABLE
Y DATA
HORIZONTAL
M Y DATA AND VERTICAL
Y DATA U
SHARPNESS
X
ADJUST
SHARPNESS
ADJUST
OUTPUT
SAMPLE
RATE
CONVERTER
CHROMA
TRAP
Y
ENABLE
VBI DETECTION
AND DECODING LOGIC
LOCKED
HMP8115
M
U
X
C,CVBS
DATA
HSYNC
M
U
X
SYNC
STRIPPER,
BRIGHTNESS,
AND CONTRAST
ADJUST
STANDARD
SELECT
RGB
LOGIC
LP FILTER
MUX
MUX
ENABLE
P[15:0]
HSYNC,VSYNC, BLANK,
FIELD, DVALID, VBIVALID
OUTPUT
TIMING
AND
FIFO
HMP8115
Introduction
inside the decoder as determined by bits 7 and 6 of the
COLOR PROCESSING register 06H. In addition to the internal AGC, the designer can also apply some gain to the
chroma before it reaches the internal AGC logic. This gain is
controlled by pin 28. The voltage at this pin determines the
gain of the chroma before it gets digitized by the chroma A/D
with a typical gain performance as shown in Figure 2.
The HMP8115 is designed to decode baseband composite
or S-video NTSC and PAL signals, and convert them to
either digital YCbCr or RGB data. In addition to performing
the basic decoding operations, the HMP8115 includes hardware to decode different types of VBI data and to generate
digital video patterns for a blue screen, black screen and full
screen color bars.
7
The digital PLLs are designed to synchronize to all NTSC
and PAL standards. A chroma PLL is used to maintain
chroma lock for demodulation of the color information; a linelocked PLL is used to maintain vertical spatial alignment.
The PLLs are designed to maintain lock even in the event of
VCR headswitches and multipath noise.
6
TEMPERATURE = 25oC
VCC = 5V
LINEAR GAIN
5
The HMP8115 contains two 8-bit A/D converters and an I2C
interface for programming internal registers.
4
3
2
External Video Processing
1
Before a video signal can be digitized the decoder has some
external processing considerations that need to be
addressed. This section discusses those external aspects of
the HMP8115.
0
1.6
2.2
2.4
2.6
2.8
3.0
3.2
3.4
FIGURE 2. CHROMINANCE AMPLIFIER GAIN
The HMP8115 supports either three composite or two composite and one S-video input.
Digitization of Video
Three analog video inputs (NTSC/PAL 1-3) are used to
select which one of three composite video sources are to be
decoded. To support S-video applications, the Y channel
drives the NTSC/PAL 3 analog input, and the C channel
drives the C analog input.
Prior to A/D conversion, the video signal is DC restored and
gained to generate known video levels into the digital processing logic. This process is addressed in the “AGC and
DC Restoration” section. After digitization, sample rate converters and a comb filter are used to perform color separation and demodulation.
The analog inputs must be AC-coupled to the video signals,
as shown in the Applications section.
A/D CONVERSION
Video data is sampled at the CLK2 frequency then processed by the input sample rate converter. The output levels
of the ADC after AGC processing are:
ANTI-ALIASING FILTERS
An external anti-alias filter is required to achieve optimum
performance and prevent high frequency components from
being aliased back into the video image.
(M) NTSC
(M, N) PAL
For the NTSC/PAL 1-3 inputs, a single filter is connected
between the YOUT and YIN pins. For the C input, the antialiasing filter should be connected before the C input. A recommended filter is shown in Figure 1.
R1
L1
332
8.2µH
C1
33pF
2.0
CONTROL VOLTAGE ON THE GAIN_CTRL PIN
ANALOG VIDEO INPUTS
YOUT
1.8
C2
82pF
white
black
blank
sync
YIN
224
76
64
0
(B, D, G, H, I, NC)
PAL
213
64
64
0
AGC AND DC RESTORATION
R2
4.02K
S-VIDEO CHROMA GAIN CONTROL
The AGC amplifier attenuates or amplifies the analog video
signal to ensure that the sync tip level generates code 0. The
difference from the ideal sync tip level of 0 is used to control
the amount of attenuation or gain of the analog video signal.
The capacitor on the LAGC_CAP pin is used to store the
voltage which sets the gain level of the input video amplifier.
The Chroma portion of S-video is AC coupled through an
anti-aliasing filter as shown in the applications section.
Unlike the composite/luma inputs, the Automatic Gain Control (AGC) for the chroma portion of S-video is done digitally
DC restoration positions the video signal such that the DC
level of the back porch generates an average code 64. The
back porch is sampled to determine the average value. The
capacitor on the L_CAP pin is used to store the voltage
FIGURE 1. RECOMMENDED ANTI-ALIASING FILTER
5
HMP8115
Y/C SEPARATION
which sets the DC offset level into the input video amplifier.
During the S-video mode of operation the capacitor on the
C_CAP pin performs the same function as the L_CAP
capacitor, except the chroma video amplifier’s DC offset is
set so that the chroma A/D generates a code of 128 during
the back porch. The internal timing windows for AGC and DC
Restoration are show in Figure 3.
A composite video signal has the luma (Y) and chroma (C)
information mixed in the same video signal. The Y/C separation process is responsible for separating the composite
video signal into these two components. The HMP8115 utilizes a comb filter to minimize the artifacts that are associated with the Y/C separation process.
INPUT SAMPLE RATE CONVERTER
The input sample rate converter is used to convert video
data sampled at the CLK2 rate to a virtual 4xfSC sample rate
for comb filtering and color demodulation. An interpolating
filter is used to generate the 4xfSC samples as illustrated in
Figure 4.
VIDEO INPUT
INCOMING VIDEO SAMPLES
DC RESTORE
TIME
AGC
RESAMPLED VIDEO
FIGURE 3. AGC AND DC RESTORE INTERNAL TIMING
TIME
4xfSC
INPUT SIGNAL DETECTION
It is assumed there is no video input if a horizontal sync is
not detected for 16 consecutive lines. When no video has
been detected, nominal video timing is generated for the
previously detected or programmed standard. A maskable
interrupt is included to flag when no video has been detected
(bit 6 of the INTERRUPT MASK register 0FH) allowing for
blue/black/color bar output modes to be enabled if desired.
The vertical sync interrupt can be used in determining when
a video signal is present at the currently selected video mux
input. Bit 0 of register 0FH is used to enable vertical sync
interrupts.
FIGURE 4. SAMPLE RATE CONVERSION
COMB FILTER
A 2-line comb filter, using a single line delay, is used to perform part of the Y/C separation process. During S-video
operation, the Y signal bypasses the comb filter; the C signal
is processed by the comb filter since it is an integral part of
the chroma demodulator. During PAL operation, the chroma
trap filter should also be enabled for improved performance.
Since a single line store is used, the chroma will normally
have a half-line vertical offset from the luma data. This may
be eliminated, vertically aligning the chroma and luma samples, at the expense of vertical resolution of the luma. Bit 0 of
the OUTPUT FORMAT register 02H controls this option.
VERTICAL SYNC AND FIELD DETECTION
The vertical sync and field detect circuit uses a low time
counter to detect the vertical sync sequence in the video
data stream. The low time counter accumulates the low time
encountered during any sync pulse, including serration and
equalization pulses. When the low time count exceeds the
vertical sync detect threshold, VSYNC is asserted immediately. FIELD is asserted at the same time that VSYNC is
asserted. FIELD is asserted low for odd fields and high for
even fields. Field is determined from the location in the video
line where VSYNC is detected. If VSYNC is detected in the
first half of the line, the field is odd. If VSYNC is detected in
the second half of a line, the field is even.
CHROMA DEMODULATION
The output of the comb filter is further processed using a
patented frequency domain transform to complete the Y/C
separation and demodulate the chromanance.
Demodulation is done at a virtual 4xfSC sample rate using
the interpolated data samples to generate U and V data. The
demodulation process decimates by 2 the U/V sample rate.
OUTPUT SAMPLE RATE CONVERTER
In the case of lost vertical sync or excessive noise that would
prevent the detection of vertical sync, the FIELD output will
continue to toggle. Lost vertical sync is declared if after 337
lines, a vertical sync period was not detected for 1 or 3
(selectable) successive fields as specified by bit 2 of the
GENLOCK CONTROL register 04H. When this occurs, the
PLLs are initialized to the acquisition state.
The output sample rate converter converts the Y, U and V
data from a virtual 4xfSC sample rate to the desired output
sample rate (i.e., 13.5MHz). It also vertically aligns the samples based on the horizontal sync information embedded in
the digital video data stream. The output sample rate is
determined by the selected video standard and whether
6
HMP8115
with the two previous lines having a color burst to limit lineto-line variations. A gain of 0.5x to 4x is used for Cb and Cr.
square or rectangular pixels are output. The output format is
4:2:2 for all modes except the RGB modes which use a 4:4:4
output format.
If “fixed gain control” is selected, the amplitude of the color
difference signals (CbCr) is multiplied by a constant, regardless of variations in the color burst amplitude. The constant
gain value is specified by the COLOR GAIN register 1CH. A
gain of 0.5x to 4x is used for Cb and Cr. Limiting the gain to
4x limits the amount of amplified noise.
CLK2 INPUT
Note that the color subcarrier is derived from CLK2. Any jitter
on CLK2 will be transferred to the color subcarrier, resulting
in color changes. Thus, CLK2 should be derived from a stable clock source, such as a crystal. The use of a PLL to generate CLK2 is not recommended. CLK2 must have a 50ppm
accuracy and at least a 60/40% duty cycle to ensure proper
operation.
If “freeze automatic gain control” is selected, the amplitude
of the color difference signals (CbCr) is multiplied by a constant. This constant is the value the AGC circuitry generated
when the “freeze automatic gain” command was selected.
The CLK2 clock rate must be one of the following frequencies:
COLOR KILLER
24.54MHz
27.00MHz
29.50MHz
The frequency of CLK2 must be 2x the desired output sample rate. The values in Table 1 below indicate the CLK2 clock
rate based on the video standard and pixel mode. The output sample rate for the given video standard and pixel mode
is half the CLK2 clock rate.
If “enable color killer” is selected, the color output is turned
off when the running average of the color burst amplitude is
below approximately 25% of nominal for four consecutive
fields. When the running average of the color burst amplitude is above approximately 25% of nominal for four consecutive fields, the color output is turned on. The color output is
also turned off when excessive phase error of the chroma
PLL is present.
TABLE 1. VIDEO STANDARD CLOCK RATE SELECTION
SUMMARY
If “force color off” is selected, color information is never
present on the outputs.
If “force color on” is selected, color information is present on
the outputs regardless of the color burst amplitude or
chroma PLL phase error.
ALLOWABLE CLK2
FREQUENCIES (MHz)
RECTANGULAR
PIXEL MODE
SQUARE
PIXEL MODE
(M) NTSC
27.00
24.54
(B, D, G, H, I, N) PAL
27.00
29.50
(M) PAL
27.00
24.54
(NC) PAL
27.00
29.50
VIDEO FORMAT
Y PROCESSING
The black level is subtracted from the luminance data to
remove sync and any blanking pedestal information. Negative values of Y are supported at this point to allow proper
decoding of “below black” luminance levels.
Scaling is done to position black at 8-bit code 0 and white at
8-bit code 219.
Digital Processing of Video
Once the luma and chroma have been separated the
HMP8115 then performs programmable modifications (i.e.
contrast, coring, color space conversions, color AGC, etc.) to
the decoded video signal.
The baseband U and V signals are scaled and offset to generate a nominal range of 16-240 for both the Cb and Cr data.
A chroma trap filter may be used to remove any residual
color subcarrier from the luminance data. The center frequency of the chroma trap is automatically determined from
the video standard being decoded. The chroma trap should
be disabled during S-video operation to maintain maximum
luminance bandwidth. Alternately, a 3MHz lowpass filter may
be used to remove high-frequency Y data. This may make a
noisy image more pleasing to the user, although softer.
DIGITAL COLOR GAIN CONTROL
Coring of the high-frequency Y data may be done to reduce
low-level high frequency noise.
UV TO CbCr CONVERSION
There are four types of color gain control modes available:
no gain control, automatic gain control, fixed gain control,
and freeze automatic gain control.
Coring of the Y data may also be done to reduce low-level
noise around black. This forces Y data with the following values to a value of 0:
If “no gain control” is selected, the amplitude of the color difference signals (CbCr) is not modified, regardless of variations in the color burst amplitude. Thus, a gain of 1x is
always used for Cb and Cr.
coring = 1: ± 1
coring = 2: ± 1, ± 2
coring = 3: ± 1, ± 2. ± 3
If “automatic gain control” is selected, the amplitude of the
color difference signals (CbCr) is compensated for variations
in the color burst amplitude. The burst amplitude is averaged
High-frequency components of the luminance signal may be
“peaked” to control the sharpness of the image. Maximum
gain may be selected to occur at either 2.6MHz or the color
7
HMP8115
The 15-bit R′G′B′ data may be converted to 15-bit linear
RGB, using the following equations. Although the PAL specifications specify a gamma of 2.8, a gamma of 2.2 is normally
used. The HMP8115 allows the selection of the gamma to
be either 2.2 or 2.8, independent of the video standard.
subcarrier frequency. This may be used to make the displayed image more pleasing to the user. It should not be
used if the output video will be compressed, as the circuit
introduces high-frequency components that will reduce the
compression ratio.
for gamma = 2.2:
The brightness control adds or subtracts a user-specified
DC offset to the Y data. The contrast control multiplies the Y
data by a user-specified amount. These may be used to
make the displayed image more pleasing to the user.
for R′G′B′ < 0.0812*31
R = (31)((R′/31)/4.5)
G = (31)((G′/31)/4.5)
B = (31)((B′/31)/4.5)
Finally, a value of 16 is added to generate a nominal range of
16 (black) to 235 (white).
for R′G′B′ >= 0.0812*31
CbCr PROCESSING
R = (31)(((R′/31) + 0.099)/1.099)2.2
G = (31)(((G′/31) + 0.099)/1.099)2.2
B = (31)(((B′/31) + 0.099)/1.099)2.2
The CbCr data is lowpass filtered to either 0.85 or 1.5MHz.
