Philips TDA9141-N2, TDA9141-N1 Datasheet

DATA SH EET
Product specification File under Integrated Circuits, IC02
December 1992
INTEGRATED CIRCUITS
TDA9141
PAL/NTSC/SECAM decoder/sync processor
December 1992 2
Philips Semiconductors Product specification
PAL/NTSC/SECAM decoder/sync processor TDA9141
FEATURES
Multistandard PAL, NTSC and SECAM
I2C-bus controlled
I2C-bus addresses can be selected by hardware
Alignment free
Few external components
Designed for use with baseband delay lines
Integrated video filters
CVBS or YC input with automatic detection
CVBS output
Vertical divider system
Two-level sandcastle signal
VA synchronization pulse (3-state)
HA synchronization pulse or clamping pulse CLP
input/output
Line-locked clock output or stand-alone I2C-bus output port
Stand-alone I2C-bus input/output port
Colour matrix and fast YUV switch
Comb filter enable input/output with subcarrier
frequency.
GENERAL DESCRIPTION
The TDA9141 is an I2C-bus controlled, alignment-free PAL/NTSC/SECAM decoder/sync processor. The TDA9141 has been designed for use with baseband chrominance delay lines, and has a combined subcarrier frequency/comb filter enable signal for communication with a PAL comb filter. The IC can process CVBS signals and Y/C input signals. The input signal is available on an output pin, in the event of a Y/C signal, it is added into a CVBS signal. The sync processor provides a two-level sandcastle, a horizontal pulse (CLP or HA pulse, bus selectable) and a vertical (VA) pulse. When the HA pulse is selected a line-locked clock (LLC) signal is available at the output port pin.
A fast switch can select either the internal Y signal with the UV input signals, or YUV signals made of the RGB input signals. The RGB input signals can be clamped with either the internal or an external clamping signal (search tuning mode). Two pins with an input/output port and an output port of the I2C-bus are available. The I2C-bus address of the TDA9141 is hardware programmable.
ORDERING INFORMATION
Note
1. SOT232-1; 1996 December 4.
EXTENDED TYPE
NUMBER
PACKAGE
PINS PIN POSITION MATERIAL CODE
TDA9141 32 SDIL plastic SOT232
(1)
December 1992 3
Philips Semiconductors Product specification
PAL/NTSC/SECAM decoder/sync processor
TDA9141
Fig.1 Block diagram.
December 1992 4
Philips Semiconductors Product specification
PAL/NTSC/SECAM decoder/sync processor TDA9141
QUICK REFERENCE DATA
SYMBOL PARAMETER CONDITIONS MIN. TYP. MAX. UNIT
V
CC
positive supply voltage 7.2 8.0 8.8 V
I
CC
supply current 45 mA
V
26(p-p)
CVBS input voltage (peak-to-peak value) top sync - white 1.0 V
V
26(p-p)
luminance input voltage (peak-to-peak value) top sync - white 1.0 V
V
22(p-p)
chrominance burst input voltage (peak-to-peak value)
0.3 V
V
12
luminance black-white output voltage 1.0 V
V
14(p-p)
U output voltage (peak-to-peak value) standard colour bar 1.33 V
V
13(p-p)
V output voltage (peak-to-peak value) standard colour bar 1.05 V
V
10
sandcastle blanking voltage level 2.5 V
V
10
sandcastle clamping voltage level 4.5 V
V
11
VA output voltage 5.0 V
V
17
HA output voltage 5.0 V
V
16(p-p)
LLC output voltage amplitude (peak-to-peak value) 500 mV
V
21,20 19(p-p)
RGB input voltage (peak-to-peak value) 0 to 100%
saturation
0.7 V
V
clamp I/O
clamping pulse input/output voltage 5.0 V
V
sub
subcarrier output voltage amplitude (peak-to-peak value)
200 mV
V
15,16
O port output voltage 5.0 V
December 1992 5
Philips Semiconductors Product specification
PAL/NTSC/SECAM decoder/sync processor TDA9141
Fig.2 Pin configuration.