Coring of the CbCr data may be done to reduce low-level
noise around zero. This forces CbCr data with the following
values to a value of 128.
for gamma = 2.8:
coring = 1: 127, 129
coring = 2: 126, 127, 129, 130
coring = 3: 125, 126, 127, 129, 130, 131
R = (31)(R′/31)2.8
G = (31)(G′/31)2.8
B = (31)(B′/31)2.8
The saturation control multiplies the CbCr data by a userspecified amount. This may be used to make the displayed
image more pleasing to the user. The CbCr data may also
be optionally multiplied by the contrast value to avoid color
shifts when changing contrast.
16-Bit R′G′B′
The following YCbCr to R′G′B′ equations are used to maintain the proper black and white levels:
R′ = 0.142(Y - 16) + 0.194(Cr - 128)
G′ = 0.288(Y - 16) - 0.201(Cr - 128) - 0.097(Cb - 128)
B′ = 0.142(Y - 16) + 0.245(Cb - 128)
The hue control provides a user-specified phase offset to the
color subcarrier during decoding. This may be used to correct slight hue errors due to transmission.
The resulting 16-bit R′G′B′ data has a range of 0 to 31 for R′
and B′, and a range of 0 to 63 for G′. Values less than 0 are
made 0; R′ and B′ values greater than 31 are made 31, G′
values greater than 63 are made 63.
YCbCr OUTPUT FORMAT PROCESSING
Y has a nominal range of 16 to 235. Cb and Cr have a nominal range of 16 to 240, with 128 corresponding to zero. Values less than 1 are made 1 and values greater than 254 are
made 254.
The 16-bit R′G′B′ data may be converted to 16-bit linear
RGB, using the following equations. Although the PAL specifications specify a gamma of 2.8, a gamma of 2.2 is normally
used. The HMP8115 allows the selection of the gamma to
be either 2.2 or 2.8, independent of the video standard.
While BLANK is asserted, Y is forced to have a value of 16,
with Cb and Cr forced to have a value of 128, unless VBI
data is present.
for gamma = 2.2:
RGB OUTPUT FORMAT PROCESSING
for R′B′ < 0.0812*31, G′ < 0.0812*63
The 4:2:2 YCbCr data is converted to 4:4:4 YCbCr data and
then converted to either 15-bit or 16-bit gamma-corrected
RGB (R′G′B′) data. While BLANK is asserted, RGB data is
forced to a value of 0.
R = (31)((R′/31)/4.5)
G = (63)((G′/63)/4.5)
B = (31)((B′/31)/4.5)
for R′B′ >= 0.0812*31, G′ >= 0.0812*63
15-Bit R′G′B′
R = (31)(((R′/31) + 0.099)/1.099)2.2
G = (63)(((G′/63) + 0.099)/1.099)2.2
B = (31)(((B′/31) + 0.099)/1.099)2.2
The following YCbCr to R′G′B′ equations are used to maintain the proper black and white levels:
R′ = 0.142(Y - 16) + 0.194(Cr - 128)
G′ = 0.142(Y - 16) - 0.099(Cr - 128) - 0.048(Cb - 128)
B′ = 0.142(Y - 16) + 0.245(Cb - 128)
for gamma = 2.8:
R = (31)(R′/31)2.8
G = (63)(G′/63)2.8
B = (31)(B′/31)2.8
The resulting 15-bit R′G′B′ data has a range of 0 to 31. Values less than 0 are made 0 and values greater than 31 are
made 31.
8
HMP8115
BUILT-IN VIDEO GENERATION
a fixed latency due to internal pipeline processing. The pulse
width of the HSYNC is defined by the END HSYNC register
36H, where the trailing edge of HSYNC has a programmable
delay of 0-510 CLK2 cycles from the leading edge.
When the blue screen, black screen or color bar output is
selected, a full-screen of blue, black or 75% colorbar output
is generated using the currently selected output format. The
type of screen to be generated is determined by bits 2 and 1
of the OUTPUT FORMAT register 02H. When built-in video
generation is not desired, the bits need to be set for normal
operation to pass decoded video.
The leading edge of VSYNC is asserted approximately half
way through the first serration pulse of each field. For an odd
field, the trailing edge of VSYNC is 5±1 CLK2 cycles after
the trailing edge of the HSYNC that follows the last equalization pulse. Refer to Figures 5 and 7. For an even field, the
trailing edge of VSYNC is 5±1 CLK2 cycles leading the leading edge of the HSYNC that follows the last equalization
pulse. Refer to Figures 6 and 8.
If a video source is input, it will be used to provide the video
timing. If an input video source is not detected, internallygenerated video timing will be used.
Pixel Port Timing
FIELD TIMING
The the timing and format of the output data and control signals is presented in the following sections.
When field information can be determined from the input
video source, the FIELD output pin reflects the video source
field state. When field information cannot be determined
from the input video source, the FIELD output pin alternates
its state at the beginning of each field. FIELD changes state
5±1 CLK2 cycles before the leading edge of VSYNC.
HSYNC AND VSYNC TIMING
The HSYNC and VSYNC output timing is VMI v1.4 compatible. Figures 5-8 illustrate the video timing. The leading edge
of HSYNC is synchronous to the video input signal and has
NTSC(M)
LINE #
524
525
1
2
3
4
5
6
7
8
9
10
PAL(M)
LINE #
521
522
523
524
525
1
2
3
4
5
6
7
VIDEO
INPUT
HSYNC
VSYNC
FIELD
‘ODD’ FIELD
‘EVEN’ FIELD
NOTE:
3. The trailing edge of VSYNC is 5±1 clocks after the trailing edge of HSYNC to be VMI compatible and to indicate a transition to an odd field.
FIGURE 5. NTSC(M) AND PAL(M) HSYNC, VSYNC AND FIELD TIMING DURING AN EVEN TO ODD FIELD TRANSITION
NTSC(M)
LINE #
PAL(M)
LINE #
262
263
264
265
266
267
268
269
270
271
272
273
259
260
261
262
263
264
265
266
267
268
269
270
VIDEO
INPUT
HSYNC
VSYNC
FIELD
‘ODD’ FIELD
‘EVEN’ FIELD
NOTE:
4. The trailing edge of VSYNC is 5±1 clocks after the leading edge of HSYNC to be VMI compatible and to indicate a transition to an even field.
FIGURE 6. NTSC(M) AND PAL(M) HSYNC, VSYNC AND FIELD TIMING DURING AN ODD TO EVEN FIELD TRANSITION
9
HMP8115
LINE #
621
622
623
624
625
1
2
3
4
5
6
7
VIDEO
INPUT
HSYNC
VSYNC
FIELD
‘ODD’ FIELD
‘EVEN’ FIELD
NOTE:
5. The trailing edge of VSYNC is 5±1 clocks after the trailing edge of HSYNC is to be VMI compatible and to indicate a transition to an odd field.
FIGURE 7. PAL(B,D,G,H,I,N,NC) HSYNC, VSYNC AND FIELD TIMING DURING AN EVEN TO ODD FIELD TRANSITION
LINE #
309
310
311
312
313
314
315
316
317
318
319
320
VIDEO
INPUT
HSYNC
VSYNC
FIELD
‘ODD’ FIELD
‘EVEN’ FIELD
NOTE:
6. The trailing edge of VSYNC is 5±1 clocks after the leading edge of HSYNC to be VMI compatible and to indicate a transition to an even field.
FIGURE 8. PAL(B,D,G,H,I,N,NC) HSYNC, VSYNC AND FIELD TIMING DURING AN ODD TO EVEN FIELD TRANSITION
BLANK AND DVALID TIMING
During active scan lines BLANK is negated when the horizontal pixel count matches the value in the END H_BLANK
register 32H. A count of 00H corresponds to the 50% point of
the leading edge of the sync tip after leaving the part. BLANK
is asserted when the horizontal pixel count matches the value
in the START H_BLANK register 31H/30H. Note that horizontally, BLANK is programmable with two pixel resolution.
DVALID is asserted when P15-P0 contain valid data. The
timing and behavior of DVALID is dependent on the output
video format and the programmed values for bit 4
(DVLD_DCYC) and bit 5 (DVLD_LTC) of the GENLOCK
CONTROL register 04H. Refer to the specific output video
format sections that follow for the specific behavior for
DVALID.
START V_BLANK register 34H/33H and END V_BLANK register 35H determine which scan lines are blanked for each
field. During inactive scan lines, BLANK is asserted during
the entire scan line. Half-line blanking of the output video
cannot be done. Reference Figure 9 for active video timing
and use Table 2 for typical blanking programming values.
BLANK is used to determine if the HMP8115 is generating
active video data. BLANK should be used in conjunction with
DVALID to capture digital data from the decoder. BLANK,
DVALID and the video data are output after the internal pipeline latency and synchronous with the rising edge of CLK2.
TABLE 2. TYPICAL VALUES FOR HBLANK AND VBLANK REGISTERS
VIDEO STANDARD
(MSB/LSB)
ACTIVE
PIXELS/
LINE
TOTAL
PIXELS/
LINE
LAST
PIXEL
COUNT
START
H_BLANK
(31H/30H)
END
H_BLANK
(32H)
START
V_BLANK
(34H/33H)
END
V_BLANK
(35H)
720
720
858
864
857 (0359H)
863 (035FH)
842 (034AH)
852 (0354H)
122 (7AH)
132 (84H)
259 (0103H)
310 (0136H)
19 (13H)
22 (16H)
640
768
780
944
779 (030BH)
943 (03AFH)
758 (02F6H)
922 (039AH)
118 (76H)
154 (9AH)
259 (0103H)
310 (0136H)
19 (13H)
22 (16H)
RECTANGULAR PIXELS
NTSC (M), PAL (M)
PAL (B, D, G, H, I,N, NC)
SQUARE PIXELS
NTSC (M), PAL (M)
PAL (B, D, G, H, I,N, NC)
10
HMP8115
NTSC M
PAL B, D, G, H, I, N, NC
LINES 1 - 22 NOT ACTIVE
LINES 1 - 22 NOT ACTIVE
ODD FIELD
SYNC AND
BACK
PORCH
240 ACTIVE LINES
PER FIELD
(LINES 23-262)
288 ACTIVE LINES
PER FIELD
(LINES 23 - 310)
VERTICAL
BLANKING
480 ACTIVE
LINES/FRAME
(NTSC, PAL M)
EVEN FIELD
LINES 263 - 284 NOT ACTIVE
240 ACTIVE LINES
PER FIELD
(LINES 285 - 524)
LINE 525
NOT ACTIVE
LINES 311 - 335 NOT ACTIVE
FRONT
PORCH
576 ACTIVE
LINES/FRAME
(PAL)
288 ACTIVE LINES
PER FIELD
(LINES 336 - 623)
NUMBER OF PIXELS
RECTANGULAR (SQUARE)
NTSC
LINES 624-625
NOT ACTIVE
PAL
TOTAL PIXELS
858 (780)
864 (944)
TOTAL PIXELS
ACTIVE PIXELS
720 (640)
720 (768)
ACTIVE PIXELS
NOTE:
7. The line numbering for PAL (M) followings NTSC (M) line count minus 3 per the video standards.
FIGURE 9. TYPICAL ACTIVE VIDEO REGIONS
TABLE 3. PIXEL OUTPUT FORMATS
PIN NAME
8-BIT, 4:2:2, YCbCr
16-BIT, 4:2:2, YCbCr
15-BIT, RGB, (5,5,5)
16-BIT, RGB, (5,6,5)
BT.656
P0
P1
P2
P3
P4
P5
P6
P7
0
0
0
0
0
0
0
0
Cb0, Cr0
Cb1, Cr1
Cb2, Cr2
Cb3, Cr3
Cb4, Cr4
Cb5, Cr5
Cb6, Cr6
Cb7, Cr7
B0
B1
B2
B3
B4
G0
G1
G2
B0
B1
B2
B3
B4
G0
G1
G2
0
0
0
0
0
0
0
0
P8
P9
P10
P11
P12
P13
P14
P15
Y0, Cb0, Cr0
Y1, Cb1, Cr1
Y2, Cb2, Cr2
Y3, Cb3, Cr3
Y4, Cb4, Cr4
Y5, Cb5, Cr5
Y6, Cb6, Cr6
Y7, Cb7, Cr7
Y0
Y1
Y2
Y3
Y4
Y5
Y6
Y7
G3
G4
R0
R1
R2
R3
R4
0
G3
G4
G5
R0
R1
R2
R3
R4
YCbCr Data,
Ancillary Data,
SAV and EAV
Sequences
PIXEL OUTPUT PORT
If DLVD_LTC=1, DVALID has the same internal timing as the
first mode, but is ANDed with the CLK2 signal, and the result
is output onto the DVALID pin. This results in a gated CLK2
signal being output during the active video time on active
scan lines. Refer to Figure 11.
Pixel data is output via the P0-P15 pins. Refer to Table 3 for
the output pin definition as a function of the output mode.
8-BIT YCbCr OUTPUT
If 8-bit YCbCr data is generated, it is output following each
rising edge of CLK2. The YCbCr data is multiplexed as [Cb Y
Cr Y′ Cb Y Cr Y′...], with the first active data each scan line
containing Cb data. The pixel output timing is shown in Figures 10 and 11.
The DVALID output pin may be configured to operate in one
of two ways. The configuration is determined by the
DVLD_LTC bit (bit 4) of the GENLOCK CONTROL register
04H.
If DVLD_LTC=0, the DVALID output is continuously asserted
during the entire active video time on active scan lines if CLK2
is exactly 2x the desired output sample rate. DVALID being
asserted indicates valid pixel data is present on the P15-P8
pixel outputs. DVALID is never asserted during the blanking
intervals. Refer to Figure 10.
BLANK, HSYNC, VSYNC, DVALID, VBIVALID, and FIELD
are output following the rising edge of CLK2. When BLANK
is asserted and VBIVALID is deasserted, the YCbCr outputs
have a value of 16 for Y and 128 for Cb and Cr.
11
HMP8115
CLK
DVALID
BLANK
Cb0
P[15-8]
NOTE:
Y0
Cr0
Y1
Cb2
Y2
Cr2
Y3
Cb4
Y4
tDVLD
8. Y0 is the first active luminance pixel data of a line. Cb0 and Cr0 are first active chrominance pixel data in a line. Cb and Cr will alternate
every cycle due to the 4:2:2 subsampling. Pixel data is not output during the blanking period, but the values on the ports are forced to
blanking levels.
FIGURE 10. OUTPUT TIMING FOR 8-BIT YCbCr MODE (DVLD_LTC = 0)
CLK
DVALID
BLANK
P[15-8]
NOTES:
Cb0
Y0
Cr0
Y1
Cb2
Y2
Cr2
Y3
Cb4
Y4
tDVLD
9. Y0 is the first active luminance pixel data of a line. Cb0 and Cr0 are first active chrominance pixel data in a line. Cb and Cr will alternate
every cycle due to the 4:2:2 subsampling. Pixel data is not output during the blanking period, but the values on the ports are forced to
blanking levels.
10. When DVLD_LTC is set to 1, the polarity of DVALID needs to be set to active low, otherwise DVALID will stay low during active video and
be gated with the clock only during the blanking interval.
FIGURE 11. OUTPUT TIMING FOR 8-BIT YCbCr MODE (DVLD_LTC = 1)
16-BIT YCbCr, 15-BIT RGB, OR 16-RGB OUTPUT
which DVALID did not have a 50% duty cycle timing and
other timing variations. The timing diagrams for this mode
can be found in Figures 14 and 15.
In these output modes, DVALID may be configured to operate in one of four modes as controlled by the DVLD_LTC and
DVLD_DCYC bits of the GENLOCK CONTROL register
(04H). Bit 4 is the DVLD_LTC bit and bit 5 is the
DVLD_DCYC bit.
If DVLD_LTC=1 and DVLD_DCYC=0, DVALID is present the
entire line time on all scan lines. DVALID may occasionally
be negated for two consecutive CLK2 cycles just prior to
active video. In this mode DVALID is guaranteed have a 50%
duty cycle only during the active video times. The timing for
this mode differs from the timing shown in Figures 12 and 13
only in that DVALID will also be asserted during the blanking
portion of the video line time as described above.
If DVLD_LTC=0 and DVLD_DCYC=0, DVALID is present
only during the active video time on active scan lines. Thus,
DVALID being asserted indicates valid pixel data is present
on the P0-P15 pixel outputs. DVALID is never asserted during the blanking intervals. In this mode DVALID will have a
50% duty cycle only during the active video times. The timing diagrams for this mode can be found in Figures 12 and
13.
If DVLD_LTC=1 and DVLD_DCYC=1, DVALID is present
during the entire line time on all scan lines. DVALID is
asserted during the blanking intervals as needed to ensure a
constant number of total samples per line. The timing for this
mode differs from the timing shown in Figures 14 and 15
only in that DVALID will also be asserted during the blanking
portion of the video line time as described above.
If DVLD_LTC=0 and DVLD_DCYC=1, DVALID behaves the
same as the first mode, with the exception that DVALID does
not have a 50% duty cycle. This mode is intended for backward compatibility with HMP8112(A) timing dependencies in
12
HMP8115
BLANK, HSYNC, VSYNC, DVALID, VBIVALID, and FIELD
are output following the rising edge of CLK2. When BLANK
is asserted and VBIVALID is deasserted, the YCbCr outputs
have a value of 16 for Y and 128 for Cb and Cr; the RGB outputs have a value of 0.
If 16-bit YCbCr, 15-bit RGB data, or 16-bit RGB data is generated, it is output following the rising edge of CLK2 while
DVALID is asserted. Either linear or gamma-corrected RGB
data may be output. The pixel output timing is shown in Figures 12 to 15.
CLK
DVALID
BLANK
P15-P8
Y0
Y1
Y2
Y3
Y4
P7-P0
Cb0
Cr0
Cb2
Cr2
Cb4
tDVLD
NOTES:
11. Y0 is the first active luminance pixel data of a line. Cb0 and Cr0 are first active chrominance pixel data in a line. Cb and Cr will alternate
every cycle due to the 4:2:2 subsampling.
12. BLANK is asserted per Figure 9.
FIGURE 12. OUTPUT TIMING FOR 16-BIT YCbCr MODE (DVLD_LTC = 0, DVLD_DCYC = 0)
CLK
DVALID
P15-P11
[P14-P10]
R0
R1
R2
R3
R4
P10-P5
[P9-P5]
G0
G1
G2
G3
G4
P4-P0
B0
B1
B2
B3
B4
tDVLD
NOTE:
13. BLANK is asserted per Figure 9.
FIGURE 13. OUTPUT TIMING FOR 16-BIT [15-BIT] RGB MODE (DVLD_LTC = 0, DVLD_DCYC = 0)
13
HMP8115
CLK
DVALID
P15-P8
P7-P0
Y0
Y1
Y2
Y3
Y4
Cb0
Cr0
Cb2
Cr2
Cb4
tDVLD
NOTES:
14. Y0 is the first active luminance pixel of a line. Cb0 and Cr0 are first active chrominance pixels in a line. Cb and Cr will alternate every
cycle due to the 4:2:2 subsampling.
15. BLANK is asserted per Figure 9.
16. DVALID is asserted for every valid pixel during both active and blanking regions. DVALID is not a 50% duty cycle synchronous output and
will appear to jitter as the Output Sample Rate converter adjusts the output timing for various data rates and clock frequency inputs.
FIGURE 14. OUTPUT TIMING FOR 16-BIT YCbCr MODE (DVLD_LTC = 0, DVLD_DCYC = 1)
CLK
DVALID
BLANK
P15-P11
[P14-P10]
R0
R1
R2
R3
R4
P10-P5
[P9-P5]
G0
G0
G2
G2
G4
P4-P0
B0
B1
B2
B3
B4
NOTES:
tDVLD
17. BLANK is asserted per Figure 9.
18. DAVLID is asserted for every valid pixel during both active and blanking regions. DVALID is not a 50% duty cycle synchronous output
and will appear to jitter as the Output Sample Rate converter adjusts the output timing for various data rates and clock frequency inputs.
FIGURE 15. OUTPUT TIMING FOR 16-BIT [15-BIT] RGB MODE (DVLD_LTC = 0, DVLD_DCYC = 1)
8-BIT BT.656 OUTPUT
If BT.656 data is generated, it is output following each rising
edge of CLK2. The BT.656 EAV and SAV formats are shown
in Table 4 and the pixel output timing is shown in Figure 16.
The EAV and SAV timing is determined by the programmed
horizontal and vertical blank timing
During the blanking intervals, the YCbCr outputs have a
value of 16 for Y and 128 for Cb and Cr, unless ancillary data
is present.
Due to the use of digital PLLs and source video timing the
total # of samples per line may not equal exactly 1716
(NTSC) or 1728 (PAL). The active video portion of the
BT.656 data stream is always exactly 1440 continuous samples. Any line-to-line timing difference from nominal # of
samples per line, plus or minus, is accommodated in the horizontal blanking interval.
BLANK, HSYNC, VSYNC, DVALID, VBIVALID, and FIELD
are output following the rising edge of CLK2.
For proper operation, CLK2 must be exactly 2x the desired
output sample rate. The DVALID output is continuously
asserted during the entire active video time.
14
HMP8115
.
CLK
DVALID
BLANK
P[15-8]
FF
00
00
Status
Cb0
Y0
Cr0
Y1
Cb2
Y2
tDVLD
NOTES:
19. Y0 is the first active luminance pixel data of a line. Cb0 and Cr0 are first active chrominance pixel data in a line. Cb and Cr will alternate
every cycle due to the 4:2:2 subsampling. Pixel data is not output during the blanking period.
20. Notice that DVALID is not asserted during the preamble and that BLANK is still asserted.
21. See Table 4 for Status bit definitions.
FIGURE 16. OUTPUT TIMING FOR 8-BIT BT.656 MODE
TABLE 4. BT.656 EAV AND SAV SEQUENCES
PIXEL INPUT
P15
P14
P13
P12
P11
P10
P9
P8
1
1
1
1
1
1
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
F
V
H
P3
P2
P1
P0
Preamble
Status Word
NOTES:
22. P3 = V xor H; P2 = F xor H; P1 = F xor V; P0 = F xor V xor H
23. F: “0” = field 1; “1” = field 2
24. V: “1” during vertical blanking
25. H: “0” at SAV (start of active video); “1” at EAV (end of active video)
Advanced Features
Detection of Closed Captioning
In addition to digitizing an analog video signal the HMP8115
has hardware to process different types of Vertical Blanking
Interval (VBI) data as described in the following sections.
The closed caption decoder monitors the appropriate scan
lines looking for the clock run-in and start bits used by captioning. If found, it locks to the clock run-in, the caption data
is sampled and loaded into shift registers, and the data is
then transferred to the caption data registers.
“SLICED” VBI DATA CAPTURE
If the clock run-in and start bits are not found, it is assumed
the scan line contains video data unless other VBI information is detected, such as teletext.
The HMP8115 implements “sliced” data capture of select
types of VBI data. The VBI decoders incorporate detection
hysteresis to prevent them from rapidly turning on and off
due to noise and transmission errors. In order to handle realworld signals, the VBI decoders also compensate for DC offsets and amplitude variations.
Once the clock run-in and start bits are found on the appropriate scan line for four consecutive odd fields, the Closed
Captioning odd field Detect status bit is set to “1”. It is reset
to “0” when the clock run-in and start bits are not found on
the appropriate scan lines for four consecutive odd fields.
CLOSED CAPTIONING
During closed captioning capture, the scan lines containing
captioning information are monitored. If closed captioning is
enabled and captioning data is present, the caption data is
loaded into the caption data registers.
Once the clock run-in and start bits are found on the appropriate scan line for four consecutive even fields, the Closed
Captioning even field Detect status bit is set to “1”. It is reset
to “0” when the clock run-in and start bits are not found on
the appropriate scan lines for four consecutive even fields.
15
HMP8115
Reading the Caption Data
Detection of WSS
The caption data registers may be accessed in two ways: via
the I2C interface or as BT.656 ancillary data.
The WSS decoder monitors the appropriate scan lines looking for the run-in and start codes used by WSS. If found, it
locks to the run-in code, the WSS data is sampled and
loaded into shift registers, and the data is then transferred to
the WSS data registers.
Captioning Disabled on Both Lines
In this case, any caption data present is ignored.
The Caption odd field Read status bit and the Caption even
field Read status bit are always a “0”.
If the run-in and start codes are not found, it is assumed the
scan line contains video data unless other VBI information is
detected, such as teletext.
Odd Field Captioning
Once the run-in and start codes are found on the appropriate
scan line for four consecutive odd fields, the WSS Line 20
Detect status bit is set to “1”. It is reset to “0” when the run-in
and start codes are not found on the appropriate scan lines
for four consecutive odd fields.
In this case, any caption data present on line 284 (or line 281
or 335 in the PAL modes) is ignored. Caption data present
on line 21 (or line 18 or 22 in the PAL modes) is captured
into a shift register then transferred to CLOSED
CAPTION_ODD_A
register
20H
and
CLOSED
CAPTION_ODD_B register 21H.
Once the run-in and start codes are found on the appropriate
scan line for four consecutive even fields, the WSS Line 283
Detect status bit is set to “1”. It is reset to “0” when the clock
run-in and start bits are not found on the appropriate scan
lines for four consecutive even fields.
The Caption even field Read status bit is always a “0”. The
Caption odd field Read status bit is set to “1” after data has
been transferred from the shift register to the CLOSED
CAPTION_ODD_A and CLOSED CAPTION_ODD_B registers. It is set to “0” after the data has been read out.
Reading the WSS Data
The WSS data registers may be accessed in two ways: via
the I2C interface or as BT.656 ancillary data.
Even Field Captioning
In this case, any caption data present on line 21 (or line 18 or
22 in the PAL modes) is ignored. Caption data present on line
284 (or line 281 or 335 in the PAL modes) is captured into a
shift register then transferred to CLOSED CAPTION_EVEN_A
register 22H and CLOSED CAPTION_EVEN_B register 23H.
WSS Disabled on Both Lines
In this case, any WSS data present is ignored.
The WSS odd field Read status bit and the WSS even field
Read status bit are always a “0”.
The Caption odd field Read status bit is always a “0”. The
Caption even field Read status bit is set to “1” after data has
been transferred from the shift register to the CLOSED
CAPTION_EVEN_A and CLOSED CAPTION_EVEN_B registers. It is set to “0” after the data has been read out.
Odd Field WSS
In this case, any WSS data present on line 283 (or line 280
or 336 in the PAL modes) is ignored. WSS data present on
line 20 (or line 17 or 23 in the PAL modes) is captured into a
shift register then transferred to the WSS_ODD_A and
WSS_ODD_B data registers.