PINNING
SYMBOL PIN DESCRIPTION
(RY) 1 chrominance output
(BY) 2 chrominance output
U
in
3 chrominance U input
V
in
4 chrominance voltage input SCL 5 serial clock input SDA 6 serial data input/output V
CC
7 positive supply input DEC 8 digital supply decoupling DGND 9 digital ground SC 10 sandcastle output V
A
11 vertical acquisition
synchronization pulse
Y
out
12 luminance output V
out
13 chrominance V output U
out
14 chrominance U output I/O PORT 15 input/output port O PORT/LLC 16 output port/line-locked clock
output
CLP/HA 17 clamping pulse/H
A
synchronization pulse
input/output F 18 fast switch select input B 19 BLUE input G 20 GREEN input R 21 RED input ADDR
(CVBS)
22 I
2
C-bus address input (CVBS
output) Fscomb 23 comb filter status input/output HPLL 24 horizontal PLL filter C 25 chrominance input Y/CVBS 26 luminance/CVBS input AGND 27 analog ground FILT
ref
28 filter reference decoupling CPLL 29 colour PLL filter XTAL 30 reference crystal input XTAL2 31 second crystal input SEC
ref
32 SECAM reference decoupling
December 1992 6
Philips Semiconductors Product specification
PAL/NTSC/SECAM decoder/sync processor
TDA9141
FUNCTIONAL DESCRIPTION General
The TDA9141 is an I
2
C-bus controlled, alignment-free PAL/NTSC/SECAM colour decoder/sync processor which has been designed for use with baseband chrominance delay lines. In the standard operating mode the I2C-bus address is 8A. If the address input is connected to the positive rail the address will change to 8E.
Input switch
WARNING: T
HE VOLTAGE ON THE CHROMINANCE PIN MUST NEVER EXCEED
5.5 V. IF IT DOES THE IC
ENTERS A TEST MODE.
The TDA9141 has a two pin input for CVBS or YC signals which can be selected via the I2C-bus. The input selector also has a position in which it automatically detects whether a CVBS or YC signal is on the input. In this input selector position, standard identification first takes place on an added Y/CVBS and C input signal. After that, both chrominance signal input amplitudes are checked once and the input with the strongest chrominance burst signal is selected. The input switch status is read out by the I2C-bus via output bit YC.
CVBS output
In the standard operating mode with the I
2
C-bus address 8A, a CVBS output signal is available on the address pin, which represents either the CVBS input signal or the Y/C input signal, added into a CVBS signal
RGB colour matrix
WARNING: THE VOLTAGE ON THE UIN
PIN MUST NEVER EXCEED
5.5 V. IFIT
DOES THE
IC ENTERS A TEST MODE.
The TDA9141 has a colour matrix to convert RGB input signals into YUV signals. A fast switch, controlled by
the signal on pin F and enabled by the I
2
C-bus via EFS (enable fast switch), can select between these YUV signals and the YUV signals of the decoder. The Y signal is internally connected to the switch. The (RY) and (BY) output signals of the decoder have to first be delayed in external baseband chrominance delay lines. The outputs of the delay lines must be connected to the UV input pins. If the RGB signals are not synchronous with the selected decoder input signal, clamping of the RGB input signals is possible by I
2
C-bus selection of STM (search tuning mode), EFS and by feeding an external clamping signal to the CLP pin. Also in search tuning mode the VA output will be in a high impedance OFF-state.
Standard identification
The standards which the TDA9141 can decode are dependent on the choice of external crystals. If a
4.4 MHz and a 3.6 MHz crystal are used then SECAM, PAL 4.4/3.6 and NTSC 4.4/3.6 can be decoded. If two
3.6 MHz crystals are used then only PAL 3.6 and NTSC 3.6 can be decoded. Which 3.6 MHz standards can be decoded is dependent on the exact frequencies of the 3.6 MHz crystals. In an application where not all standards are required only one crystal is sufficient (in this instance the crystal must be connected to the reference crystal input (pin 30)). If a
4.4 MHz crystal is used it must always be connected to pin 30. Both crystals are used to provide a reference for the filters and the horizontal PLL, however, only the reference crystal is used to provide a reference for the SECAM demodulator. To enable the calibrating circuits to be adjusted exactly two bits from I
2
C-bus subaddress 00 are used to indicate which crystals are connected to the IC.
The standard identification circuit is a digital circuit without external components; the search loop is illustrated in Fig.3.
The decoder (via the I
2
C-bus) can be forced to decode either SECAM or PAL/NTSC (but not PAL or NTSC). Crystal selection can also be forced. Information concerning which standard and which crystal have been selected and whether the colour killer is ON or OFF is provided by the read out. Using the forced-mode does not affect the search loop, it does, however, prevent the decoder from reaching or staying in an unwanted state. The identification circuit skips impossible standards (e.g. SECAM when no 4.4 MHz crystal is fitted) and illegal standards (e.g. is forced mode). To reduce the risk of wrong identification PAL has priority over SECAM (only line identification is used for SECAM).