Odd and Even Field Captioning
Caption data present on line 21 (or line 18 or 22 in the PAL
modes) is captured into a shift register then transferred to
the
CLOSED
CAPTION_ODD_A
and
CLOSED
CAPTION_ODD_B registers. Caption data present on line 284
(or line 281 or 335 in the PAL modes) is captured into a shift
register then transferred to the CLOSED CAPTION_EVEN_A
and CLOSED CAPTION_EVEN_B registers.
The WSS even field Read status bit is always a “0”. The
WSS odd field Read status bit is set to “1” after data has
been
transferred from the shift register to the WSS_ODD_A and
WSS_ODD_B registers. It is set to “0” after the data has
been read out.
The Caption odd field Read status bit is set to “1” after data
has been transferred from the shift register to the CLOSED
CAPTION_ODD_A and CLOSED CAPTION_ODD_B registers. It is set to “0” after the data has been read out.
Even Field WSS
In this case, any WSS data present on line 20 (or line 17 or
23 in the PAL modes) is ignored. WSS data present on line
283 (or line 280 or 336 in the PAL modes) is captured into a
shift register then transferred to the WSS_EVEN_A and
WSS_EVEN_B data registers.
The Caption even field Read status bit is set to “1” after data
has been transferred from the shift register to the CLOSED
CAPTION_EVEN_A and CLOSED CAPTION_EVEN_B registers. It is set to “0” after the data has been read out.
The WSS odd field Read status bit is always a “0”. The WSS
even field Read status bit is set to “1” after data has been
transferred from the shift register to the WSS_EVEN_A and
WSS_EVEN_B registers. It is set to “0” after the data has
been read out.
WIDESCREEN SIGNALLING (WSS)
During WSS capture (ITU-R BT.1119 and EIAJ CPX-1204),
the scan lines containing WSS information are monitored. If
WSS is enabled and WSS data is present, the WSS data is
loaded into the WSS data registers.
16
HMP8115
Real-Time Control Interface (RTCI) information. Teletext and
RTCI data is only available as BT.656 ancillary data.
Odd and Even WSS
WSS data present on line 20 (or line 17 or 23 in the PAL
modes) is captured into a shift register then transferred to
the WSS_ODD_A and WSS_ODD_B registers. WSS data
present on line 283 (or line 280 or 336 in the PAL modes) is
captured into a shift register then transferred to the
WSS_EVEN_A and WSS_EVEN_B registers.
VBIVALID OUTPUT TIMING
The VBIVALID output is asserted when outputting closed
captioning, widescreen signalling, teletext or RTCI data as
BT.656 ancillary data. It is asserted during the entire BT.656
ancillary data packet time, including the preamble.
The WSS odd field Read status bit is set to “1” after data has
been transferred from the shift register to the WSS_ODD_A
and WSS_ODD_B registers. It is set to “0” after the data has
been read out.
BT.656 CLOSED CAPTIONING AND WIDE SCREEN
SIGNALLING
Table 5 illustrates the format when outputting the caption
data registers as BT.656 ancillary data. The ancillary data is
present during the horizontal blanking interval after the line
containing the captioning information.
The WSS even field Read status bit is set to “1” after data
has been transferred from the shift register to the
WSS_EVEN_A and WSS_EVEN_B registers. It is set to “0”
after the data has been read out.
Table 6 illustrates the format when outputting the WSS data
registers as BT.656 ancillary data. The ancillary data is
present during the horizontal blanking interval after the line
containing the WSS information.
BT.656 ANCILLARY DATA
Through the BT.656 interface the HMP8115 can generate
non-active video data which contains CC, WSS, teletext or
CLK
VBIVALID
P[15-8]
00
FF
FF
DATA ID
BLK #
# BYTES/4
BYTE #1
BYTE #2
BYTE #3
BYTE #4
tDVLD
NOTES:
26. BT.656 VBI ancillary starts with a 00H, FFH and FFH sequence which is opposite to the SAV/EAV sequence of FFH, 00H and 00H.
27. During active VBI data intervals, DVALID is deasserted and BLANK is asserted.
FIGURE 17. OUTPUT TIMING FOR BT.656 VBI DATA TRANSFERS (CC, WSS, TELETEXT, RTCI)
TABLE 5. READING THE CLOSED CAPTION DATA AS BT.656 ANCILLARY DATA
PIXEL OUTPUT
Preamble
P15
P14
P13
P12
P11
P10
P9
P8
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
Data ID
P14
ep
1
1
0
0
0
0 = odd field data
1 = even field data
Data Block Number
P14
ep
0
0
0
0
0
1
Data Word Count
P14
ep
0
0
0
0
0
1
Caption Data
P14
ep
0
0
bit 15
bit 14
bit 13
bit 12
P14
ep
0
0
bit 11
bit 10
bit 9
bit 8
P14
ep
0
0
bit 7
bit 6
bit 5
bit 4
P14
ep
0
0
bit 3
bit 2
bit 1
bit 0
P14
bit 6
bit 5
bit 4
bit 3
bit 2
bit 1
bit 0
CRC
NOTES:
28. ep = even parity for P8-P13.
29. CRC = Sum of P8-P14 of Data ID through last user data word. Preset to all zeros, carry is ignored.
17
HMP8115
TABLE 6. OUTPUTTING THE SLICED WSS DATA AS BT.656 ANCILLARY DATA
PIXEL OUTPUT
P15
P14
P13
P12
P11
P10
P9
P8
Preamble
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
Data ID
P14
ep
1
1
0
0
1
0 =odd field data
1 =even field data
Data Block Number
P14
ep
0
0
0
0
0
1
Data Word Count
P14
ep
0
0
0
0
1
0
WSS Data
P14
ep
0
0
0
0
bit 13
bit 12
P14
ep
0
0
bit 11
bit 10
bit 9
bit 8
P14
ep
0
0
bit 7
bit 6
bit 5
bit 4
P14
ep
0
0
bit 3
bit 2
bit 1
bit 0
P14
ep
0
0
0
0
bit 5
bit 4
P14
ep
0
0
bit 3
bit 2
bit 1
bit 0
P14
ep
0
0
0
0
0
0
P14
ep
0
0
0
0
0
0
P14
bit 6
bit 5
bit 4
bit 3
bit 2
bit 1
bit 0
WSS CRC
Data
CRC
NOTES:
30. ep = even parity for P8-P13.
31. WSS CRC data = “00 0000” during PAL operation.
32. CRC = Sum of P8-P14 of Data ID through last user data word. Preset to all zeros, carry is ignored.
TELETEXT
If a teletext clock run-in is found before line 23 or line 289 for
NTSC and (M) PAL, or line 336 for (B, D, G, H, I, N, NC) PAL,
the VBI Teletext Detect status bit is immediately set to “1”. If
not found by these lines, the status bit is immediately reset to
“0”.
The HMP8115 supports ITU-R BT.653 625-line and 525-line
teletext system B, C and D capture. NABTS (North American
Broadcast Teletext Specification) is the same as BT.653 525line system C, which is also used to transmit Intel Intercast™
information. WST (World System Teletext) is the same as
BT.653 system B. Figure 18 shows the basic structure of a
video signal that contains teletext data.
Accessing the Teletext Data
The teletext data must be output as BT.656 ancillary data.
The I2C interface does not have the bandwidth to output
teletext information when needed.
The scan lines containing teletext information are monitored.
If teletext is enabled and teletext data is present, the teletext
data is output as BT.656 ancillary data.
Table 7 illustrates the teletext BT.656 ancillary data format
and Figure 17 depicts the portion of the incoming teletext
signal which is sliced and output as part of the ancillary data
stream. The teletext data is present during the horizontal
blanking interval after the line containing the teletext information. The actual BT.656 bytes that contain teletext data
only contain 4 bits of the actual data packet. Note that only
the data packet of Figure 18 is sent as ancillary data; the
clock run-in is not included in the data stream.
Detection of Teletext
The teletext decoder monitors the scan lines, looking for the
16-bit clock run-in (sometimes referred to as the clock synchronization code) used by teletext. If found, it locks to the
clock run-in, the teletext data is sampled and loaded into
shift registers, and the data is then transferred to internal
holding registers.
If the clock run-in is not found, it is assumed the scan line
contains video data unless other VBI information is detected,
such as WSS.
Intercast™ is a trademark of Intel Corporation.
18
HMP8115
CLOCK
RUN-IN
DATA PACKET
Bit 0
MSB
NOTES:
33. The MSB is bit number: 271 for system C, 279 for system B 525-line and 343 for system B 625-line.
34. The clock run-in is 16 bits wide for both systems and is not included in the BT.656 ancillary data stream.
35. The bit rate is 5.727272 Mbits/second for system B and C on 525/60 systems and 6.9375 and 5.734375 Mbits/second respectively for
625/50 systems.
FIGURE 18. TELETEXT VBI VIDEO SIGNAL
TABLE 7. OUTPUTTING THE SLICED TELETEXT DATA AS BT.656 ANCILLARY DATA
PIXEL INPUT
P15
P14
P13
P12
P11
P10
P9
P8
Preamble
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
Data ID
P14
ep
1
1
0
1
0
0
Data Block Number
P14
ep
0
0
0
0
0
1
Data Word Count
P14
ep
0
1
0
1
1
0
Teletext Data
(B, 625-line = 43 bytes)
(B, 525-line = 35 bytes)
(C = 34 bytes)
P14
ep
0 = 525-line
1 = 625-line
0 = system B
1 = system C
bit 343
bit 342
bit 341
bit 340
P14
ep
0
0
bit 339
bit 338
bit 337
bit 336
:
Reserved
CRC
P14
ep
0
0
bit 7
bit 6
bit 5
bit 4
P14
ep
0
0
bit 3
bit 2
bit 1
bit 0
P14
ep
0
0
0
0
0
0
P14
ep
0
0
0
0
0
0
P14
bit 6
bit 5
bit 4
bit 3
bit 2
bit 1
bit 0
NOTES:
36. ep = even parity for P8-P13.
37. CRC = Sum of P8-P14 of Data ID through last user data word. Preset to all zeros, carry is ignored.
38. For 525-line system B, bits 280-343 are “0”.
39. For system C, bits 272-343 are “0”.
19
HMP8115
REAL TIME CONTROL INTERFACE
The PSW bit is always a “0” for NTSC encoding. During PAL
encoding, it indicates the sign of V (“0” = negative; “1” = positive) for that scan line.
The Real Time Control Interface (RTCI) outputs timing information for a NTSC/PAL encoder as BT.656 ancillary data.
This allows the encoder to generate “clean” output video.
RTCI information via BT.656 ancillary data is shown in Table
8. If enabled, this transfer occurs once per line and is completed before the start of the SAV sequence.
TABLE 8. OUTPUTTING RTCI AS BT.656 ANCILLARY DATA
PIXEL INPUT
P15
P14
P13
P12
P11
P10
P9
P8
Preamble
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
Data ID
P14
ep
1
1
0
1
0
1
Data Block Number
P14
ep
0
0
0
0
0
1
Data Word Count
P14
ep
0
0
0
0
1
1
HPLL
Increment
P14
ep
0
0
0
0
0
0
P14
ep
0
0
0
0
0
0
P14
ep
0
0
0
0
0
0
P14
ep
0
0
0
0
0
0
P14
ep
PSW
0
bit 31
bit 30
bit 29
bit 28
P14
ep
F2 = 0
F1 = 0
bit 27
bit 26
bit 25
bit 24
FSCPLL
Increment
:
CRC
P14
ep
0
0
bit 7
bit 6
bit 5
bit 4
P14
ep
0
0
bit 3
bit 2
bit 1
bit 0
P14
bit 6
bit 5
bit 4
bit 3
bit 2
bit 1
bit 0
NOTES:
40. ep = even parity for P8-P13.
41. CRC = Sum of P8-P14 of Data ID through last user data word. Preset to all zeros, carry is ignored.
20
HMP8115
During I2C write cycles, the first data byte after the slave
address is treated as the control register sub address and is
written into the internal address register. Any remaining data
bytes sent during an I2C write cycle are written to the control
registers, beginning with the register specified by the
address register as given in the first byte. The address register is then autoincremented after each additional data byte
sent on the I2C bus during a write cycle. Writes to reserved
bits within registers or reserved registers are ignored.
Host Interface
All internal registers may be written to or read by the host
processor at any time, except for those bits identified as
read-only. The bit descriptions of the control registers are
listed in Tables 9-48.
The HMP8115 supports the fast-mode (up to 400 kbps) I2C
interface consisting of the SDA and SCL pins. The device
acts as a slave for receiving and transmitting data over the
serial interface. When the interface is not active, SCL and
SDA must be pulled high using external 4kΩ pull-up resistors. The slave address for the HMP8115 is 88H.
In order to perform a read from a specific control register
within the HMP8115, an I2C bus write must first be performed to properly setup the address register. Then an I2C
bus read can be performed to read from the desired control
register(s). As a result of needing the write cycle for a read
cycle there are actually two START conditions as shown in
Figure 21. The address register is then autoincremented
after each byte read during the I2C read cycle. Reserved
registers return a value of 00H .
Data is placed on the SDA line when the SCL line is low and
held stable when the SCL line is pulled high. Changing the
state of the SDA line while SCL is high will be interpreted as
either an I2C bus START or STOP condition as indicated by
Figure 20.
tSU:DATA
tBUF
SDA
tHD:DATA
SCL
tLOW
tHIGH
tR
tF
tSU:STOP
FIGURE 19. I2C TIMING DIAGRAM
SDA
SCL
8
1-7
S
START
CONDITION
9
R/W
ADDRESS
1-7
ACK
8
DATA
9
P
ACK
STOP
CONDITION
FIGURE 20. I2C SERIAL DATA FLOW
DATA WRITE
1000 1000
S
CHIP ADDR
FROM MASTER
A
SUB ADDR
A
0x88
DATA READ
S
DATA
A
REGISTER
POINTED
TO BY
SUB ADDR
DATA
A
P
FROM HMP8115
OPTIONAL FRAME
MAY BE REPEATED
n TIMES
1000 1000 (R/W)
CHIP ADDR
0x88
A
SUB ADDR
A
S
CHIP ADDR
A
0x89
DATA
REGISTER
POINTED
TO BY
SUB ADDR
A
DATA
OPTIONAL FRAME
MAY BE REPEATED
n TIMES
FIGURE 21. REGISTER WRITE/READ FLOW
21
NA
P
S = START CYCLE
P = STOP CYCLE
A = ACKNOWLEDGE
NA = NO ACKNOWLEDGE
HMP8115
HMP8115 Control Registers
TABLE 9. 8115 REGISTER SUMMARY
SUBADDRESS
CONTROL REGISTER
RESET/
DEFAULT
VALUE
USE
VALUE
COMMENTS
00H
PRODUCT ID
15H
01H
INPUT FORMAT
18H
Defaults to Autodetect of input video standard
02H
OUTPUT FORMAT
00H
Defaults to 16-bit YCbCr format
03H
OUTPUT CONTROL
00H
Defaults to outputs disabled
04H
GENLOCK CONTROL
01H
Defaults to 27MHz CLK2, Rectangular Pixel mode
05H
ANALOG INPUT CONTROL
00H
Defaults to input signal select = NTSC/PAL1
06H
COLOR PROCESSING
52H
07H
RESERVED
08H
LUMA PROCESSING
09H
Reserved
0AH
SLICED VBI DATA ENABLE
00H
0BH
SLICED VBI DATA OUTPUT
00H
0CH
VBI DATA STATUS
00H
0DH
Reserved
0EH
VIDEO STATUS
00H
0FH
INTERRUPT MASK
00H
10H
INTERRUPT STATUS
00H
11H-17H
Reserved
04H
-
-
-
18H
BRIGHTNESS
00H
19H
CONTRAST
80H
1AH
HUE
00H
1BH
SATURATION
80H
1CH
COLOR GAIN
40H
1DH
Reserved
1EH
SHARPNESS
10H
1FH
HOST CONTROL
00H
20H
CLOSED CAPTION_ODD_A
80H
21H
CLOSED CAPTION_ODD_B
80H
22H
CLOSED CAPTION_EVEN_A
80H
23H
CLOSED CAPTION_EVEN_B
80H
24H
WSS_ODD_A
00H
25H
WSS_ODD_B
00H
26H
WSS_CRC_ODD
00H
27H
WSS_EVEN_A
00H
28H
WSS_EVEN_B
00H
29H
WSS_CRC_EVEN
00H
2AH-2FH
Reserved
-
-
22
HMP8115
TABLE 9. 8115 REGISTER SUMMARY (Continued)
SUBADDRESS
CONTROL REGISTER
RESET/
DEFAULT
VALUE
USE
VALUE
30H
START H_BLANK LOW
4AH
Table 2
31H
START H_BLANK HIGH
03H
Table 2
32H
END H_BLANK
7AH
Table 2
33H
START V_BLANK LOW
02H
Table 2
34H
START V_BLANK HIGH
01H
Table 2
35H
END V_BLANK
12H
Table 2
36H
END HSYNC
40H
Table 2
37H
HSYNC DETECT WINDOW
FFH
20H
38H-3FH
Reserved
-
40H-7FH
Test and Unused
-
COMMENTS
Recommend HSYNC DETECT WINDOW= 20H
TABLE 10. PRODUCT ID REGISTER
SUB ADDRESS = 00H
BIT
NO.
7-0
FUNCTION
Product ID
DESCRIPTION
This 8-bit register specifies the last two digits of the product number.
It is a read-only register. Data written to it is ignored.
RESET
STATE
15H
TABLE 11. INPUT FORMAT REGISTER
SUB ADDRESS = 01H
BIT
NO.
7
6-5
FUNCTION
DESCRIPTION
Reserved
RESET STATE
0B
Video Timing Standard
These bits are read only unless D4 = “0”.
00 = (M) NTSC
01 = (B, D, G, H, I, N) PAL
10 = (M) PAL
11 = Combination (N) PAL; also called (NC) PAL
00B
4
Auto Detect
Video Standard
0 = Manual selection of video timing standard
1 = Auto detect of video timing standard
1B
3
Setup Select
Typically, this bit should be a “1” during (M) NTSC and (M, N) PAL
operation. Otherwise, it should be a “0”.
0 = Video source has a 0 IRE blanking pedestal
1 = Video source has a 7.5 IRE blanking pedestal
1B
2-0
Reserved
000B
23
HMP8115
TABLE 12. OUTPUT FORMAT REGISTER
SUB ADDRESS = 02H
BIT
NO.
FUNCTION
DESCRIPTION
RESET STATE
7-5
Output
Color
Format
000 = 16-bit 4:2:2 YCbCr
001 = 8-bit 4:2:2 YCbCr
010 = 8-bit BT.656
011 = 15-bit RGB
100 = 16-bit RGB
101 = reserved
110 = reserved
111 = reserved
000B
4-3
RGB
Gamma
Select
These bits are ignored except during RGB output modes.
00 = Linear RGB (gamma of input source = 2.2)
01 = Linear RGB (gamma of input source = 2.8)
10 = Gamma-corrected RGB (gamma = gamma of input source)
11 = reserved
00B
2-1
Output
Color
Select
00 = Normal operation
01 = Output blue field
10 = Output black field
11 = Output 75% color bars
00B
Vertical Pixel
Siting
This bit specifies whether or not the chrominance pixels have a halfline pixel offset from their associated luminance pixels.
0 = Half-line offset
1 = Aligned
0B
0
TABLE 13. OUTPUT CONTROL REGISTER
SUB ADDRESS = 03H
BIT
NO.
FUNCTION
DESCRIPTION
RESET
STATE
7
Video Data
Output Enable
This bit is used to enable the P0-P15 outputs.
0 = Outputs 3-stated
1 = Outputs enabled
0B
6
Video Timing
Output Enable
This bit is used to enable the HSYNC, VSYNC, BLANK, FIELD, VBIVALID, DVALID, and
INTREQ outputs.
0 = Outputs 3-stated
1 = Outputs enabled
0B
5
FIELD Polarity
0 = Active low (low during odd fields)
1 = Active high (high during odd fields)
0B
4
Polarity
BLANK
0 = Active low (low during blanking)
1 = Active high (high during blanking)
0B
3
HSYNC Polarity
0 = Active low (low during horizontal sync)
1 = Active high (high during horizontal sync)
0B
2
VSYNC Polarity
0 = Active low (low during vertical sync)
1 = Active high (high during vertical sync)
0B
1
DVALID Polarity
0 = Active low (low during valid pixel data)
1 = Active high (high during valid pixel data)
0B
0
VBIVALID
Polarity
0 = Active low (low during VBI data)
1 = Active high (high during VBI data)
0B
24
HMP8115
TABLE 14. GENLOCK CONTROL REGISTER
SUB ADDRESS = 04H
BIT
NO.
FUNCTION
DESCRIPTION
RESET
STATE
7
Aspect Ratio
Mode
0 = Rectangular (BT.601) pixels
1 = Square pixels
0B
6
Freeze Output
Timing Enable
Setting this bit to a “1” freezes the output timing at the end of the field. Resetting this bit
to a “0” resumes normal operation at the start of the next field.
0 = Normal operation
1 = Freeze output timing
0B
5
DVALID Duty Cycle
Control
(DVLD_DCYC)
This bit is ignored during the 8-bit YCbCr and BT.656 output modes.
During 16-bit YCbCr, 15-bit RGB, or 16-bit RGB output modes, this bit is defined as:
0 = DVALID has 50/50 duty cycle at the pixel output datarate
1 = DVALID goes active based on linelock. This will cause DVALID to not have a 50/50
duty cycle. This bit is intended to be used in maintaining backward compatibilty with the
HMP8112A DVALID output timing.
0B
4
DVALID Line Timing Control
(DVLD_LTC)
During 16-bit YCbCr, 15-bit RGB, or 16-bit RGB output modes, this bit is defined as:
0 = DVALID present only during active video time on active scan lines
1 = DVALID present the entire scan line time on all scan lines
During the 8-bit YCbCr and BT.656 output modes, this bit defines the DVALID output signal as:
0 = Normal timing
1 = DVALID signal ANDed with CLK2
0B
3
Missing HSYNC
Detect Select
This bit specifies the number of missing horizontal sync pulses before the device goes
into the horizontal lock acquisition mode. In mode “0”, the default value of the HPLL Adjust register should be used. In mode “1”, the typical values the HPLL Adjust register
should be 10H to 20H.
0 = 12 pulses
1 = 1 pulse
0B
2
Missing VSYNC
Detect Select
This bit specifies the number of missing vertical sync pulses before the device goes into
the vertical lock acquisition mode.
0 = 3 pulses
1 = 1 pulse
0B
1-0
CLK2 Frequency
This bit indicates the frequency of the CLK2 input clock.
00 = 24.54MHz
01 = 27.0MHz
10 = 29.5MHz
11 = Reserved
01B
TABLE 15. ANALOG INPUT CONTROL REGISTER
SUB ADDRESS = 05H
BIT
NO.
FUNCTION
7-3
Reserved
2-0
Video Signal
Input Select
DESCRIPTION
RESET
STATE
00000B
000 = NTSC/PAL 1
001 = NTSC/PAL 2
010 = NTSC/PAL 3
011 = S-video
100 = reserved
101 = reserved
110 = reserved
111 = reserved
000B
25
HMP8115
TABLE 16. COLOR PROCESSING REGISTER
SUB ADDRESS = 06H
BIT
NO.
FUNCTION
DESCRIPTION
RESET
STATE
7-6
Color Gain
Control Select
If a value of “10”, the color gain adjust register is used to specify the amount of color gain
to be applied.
00 = No gain control (gain = 1x)
01 = Automatic gain control
10 = Fixed gain control
11 = Freeze automatic gain control
01B
5-4
Color Killer
Select
00 = Force color on
01 = Enable color killer
10 = reserved
11 = Force color off
01B
3-2
Color Coring
Select
Coring may be used to reduce low-level noise around zero (code 128) in the CbCr signals.
00 = No coring
01 = 1 code coring
10 = 2 code coring
11 = 3 code coring
00B
1
Contrast Control
Select
This bit specifies whether the contrast control affects just the Y data (“0”) or both the Y
and CbCr data (“1”). To avoid color shifts when changing contrast, this bit should be a “1”.
0 = Contrast controls only Y data
1 = Contrast controls Y and CbCr data
1B
0
Color Lowpass
Filter Select
This bit selects the bandwidth of the CbCr data.
0 = 850kHz
1 = 1.5MHz
0B
TABLE 17. LUMA PROCESSING REGISTER
SUB ADDRESS = 08H
BIT
NO.
FUNCTION
DESCRIPTION
RESET
STATE
7-6
Y Filtering
Select
The chroma trap filter may be used to remove any residual color subcarrier information
from the Y channel. During S-video operation, it should be disabled. During PAL operation, it should be enabled. The 3MHz lowpass filter may be used to remove high-frequency noise.
00 = No filtering
01 = Enable chroma trap filter
10 = Enable 3.0MHz lowpass filter
11 = reserved
00B
5-4
Black Level Y
Coring Select
Coring may be used to reduce low-level noise around black in the Y signal.
00 = No coring
01 = 1 code coring
10 = 2 code coring
11 = 3 code coring
00B
3-2
High Frequency Y
Coring Select
Coring may be used to reduce high-frequency low-level noise in the Y signal.
00 = No coring
01 = 1 code coring
10 = 2 code coring
11 = 3 code coring
01B
1-0
Sharpness
Frequency Select
If a value of “01” or “10”, the sharpness adjust register is used to specify the amount of
sharpness to be applied.
00 = Bypass sharpness control
01 = Maximum gain at 2.6MHz
10 = Maximum gain at color subcarrier frequency
11 = reserved
00B
26
HMP8115
TABLE 18. SLICED VBI DATA ENABLE REGISTER
SUB ADDRESS = 0AH
BIT
NO.
RESET
STATE
FUNCTION
DESCRIPTION
7-6
Sliced
Closed Captioning
Enable
00 = Closed caption disabled
01 = Closed caption enabled for odd fields: line 21 for NTSC, line 18 for (M) PAL, or line
22 for (B, D, G, H, I, N, NC) PAL
10 = Closed caption enabled for even fields: line 284 for NTSC, line 281 for (M) PAL, or
line 335 for (B, D, G, H, I, N, NC) PAL
11 = Closed caption enabled for both odd and even fields
00B
5-4
Sliced
WSS Enable
00 = WSS disabled
01 = WSS enabled for odd fields: line 20 for NTSC; line 17 for (M) PAL, or line 23 for (B,
D, G, H, I, N, NC) PAL
10 = WSS enabled for even fields: line 283 for NTSC, line 280 for (M) PAL, or line 336
for (B, D, G, H, I, N, NC) PAL
11 = WSS enabled for both odd and even fields
00B
3-2
Sliced
Teletext
Enable
00 = Teletext disabled
01 = Teletext system B enabled
10 = Teletext system C enabled
11 = reserved
00B
1-0
Reserved
00B
TABLE 19. SLICED VBI DATA OUTPUT REGISTER
SUB ADDRESS = 0BH
BIT
NO.
FUNCTION
DESCRIPTION
RESET
STATE
7
Sliced
Closed Caption
BT.656 Output
Enable
This bit specifies whether or not to output the caption data registers as BT.656 ancillary
data. It is ignored unless captioning is enabled. Access via the I2C interface is always
available.
0 = Do not output as BT.656 ancillary data
1 = Output as BT.656 ancillary data
0B
6
Sliced WSS
BT.656 Output
Enable
This bit specifies whether or not to output the WSS data registers as BT.656 ancillary
data. It is ignored unless WSS is enabled. Access via the I2C interface is always
available.
0 = Do not output as BT.656 ancillary data
1 = Output as BT.656 ancillary data
0B
5
Sliced Teletext
BT.656 Output
Enable
This bit specifies whether or not to output teletext data as BT.656 ancillary data. It is ignored unless teletext is enabled.
0 = Do not output as BT.656 ancillary
1 = Output as BT.656 ancillary data
0B
4-1
0
Reserved
RTCI
BT.656 Output
Enable
0000B
This bit specifies whether or not to output RTCI data as BT.656 ancillary data.
0 = Do not output as BT.656 ancillary
1 = Output as BT.656 ancillary data
27
0B
HMP8115
TABLE 20. VBI DATA STATUS REGISTER
SUB ADDRESS = 0CH
BIT
NO.
FUNCTION
DESCRIPTION
RESET
STATE
7
Closed Captioning
Odd Field
Detect Status
This bit is read-only. Data written to this bit is ignored.
0 = Closed captioning not detected
1 = Closed captioning detected
0B
6
Closed Captioning
Even Field
Detect Status
This bit is read-only. Data written to this bit is ignored.
0 = Closed captioning not detected
1 = Closed captioning detected
0B
5
WSS
Odd Field
Detect Status
This bit is read-only. Data written to this bit is ignored.
0 = WSS not detected
1 = WSS detected
0B
4
WSS
Even Field
Detect Status
This bit is read-only. Data written to this bit is ignored.
0 = WSS not detected
1 = WSS detected
0B
3
VBI Teletext
Detect Status
This bit is read-only. Data written to this bit is ignored.
0 = Teletext not detected during vertical blanking interval
1 = Teletext detected during vertical blanking interval
0B
2-0
Reserved
000B
TABLE 21. VIDEO STATUS REGISTER
SUB ADDRESS = 0EH
BIT
NO.
FUNCTION
DESCRIPTION
RESET
STATE
7
Vertical Lock
Status
This bit is read-only. Data written to this bit is ignored.
0 = Not vertically locked
1 = Vertically locked
0B
6
Horizontal Lock
Status
This bit is read-only. Data written to this bit is ignored.
0 = Not horizontally locked
1 = Horizontally locked
0B
5
Color Lock
Status
This bit is read-only. Data written to this bit is ignored.
0 = Not color locked
1 = Color locked
0B
4
Input Video
Detect Status
This bit is read-only. Data written to this bit is ignored.
0 = Input video not detected on selected video input
1 = Input video detected on selected video input
0B
3-0
Reserved
0000B
28
HMP8115
TABLE 22. INTERRUPT MASK REGISTER
SUB ADDRESS = 0FH
BIT
NO.
FUNCTION
DESCRIPTION
RESET
STATE
7
Genlock Loss
Interrupt Mask
If this bit is a “1”, an interrupt is generated when genlock is lost.
0 = Interrupt disabled
1 = Interrupt enabled
0B
6
Input Signal Loss
Interrupt Mask
If this bit is a “1”, an interrupt is generated when a video signal is no longer detected on
the selected video input.
0 = Interrupt disabled
1 = Interrupt enabled
0B
5
Closed Caption
Interrupt Mask
If this bit is a “1”, an interrupt is generated when the Caption_ODD_A and
Caption_ODD_B or the Caption_EVEN_A and Caption_EVEN_B data registers contain
new data.
0 = Interrupt disabled
1 = Interrupt enabled
0B
4
WSS
Interrupt Mask
If this bit is a “1”, an interrupt is generated when the WSS_ODD_A and WSS_ODD_B or
the WSS_EVEN_A and WSS_EVEN_B data registers contain new data.
0 = Interrupt disabled
1 = Interrupt enabled
0B
3
Teletext
Interrupt Mask
If this bit is a “1”, an interrupt is generated when teletext information is first detected at
the beginning of each field.
0 = Interrupt disabled
1 = Interrupt enabled
0B
2-1
0
Reserved
Vertical Sync
Interrupt Mask
00B
If this bit is a “1”, an interrupt is generated at the beginning of each field.
0 = Interrupt disabled
1 = Interrupt enabled
0B
TABLE 23. INTERRUPT STATUS REGISTER
SUB ADDRESS = 10H
BIT
NO.
FUNCTION
DESCRIPTION
RESET
STATE
7
Genlock Loss
Interrupt Status
If this bit is a “1”, the reason for the interrupt request was that genlock was lost. To clear
the interrupt request, a “1” must be written to this bit.
0B
6
Input Signal Loss
Interrupt Status
If this bit is a “1”, the reason for the interrupt request was that the input video source is
no longer present. To clear the interrupt request, a “1” must be written to this bit.
0B
5
Closed Caption
Interrupt Status
If this bit is a “1”, the reason for the interrupt request was that the Caption_ODD_A and
Caption_ODD_B or the Caption_EVEN_A and Caption_EVEN_B data registers contain
new data. To clear the interrupt request, a “1” must be written to this bit.
0B
4
WSS
Interrupt Status
If this bit is a “1”, the reason for the interrupt request was that the WSS_ODD_A and
WSS_ODD_B or the WSS_EVEN_A and WSS_EVEN_B data registers contain new data. To clear the interrupt request, a “1” must be written to this bit.
0B
3
Teletext
Interrupt Status
If this bit is a “1”, the reason for the interrupt request was that teletext data has been detected in the current field. To clear the interrupt request, a “1” must be written to this bit.
0B
2-1
0
Reserved
Vertical Sync
Interrupt Status
00B
If this bit is a “1”, the reason for the interrupt request was that a new field was started. To
clear the interrupt request, a “1” must be written to this bit.
29
0B
HMP8115
TABLE 24. BRIGHTNESS REGISTER
SUB ADDRESS = 18H
BIT
NO.
FUNCTION
7
Reserved
6-0
Brightness
Adjust
DESCRIPTION
RESET
STATE
0B
These bits control the brightness. They may have a value of +63 (“011 1111”) to -64 (“100
0000”), with positive values increasing brightness. A value of 0 (“000 0000”) has no effect
on the data.
0000000B
TABLE 25. CONTRAST REGISTER
SUB ADDRESS = 19H
BIT
NO.
7-0
FUNCTION
Contrast
Adjust
DESCRIPTION
These bits control the contrast. They may have a value of 0x (“0000 0000”) to 1.992x
(“1111 1111”). A value of 1x (“1000 0000”) has no effect on the data.
RESET
STATE
80H
TABLE 26. HUE REGISTER
SUB ADDRESS = 1AH
BIT
NO.
7-0
FUNCTION
Hue
Adjust
DESCRIPTION
These bits control the color hue. They may have a value of +30 degrees (“0111 1111”) to
-30 degrees (“1111 1111”). A value of 0 degrees (“0000 0000”) has no effect on the color
data.
RESET
STATE
00H
TABLE 27. SATURATION REGISTER
SUB ADDRESS = 1BH
BIT
NO.
7-0
FUNCTION
Saturation
Adjust
DESCRIPTION
These bits control the color saturation. They may have a value of 0x (“0000 0000”) to
1.992x (“1111 1111”). A value of 1x (“1000 0000”) has no effect on the color data. A value
of 0x (“0000 0000”) disables the color information.
RESET
STATE
80H
TABLE 28. COLOR GAIN REGISTER
SUB ADDRESS = 1CH
BIT
NO.
7-0
FUNCTION
Color Gain
Adjust
DESCRIPTION
These bits control the amount of gain control for the color difference (CbCr) signals. They
may have a value of 0.5x (“0010 0000”) to 3.98x (“1111 1111”). A value of 1x (“0100
0000”) has no effect on the data. This register is ignored unless the color gain control
mode selection is “fixed gain control”.
RESET
STATE
40H
TABLE 29. SHARPNESS REGISTER
SUB ADDRESS = 1EH
BIT
NO.
FUNCTION
7-6
Reserved
5-0
Sharpness
Adjust
DESCRIPTION
RESET
STATE
00B
These bits control the amount of gain control of high frequency luminance signals (either
2.6MHz or Fsc). They may have a value of +12dB (“11 1111”) to -12dB (“00 0100”). A
value of 0dB (“01 0000”) has no effect on the data. This register is ignored if the sharpness mode selection is “disable sharpness control” or “reserved”.
30
010000B
HMP8115
TABLE 30. HOST CONTROL REGISTER
SUB ADDRESS = 1FH
BIT
NO.
FUNCTION
DESCRIPTION
When this bit is set to 1, the entire device except the I2C bus is reset to a known state
exactly like the RESET input going active. The software reset will initialize all register bits
to their reset state. Once set this bit is self clearing after only 4 CLK periods. This bit is
cleared on power-up by the external RESET pin.
RESET
STATE
7
Software Reset
6
Reserved
5
Closed Caption
Odd Field
Read Status
This bit is read-only. Data written to this bit is ignored. The bit is cleared when the caption
data has been read out via the I2C interface or as BT.656 ancillary data.
0 = No new caption data
1 = Caption_ODD_A and Caption_ODD_B data registers contain new data.
0B
4
Closed Caption
Even Field
Read Status
This bit is read-only. Data written to this bit is ignored. The bit is cleared when the caption
data has been read out via the I2C interface or as BT.656 ancillary data.
0 = No new caption data
1 = Caption_EVEN_A and Caption_EVEN_B data registers contain new data.
0B
3
WSS
Odd Field
Read Status
This bit is read-only. Data written to this bit is ignored. The bit is cleared when the WSS
data has been read out via the I2C interface or as BT.656 ancillary data.
0 = No new WSS data
1 = WSS_ODD_A and WSS_ODD_B data registers contain new data.
0B
2
WSS
Even Field
Read Status
This bit is read-only. Data written to this bit is ignored. The bit is cleared when the WSS
data has been read out via the I2C interface or as BT.656 ancillary data.
0 = No new WSS data
1 = WSS_EVEN_A and WSS_EVEN_B data registers contain new data.
0B
1-0
0B
0B
Reserved
00B
TABLE 31. CLOSED CAPTION_ODD_A DATA REGISTER
SUB ADDRESS = 20H
BIT
NO.
7-0
FUNCTION
Odd Field
Caption Data
DESCRIPTION
If odd field captioning is enabled and present, this register is loaded with the first eight
bits of caption data on line 18, 21, or 22. Bit 0 corresponds to the first bit of caption information. Data written to this register is ignored.
RESET
STATE
80H
TABLE 32. CLOSED CAPTION_ODD_B DATA REGISTER
SUB ADDRESS = 21H
BIT
NO.
15-8
FUNCTION
Odd Field
Caption Data
DESCRIPTION
If odd field captioning is enabled and present, this register is loaded with the second eight
bits of caption data on line 18, 21, or 22. Data written to this register is ignored.
RESET
STATE
80H
TABLE 33. CLOSED CAPTION_EVEN_A DATA REGISTER
SUB ADDRESS = 22H
BIT
NO.
7-0
FUNCTION
Even Field
Caption Data
DESCRIPTION
If even field captioning is enabled and present, this register is loaded with the first eight
bits of caption data on line 281, 284, or 335. Bit 0 corresponds to the first bit of caption
information. Data written to this register is ignored.
31
RESET
STATE
80H
HMP8115
TABLE 34. CLOSED CAPTION_EVEN_B DATA REGISTER
SUB ADDRESS = 23H
BIT
NO.
15-8
FUNCTION
Even Field
Caption Data
DESCRIPTION
If even field captioning is enabled and present, this register is loaded with the second
eight bits of caption data on line 281, 284, or 335. Data written to this register is ignored.
RESET
STATE
80H
TABLE 35. WSS_ODD_A DATA REGISTER
SUB ADDRESS = 24H
BIT
NO.
7-0
FUNCTION
Odd Field
WSS Data
DESCRIPTION
If odd field WSS is enabled and present, this register is loaded with the first eight bits of
WSS information on line 17, 20, or 23. Bit 0 corresponds to the first bit of WSS information. Data written to this register is ignored.
RESET
STATE
00H
TABLE 36. WSS_ODD_B DATA REGISTER
SUB ADDRESS = 25H
BIT
NO.
FUNCTION
15-14
Reserved
13-8
Odd Field
WSS Data
DESCRIPTION
RESET
STATE
00B
If odd field WSS is enabled and present, this register is loaded with the second six bits of
WSS information on line 17, 20, or 23. Data written to this register is ignored.
000000B
TABLE 37. WSS_CRC_ODD DATA REGISTER
SUB ADDRESS = 26H
BIT
NO.
FUNCTION
7-6
Reserved
5-0
Odd Field
WSS CRC Data
DESCRIPTION
RESET
STATE
00B
If odd field WSS is enabled and present during NTSC operation, this register is loaded
with the six bits of CRC information on line 20. It is always a “000000” during PAL operation. Data written to this register is ignored.
000000B
TABLE 38. WSS_EVEN_A DATA REGISTER
SUB ADDRESS = 27H
BIT
NO.
7-0
FUNCTION
Even Field
WSS Data
DESCRIPTION
If even field WSS is enabled and present, this register is loaded with the first eight bits of
WSS information on line 280, 283, or 336. Bit 0 corresponds to the first bit of WSS information. Data written to this register is ignored.
RESET
STATE
00H
TABLE 39. WSS_EVEN_B DATA REGISTER
SUB ADDRESS = 28H
BIT
NO.
FUNCTION
15-14
Reserved
13-8
Even Field
WSS Data
DESCRIPTION
RESET
STATE
00B
If even field WSS is enabled and present, this register is loaded with the second six bits
of WSS information on line 280, 283, or 336. Data written to this register is ignored.
32
000000B
HMP8115
TABLE 40. WSS_CRC_EVEN DATA REGISTER
SUB ADDRESS = 29H
BIT
NO.
FUNCTION
7-6
Reserved
5-0
Even Field
WSS CRC Data
DESCRIPTION
RESET
STATE
00B
If even field WSS is enabled and present during NTSC operation, this register is loaded
with the six bits of CRC information on line 283. It is always a “000000” during PAL operation. Data written to this register is ignored.
000000B
TABLE 41. START H_BLANK LOW REGISTER
SUB ADDRESS = 30H
BIT
NO.
7-0
FUNCTION
Assert BLANK
Output Signal
DESCRIPTION
This 8-bit register is cascaded with Start H_Blank High Register to form a 10-bit
start_horizontal_blank REGISTER. It specifies the horizontal count (in 1x clock cycles) at
which to assert BLANK each scan line. Bit 0 is always a “0”, so the start of horizontal
blanking may only be done with two pixel resolution. The leading edge of HSYNC is count
000H.
RESET
STATE
4AH
TABLE 42. START H_BLANK HIGH REGISTER
SUB ADDRESS = 31H
BIT
NO.
15-10
9-8
FUNCTION
DESCRIPTION
Reserved
Assert BLANK
Output Signal
RESET
STATE
000000B
This 2-bit register is cascaded with Start H_Blank Low Register to form a 10-bit
start_horizontal_blank register. It specifies the horizontal count (in 1x clock cycles) at
which to assert BLANK each scan line. The leading edge of HSYNC is count 000H.
11B
TABLE 43. END H_BLANK REGISTER
SUB ADDRESS = 32H
BIT
NO.
7-0
FUNCTION
Negate BLANK
Output Signal
DESCRIPTION
This 8-bit register specifies the horizontal count (in 1x clock cycles) at which to negate
BLANKeach scan line. Bit 0 is always a “0”, so the end of horizontal blanking may only
be done with two pixel resolution. The leading edge of HSYNC is count 000H.
RESET
STATE
7AH
TABLE 44. START V_BLANK LOW REGISTER
SUB ADDRESS = 33H
BIT
NO.
7-0
FUNCTION
Assert BLANK
Output Signal
DESCRIPTION
This 8-bit register is cascaded with Start V_Blank High Register to form a 9-bit
start_vertical_blank register. It specifies the line number to assert BLANK each field.
For NTSC operation, it occurs on line (n + 5) on odd fields and line (n + 268) on even
fields. For PAL operation, it occurs on line (n + 5) on odd fields and line (n + 318) on even
fields.
33
RESET
STATE
02H
HMP8115
TABLE 45. START V_BLANK HIGH REGISTER
SUB ADDRESS = 34H
BIT
NO.
15-9
8
FUNCTION
DESCRIPTION
Reserved
Assert BLANK
Output Signal
RESET
STATE
0000000B
This 1-bit register is cascaded with Start V_Blank Low Register to form a 9-bit
start_vertical_blank register.
1B
TABLE 46. END V_BLANK REGISTER
SUB ADDRESS = 35H
BIT
NO.
7-0
FUNCTION
Negate BLANK
Output Signal
DESCRIPTION
This 8-bit register specifies the line number to negate BLANK each field.
RESET
STATE
12H
For NTSC operation, it occurs on line (n + 5) on odd fields and line (n + 268) on even
fields. For PAL operation, it occurs on line (n + 5) on odd fields and line (n + 318) on even
fields.
TABLE 47. END HSYNC REGISTER
SUB ADDRESS = 36H
BIT
NO.
7-0
FUNCTION
Negate HSYNC
Output Signal
DESCRIPTION
This 8-bit register specifies the horizontal count at which to negate HSYNC each scan
line. Values may range from 0 (0000 0000) to 510 (1111 1111) CLK2 cycles. The leading
edge of HSYNC is count 00H.
RESET
STATE
40H
TABLE 48. HSYNC DETECT WINDOW REGISTER
SUB ADDRESS = 37H
BIT
NO.
7-0
FUNCTION
Horizontal Sync
Detect Window
DESCRIPTION
This 8-bit register specifies the width of the window (in 1x clock samples) to look for horizontal sync pulses each line. The window is centered about where the horizontal sync
pulse should be located.
If the horizontal sync pulse falls inside this window, the digital PLL will lock to it. If the horizontal sync pulse falls outside this window, the digital PLL is immediately reset to have
the same timing.
Recommend using a value of 20H to optimize the response time of the digital PLL.
34
RESET
STATE
FFH
HMP8115
Pinout
GND
VCC
DEC_T
LAGC_CAP
LCAP
VCC
NC
NC
GND
HSYNC
VSYNC
GND
VCC
FIELD
DVALID
BLANK
80 LEAD PQFP
TOP VIEW
80 79 78 77 76 75 74 73 72 71 70 69 68 67 66 65
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
64
63
62
61
60
59
58
57
56
55
54
53
52
51
50
49
48
47
46
45
44
43
42
41
25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40
GND
VCC
WPE
GAIN_CNTL
CCAP
DEC_L
VCC
NC
GND
RESET
GND
GND
VCC
CLK2
GND
SDA
AGND
VAA
AGND
NC
NTSC/PAL3
NTSC/PAL2
NTSC/PAL1
YIN
YOUT
AGND
AGND
VAA
CLK2
VAA
AGND
AGND
A/D_TEST
NC
C
NC
AGND
AGND
AGND
AGND
35
P15
P14
GND
VBIVALID
P13
VCC
P12
P11
P10
P9
P8
GND
VCC
P7
P6
P5
P4
P3
GND
P2
INTREQ
P1
P0
SCL
HMP8115
Pin Description
PIN
NAME
PIN
NUMBER
INPUT/
OUTPUT
P0-P15
42, 43, 45,
47-51, 54-58,
60, 63, 64
O
Pixel output pins. See Table 3.
HSYNC
71
O
Horizontal sync output. HSYNC is asserted during the horizontal sync intervals. The
polarity of HSYNC is programmable. This pin is three-stated after a RESET or software reset and should be pulled high through a 10K resistor.
VSYNC
70
O
Vertical sync output. VSYNC is asserted during the vertical sync intervals. The polarity of VSYNC is programmable. This pin is three-stated after a RESET or software reset and should be pulled high through a 10K resistor.
FIELD
67
O
FIELD output. The polarity of FIELD is programmable. This pin is three-stated after a
RESET or software reset and should be pulled high through a 10K resistor.
BLANK
65
O
Composite blanking output. BLANK is asserted during the horizontal and vertical
blanking intervals. The polarity of is programmable. This pin is three-stated after a
RESET or software reset and should be pulled high through a 10K resistor.
DVALID
66
O
Data valid output. DVALID is asserted during CLK2 cycles that contain valid pixel data. This pin is three-stated after a RESET or software reset and should be pulled high
through a 10K resistor.
CLK2
38, 13
I
2x pixel clock inputs. All CLK2 pins must be connected together. This clock must be
a continuous, free-running clock.
RESET
34
I
Reset control input. A logical zero for a minimum of four CLK2 cycles resets the device. RESET must be a logical one for normal operation.
SDA
40
I/O
SCL
41
I
I2C interface clock input.
WPE
27
I
White Peak Enable. When enabled (“1”), the video gain is reduced when the A/D output code exceeds 248. When disabled (“0”), the video amplifier will clip when the A/D
output code reaches code 255.
VBIVALID
61
O
Vertical Blanking Interval Valid output. VBIVALID is asserted during CLK2 cycles that
contain valid VBI (Vertical Blanking Interval) data such as Closed Captioning, Teletext, and Wide Screen Signalling data. The polarity of VBIVALID is programmable.
This pin is three-stated after a RESET or software reset and should be pulled high
through a 10K resistor.
INTREQ
44
O
Interrupt Request Output. This is an open-drain output and requires an external 10K
pull-up resistor to VCC.
NTSC/PAL 1
7
I
Composite Video Input. This input must be AC-coupled to the video signal (using a
1µF capacitor) and terminated with a 75Ω resistor, as shown in the Applications section. These components should be as close to this pin as possible for best performance. If not used, this pin should be connected to AGND through a 0.1µF capacitor.
NTSC/PAL 2
6
I
Composite Video Input. This input must be AC-coupled to the video signal (using a
1µF capacitor) and terminated with a 75Ω resistor, as shown in the Applications section. These components should be as close to this pin as possible for best performance. If not used, this pin should be connected to AGND through a 0.1µF capacitor.
NTSC/PAL 3
(Y)
5
I
Composite video or Luminance (Y) video input. This input must be AC-coupled to the
video signal (using a 1µF capacitor) and terminated with a 75Ω resistor, as shown in
the Applications section. These components should be as close to this pin as possible for best performance. If not used, this pin should be connected to AGND through
a 0.1µF capacitor.
DESCRIPTION
I2C interface data input/output.
36
HMP8115
Pin Description
(Continued)
PIN
NAME
PIN
NUMBER
INPUT/
OUTPUT
C
19
I
Chrominance (C) video input. This input must be AC-coupled to the video signal (using a 1µF capacitor) and terminated with a 75Ω resistor, as shown in the Applications
section. These components, and the corresponding anti-aliasing lowpass filter,
should be as close to this pin as possible for best performance. If not used, this pin
should be connected to AGND through a 0.1µF capacitor.
YOUT
9
O
Analog output of the video multiplexer. This output should be lowpass filtered and input via the YIN pin, as shown in the Applications section. The anti-aliasing lowpass
filter should be as close to YOUT and YIN as possible for best performance.
YIN
8
I
Analog input to the ADC.
GAIN_CTRL
28
I
Gain Control Input. A DC voltage is used to set the video amplifier’s gain, as shown
in Figure 2. The reference circuit should be as close to this pin as possible for best
performance.
DEC_T
78
I
Decoupling for A/D Converter Reference. A 0.1µF capacitor should be connected between this pin and AGND, as shown in the Applications section. This capacitor should
be as close to this pin as possible for best performance.
DEC_L
30
I
Decoupling for A/D Converter Reference. A 0.1µF capacitor should be connected between this pin and AGND, as shown in the Applications section. This capacitor should
be as close to this pin as possible for best performance.
LAGC_CAP
77
I
Capacitor connection for Luminance AGC Circuit. Controls the AGC loop time constant. A 0.01µF capacitor should be connected between this pin and AGND, as shown
in the Applications section. This capacitor should be as close to this pin as possible
for best performance.
LCAP
76
I
Capacitor connection for Luminance Clamp Circuit. Controls the clamp loop time constant. A 0.047µF capacitor should be connected between this pin and AGND, as
shown in the Applications section. This capacitor should be as close to this pin as
possible for best performance.
CCAP
29
I
Capacitor connection for Chrominance Clamp Circuit. Controls the clamp loop time
constant. A 0.047µF capacitor should be connected between this pin and AGND, as
shown in the Applications section. This capacitor should be as close to this pin as
possible for best performance.
VCC
26, 31,37, 52,
59, 68, 75, 79
I
Digital power supply pins. All VCC pins must be connected together.
GND
25, 33, 35, 36,
39, 46, 53, 62,
69, 72, 80
I
Digital ground pins. All GND pins must be connected together.
VAA
2, 12,14
I
Analog power supply pins. All VAA pins must be connected together.
AGND
1, 3, 10, 11,
15,16, 21, 22,
23, 24
I
Analog ground pins. All AGND pins must be connected together.
A/D TEST
17
O
A/D test pin. This pin must be left floating for proper operation.
NC
4, 18, 20, 32,
73, 74
DESCRIPTION
No Connect pins. These pins must be left floating for proper operation.
37
HMP8115
Applications Information
PCB LAYOUT CONSIDERATIONS
Analog Signals
A PCB board with a minimum of 4 layers is recommended,
with layers 1 and 4 (top and bottom) for signals and layers 2
and 3 for power and ground. The PCB layout should implement the lowest possible noise on the power and ground
planes by providing excellent decoupling.
Traces containing digital signals should not be routed over,
under, or adjacent to the analog output traces to minimize
crosstalk. If this is not possible, coupling can be minimized
by routing the digital signals at a 90 degree angle to the analog signals. The analog input traces should also not overlay
the VAA power plane to maximize high-frequency power supply rejection.
The optimum layout places the HMP8115 as close as possible to the power supply connector and the video input connector.
EVALUATION BOARD
Component Placement
HMPVIDEVAL/ISA
External components should be positioned as close as possible to the appropriate pin, ideally such that traces can be
connected point to point. Chip capacitors are recommended
where possible, with radial lead ceramic capacitors the second-best choice.
The HMPVIDEVAL/ISA evaluation board allows connecting
the HMP8115 into a PC ISA slot for evaluation. It includes
the HMP8115 NTSC/PAL decoder, 3MB of VRAM, and a
NTSC/PAL encoder. The board accepts composite or
S-video input and displays video on a standard TV. The ISA
bus and evaluation software allow easy performance evaluation of the HMP8115 using tools such as the Tektronix
VM700 video test system.
Power supply decoupling should be done using a 0.1µF
ceramic capacitor in parallel with a 0.01µF chip capacitor for
each group of VAA and VCC pins to ground. These capacitors should be located as close to the power and ground pins
as possible, using short, wide traces.
RELATED APPLICATION NOTES
Digital Ground Plane
Application Notes are also available on the Intersil Multimedia web site at http://www.semi.harris.com/mmedia.
All GND pins on the HMP8115 should be connected to the
digital ground plane of the board.
AN9644: Composite Video Separation Techniques
AN9716: Widescreen Signalling (WSS)
Analog Ground Plane
AN9717: YCbCr to RGB Considerations
A separate analog ground plane for the HMP8115 is recommended. All AGND pins on the HMP8115 should be connected to the analog ground plane. This analog ground
plane should be connected to the board’s digital ground
plane at a single point.
AN9728: BT.656 Video Interface for ICs
AN9738: Video Module Interface (VMI) for ICs
Analog Power Plane
The HMP8115 should have its own VAA power plane that is
isolated from the common power plane of the board, with a
gap between the two power planes of at least 1/8 inch. All
VAA pins on the HMP8115 must be connected to this analog
power plane. The analog power plane should be connected
to the board’s normal VCC power plane at a single point
though a low-resistance ferrite bead, such as a Ferroxcube
5659065-3B, Fair-Rite 2743001111, or TDK BF45-4001. The
ferrite bead provides resistance to switching currents,
improving the performance of HMP8115. A single 47µF
capacitor should also be used between the analog power
plane and the ground plane to control low-frequency power
supply ripple.
If a separate linear regulator is used to provide power to the
analog power plane, the power-up sequence should be
designed to ensure latchup will not occur. A separate linear regulator is recommended if the power supply noise on the VAA
pins exceeds 200mV.
38
HMP8115
U1
NTSC-PAL1
C1
NTSC-PAL2
C2
NTSC-PAL3/Y
C3
7
1.0µF
6
1.0µF
NTSC/PAL 1
NTSC/PAL 2
5 NTSC/PAL 3
1.0µF
R3
75
R2
75
R1
75
ANTI-ALIAS
FILTER
CHROMA
R4
75
C4
19
1.0µF
ANTI-ALIAS
FILTER
8
9
77
C5
0.01µF
C
76
C6
0.047µF
29
C7
0.047µF
YIN
YOUT
LAGC_CAP
LCAP
CCAP
P[7..0]
P7
P6
P5
P4
P3
P2
P1
P0
P15
P14
P13
P12
P11
P10
P9
P8
BLANK
DVALID
FIELD
HSYNC
VSYNC
VBIVALID
INTREQ
78
C8
0.1µF
C9
0.01µF
C10
0.1µF
30
DEC_T
DEC_L
C11
0.01µF
VAA
R5
1K
R6
750
28
RESET
SDA
SCL
CLK2
CLK2
TEST
51
50
49
48
47
45
43
42
64
63
60
58
57
56
55
54
VCC
R16
4K
BLANK
HSYNC
VSYNC
VBIVALID
44
34
40
41
38
13
36
27
R17
4K
DVALID
FIELD
INTREQ
RESET
27MHz
VAA
R7
10K
JP1
JUMPER
FIGURE 22. HMP8115 REFERENCE SCHEMATICS
39
VCC VCC
RP1
10K
65
66
67
71
70
61
GAIN_CNTL
WPE
P[15..8]
R8
50
C12
15pF
SDA
SCL
27MHz
HMP8115
Absolute Maximum Ratings
Thermal Information
Digital Supply Voltage (VCC to GND) . . . . . . . . . . . . . . . . . . . . 7.0V
Analog Supply Voltage (VAA to GND) . . . . . . . . . . . . . . . . . . . . 7.0V
Digital Input Voltages . . . . . . . . . . . . . . . GND - 0.5V to VCC + 0.5V
ESD Classification . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Class 1
Thermal Resistance (Typical, See Note 42)
θJA (oC/W)
PQFP Package . . . . . . . . . . . . . . . . . . . . . . . . . . . .
42
Maximum Power Dissipation
HMP8115CN . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1.9W
Maximum Storage Temperature Range . . . . . . . . . .-65oC to 150oC
Maximum Junction Temperatures . . . . . . . . . . . . . . . . . . . . . 150oC
Maximum Lead Temperature (Soldering 10s) . . . . . . . . . . . . 300oC
Operating Temperature Range
HMP8115CN . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 0oC to 70oC
CAUTION: Stresses above those listed in “Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress only rating and operation
of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied.
NOTE:
42. θJA is measured with the component mounted on an evaluation PC board in free air. Dissipation rating assumes device is mounted with
all leads soldered to printed circuit board.
Electrical Specifications
VCC = VAA = 5.0V, TA = 25oC
PARAMETER
SYMBOL
TEST CONDITION
MIN
TYP
MAX
UNITS
4.75
5
5.25
V
-
280
315
mA
-
105
115
mA
-
175
200
mA
-
1.47
1.66
W
POWER SUPPLY CHARACTERISTICS
Power Supply Voltage Range
VCC, VAA
Total Power Supply Current
ITOT
Digital Power Supply Current
ICC
Analog Power Supply Current
IAA
Total Power Dissipation
PTOT
(Note 43)
CLK2 = 29.5MHz,
VCC = VAA = 5.25V
Outputs Not Loaded
CLK2 = 29.5MHz,
VCC = VAA = 5.25V,
Outputs Not Loaded
DC CHARACTERISTICS: DIGITAL I/O (EXCEPT CLK2 and I2C INTERFACE)
Input Logic High Voltage
VIH
VCC = Max
2.0
-
-
V
Input Logic Low Voltage
VIL
VCC = Min
-
-
0.8
V
2.4
-
-
V
Output Logic High Voltage
VOH
IOH = -4mA, VCC = Max
Output Logic Low Voltage
VOL
IOL = 4mA, VCC = Min
-
-
0.4
V
VCC = Max
Input = 0V or 5V
-
-
10
µA
f = 1MHz, (Note 43)
All Measurements Referenced to
Ground, TA = 25oC
-
8
-
pF
-
-
10
µA
Input Leakage Current
Input/Output Capacitance
Three-State Output Current
Leakage
IIH, IIL
CIN, COUT
IOZ
DC CHARACTERISTICS: CLK2 DIGITAL INPUT
Input Logic High Voltage
VIH
VCC = Max
0.7xVCC
-
-
V
Input Logic Low Voltage
VIL
VCC = Min
-
-
0.3xVCC
V
Input Leakage Current
IIH
VCC = Max
Input = 0V or VCC
-
-
10
µA
- 450
-
-
µA
-
8
-
pF
IIL
Input Capacitance
CIN
CLK2 = 1MHz, (Note 43)
All Measurements Referenced to
Ground, TA = 25oC
40
HMP8115
Electrical Specifications
PARAMETER
VCC = VAA = 5.0V, TA = 25oC (Continued)
SYMBOL
TEST CONDITION
MIN
TYP
MAX
UNITS
DC CHARACTERISTICS: I2C INTERFACE
Input Logic High Voltage
VIH
VCC = Max
0.7xVCC
-
-
V
Input Logic Low Voltage
VIL
VCC = Min
-
-
0.3xVCC
V
3.0
-
-
V
Output Logic High Voltage
VOH
IOH = -1mA, VCC = Max
Output Logic Low Voltage
VOL
IOL = 3mA, VCC = Min
0
-
0.4
V
VCC = Max
Input = 0V or 5V
-
-
10
µA
SCL = 400kHz, (Note 43)
All Measurements Referenced
to GND, TA = 25oC
-
8
-
pF
20
-
29.5
MHz
40
-
60
%
Input Leakage Current
Input/Output Capacitance
IIH, IIL
CIN, COUT
AC CHARACTERISTICS: DIGITAL I/O (EXCEPT I2C INTERFACE)
CLK2 Frequency
CLK2 Waveform Symmetry
(Note 43)
CLK2 Pulse Width High
tPWH
13
-
-
ns
CLK2 Pulse Width Low
tPWL
13
-
-
ns
10
-
-
ns
(Note 44)
Data and Control Setup Time
tSU
Data and Control Hold Time
tHD
0
-
-
ns
tDVLD
0
5
8
ns
-
2
6
ns
CLK2 to Output Delay
tr, tf
Data and Control Rise/Fall Time
(Note 43)
AC CHARACTERISTICS: I2C INTERFACE
SCL Clock Frequency
fSCL
0
-
400
kHz
SCL Pulse Width Low
tLOW
1.3
-
-
µs
SCL Pulse Width High
tHIGH
0.6
-
-
µs
Data Hold Time
tHD:DATA
0
-
-
ns
Data Setup Time
tSU:DATA
100
-
-
ns
-
-
300
ns
-
-
300
ns
SDA, SCL Rise Time
tR
SDA, SCL Fall Time
tF
(Note43)
ANALOG INPUT PERFORMANCE
Composite Video Input Amplitude
(Sync Tip to White Level)
Input Termination of 75Ω and
1.0µF AC-Coupled
0.5
1.0
2.0
VP-P
Luminance (Y) Video
Input Amplitude
(Sync Tip to White Level)
Input Termination of 75Ω and
1.0µF AC-Coupled
0.5
1.0
2.0
VP-P
Chrominance (C) Video Input
Amplitude (Burst Amplitude)
Input Termination of 75Ω and
1.0µF AC-Coupled, (Note 43)
0.143
0.286
0.6
VP-P
200
-
-
kΩ
Video Input Impedance
RAIN
Note 43
41
HMP8115
Electrical Specifications
PARAMETER
Video Input Bandwidth
ADC Input Range
VCC = VAA = 5.0V, TA = 25oC (Continued)
SYMBOL
MIN
TYP
MAX
UNITS
5
-
-
MHz
AIN FULL SCALE
-
1
-
VP-P
AIN OFFSET
-
1.5
-
V
-
2
-
LSB
-
0.35
-
LSB
-
2
-
%
-
1
-
Deg.
-
2
-
Deg.
-
2
-
%
NTC-7 Composite (Note 43)
-
2
-
%
SNRL WEIGHTED
Pedestal Input (Note 43)
-
50
-
dB
tLOCK
Time from Initial Lock
Acquisition to an Error of
1 Pixel. (Note 43)
2
3
-
Fields
-
5
%
1 or 12
1 or 12
1 or 12
Hsyncs
1 or 3
1 or 3
1 or 3
Vsyncs
BW
ADC Integral Nonlinearity
INL
ADC Differential Nonlinearity
DNL
TEST CONDITION
1VP-P Sine Wave Input to
-3dBc Reduction, (Note 43)
Best Fit Linearity
VIDEO PERFORMANCE
Differential Gain
DG
Differential Phase
DP
Hue Accuracy
Modulated Ramp (Note 43)
75% Color Bars (Note 43)
Color Saturation Accuracy
Luminance Nonlinearity
SNR
GENLOCK PERFORMANCE
Horizontal Locking Time
Long-Term horizontal Sync
Lock Range
Range over specified pixel jitter
is maintained. Assumes line
time changes by amount indicated slowly between over one
field. (Note 43)
Number of Missing Horizontal
Syncs Before Lost Lock Declared
HSYNC LOST
Number of Missing Vertical Syncs
Before Lost Lock Declared
VSYNC LOST
Programmable via register 04H
(Note 43)
-
Long-Term Color Subcarrier
Lock Range
Range over color subcarrier
locking time and accuracy specifications are maintained. Subcarrier frequency changes by
amount indicated slowly over 24
hours. (Note 43)
-
±200
±400
Hz
Vertical Sample Alignment
(Notes 43, 45)
-
1/8
-
Pixel
-
10
-
ns
NOTES:
43. Guaranteed by design or characterization.
44. Test performed with CL = 40pF, IOL = 4mA, IOH = -4mA. Input reference level is 1.5V for all inputs. VIH = 3.0V, VIL = 0V.
45. This should not be confused with Clock Jitter, since the HMP8115 does not generate the sample clock. Thus, clock jitter is solely dependent on the source of the CLK2 signal. The Vertical Sample Alignment parameter specifies how accurately samples align vertically from
one scan line to the next.
42
HMP8115
Metric Plastic Quad Flatpack Packages (MQFP/PQFP)
Q80.14x20 (JEDEC MO-108CB-1 ISSUE A)
D
80 LEAD METRIC PLASTIC QUAD FLATPACK PACKAGE
D1
-D-
-B-
-AE E1
e
PIN 1
SEATING
A PLANE
-H-
0.10
0.004
0.40
0.016 MIN
-C-
5o-16o
0.20
A-B S
0.008 M C
0o MIN
A2 A1
0o-7o
L
5o-16o
INCHES
MILLIMETERS
SYMBOL
MIN
MAX
MIN
MAX
NOTES
A
-
0.134
-
3.40
-
A1
0.010
-
0.25
-
-
A2
0.100
0.120
2.55
3.05
-
B
0.012
0.018
0.30
0.45
6
B1
0.012
0.016
0.30
0.40
-
D
0.904
0.923
22.95
23.45
3
D1
0.783
0.791
19.90
20.10
4, 5
E
0.667
0.687
16.95
17.45
3
E1
0.547
0.555
13.90
14.10
4, 5
L
0.026
0.037
0.65
0.95
N
80
80
7
e
0.032 BSC
0.80 BSC
-
ND
24
24
-
NE
16
16
Rev. 0 1/94
NOTES:
D S
1. Controlling dimension: MILLIMETER. Converted inch
dimensions are not necessarily exact.
B
2. All dimensions and tolerances per ANSI Y14.5M-1982.
B1
3. Dimensions D and E to be determined at seating plane -C- .
4. Dimensions D1 and E1 to be determined at datum plane
-H- .
0.13/0.17
0.005/0.007
5. Dimensions D1 and E1 do not include mold protrusion.
Allowable protrusion is 0.25mm (0.010 inch) per side.
BASE METAL
WITH PLATING
6. Dimension B does not include dambar protrusion. Allowable
dambar protrusion shall be 0.08mm (0.003 inch) total.
0.13/0.23
0.005/0.009
7. “N” is the number of terminal positions.
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