Integrated filters
All filters, including the luminance delay line, are an integral part of the IC. The filters are gyrator-capacitor type filters. The resonant frequency of the filters is controlled by a circuit that uses the active crystal to tune the SECAM Cloche filter during the vertical flyback time. The remaining filters and the luminance delay line are matched to this filter. The filters can be switched to either 4.43 MHz,
4.28 MHz or 3.58 MHz irrespective of the frequency of the active crystal. The switching is controlled by the identification circuit. In YC mode the chrominance notch filter is bypassed, to preserve full signal bandwidth. For a CVBS signal the chrominance notch filter can be bypassed by I
2
C-bus selection of TB (trap bypass). The luminance delay line delivers the Y signal to the output 60 ns after the
(RY) and (BY) signals have arrived at their outputs.
December 1992 7
Philips Semiconductors Product specification
PAL/NTSC/SECAM decoder/sync processor
TDA9141
This compensates for the delay of the external chrominance delay lines.
Colour decoder
The PAL/NTSC demodulator employs an oscillator that can operate with either crystal (3.6 or 4.4 MHz). If the I
2
C-bus indicates that only one crystal is connected it will always connect to the crystal on the reference crystal input (pin 30).
The Hue signal, which is adjustable via the I2C-bus, is gated during the burst for NTSC signals.
The SECAM demodulator is an auto-calibrating PLL demodulator which has two references. The reference crystal, to force the PLL to the desired free-running frequency and the bandgap reference, to obtain the correct absolute value of the output signal. The VCO of the PLL is calibrated during each vertical blanking period, when the IC is in search mode or SECAM mode. If the reference crystal is not 4.4 MHz the decoder will not produce the correct SECAM signals.
The frequency of the active crystal is fed to the Fscomb output, which can be connected to an external comb filter IC. The DC value on this pin contains the comb enable information. Comb enable is true when bus bit ECMB is HIGH. If ECMB is LOW, the subcarrier frequency is suppressed. The external comb filter can force the DC value of Fscomb LOW, as pin Fscomb also acts as input pin. In this event the subcarrier frequency is still present. If the DC value of Fscomb is HIGH, the input switch is always forced in Y/C mode, indicated by bus bit YC.
Sync processor (ϕ1 loop)
The main part of the sync circuit is a 432 × fH (6.75 MHz) oscillator the frequency of which is divided by 432 to lock the Phase 1 loop to the incoming signal. The time constant of the loop can be forced by the I2C-bus (fast or slow). If required the IC can select the time constant, depending on the noise content of the input signal and whether the loop is phase-locked or not (medium or slow). The free-running frequency of the oscillator is determined by a digital control circuit that is locked to the active crystal.
When a power-on-reset pulse is detected the frequency of the oscillator is switched to a frequency greater than 6.75 MHz to protect the horizontal output transistor. The oscillator frequency is reset to
6.75 MHz when the crystal indication bits have been loaded into the IC. To ensure that this procedure does not fail it is absolutely necessary to send subaddress 00 before subaddress
01. Subaddress 00 contains the crystal indication bits and when subaddress 01 is received the line oscillator calibration will be initiated (for the start-up procedure after power-on reset detection see the I2C-bus protocol. The calibration is terminated when the oscillator frequency reaches 6.75 MHz. The oscillator is again calibrated when an out-of-lock condition with the input signal is detected by the coincidence detector. Again the calibration will be terminated when the oscillator frequency reaches 6.75 MHz. The Phase 1 loop can be opened using the I2C-bus. This is to facilitate On Screen Display (OSD) information. If there is no input signal or a very noisy input signal the phase 1 loop can be opened to provide a stable line frequency and thus a stable picture.
The sync part also delivers a two-level sandcastle signal, which provides a combined horizontal and vertical blanking signal and a clamping pulse for the display section of the TV.
Vertical divider system
The vertical divider system has a fully integrated vertical sync separator. The divider can accommodate both 50 and 60 Hz systems; it can either locate the field frequency automatically or it can be forced to the desired system via the I2C-bus. A block diagram of the vertical divider system is illustrated in Fig.4. The divider system operates at twice the horizontal line frequency. The line counter receives enable pulses at this line frequency, thereby counting two pulses per line. A state diagram of the controller is illustrated in Fig.5. Because it is symmetrical only the right hand part will be described.
Depending on the previously found field frequency, the controller will be in one of the COUNT states. When the line counter has counted 488 pulses (i.e. 244 lines of the video input signal) the controller will move to the next state depending on the output of the norm counter. This can be either NORM, NEAR_NORM or NO_NORM depending on the position of the vertical sync pulse in the previous fields. When the controller is in the NORM state it generates the vertical sync pulse (VSP) automatically and then, when the line counter is at LC = 626, moves to the WAIT state. In this condition it waits for the next pulse of the double line frequency signal and then moves to the COUNT state of the current field frequency. When the controller returns to the COUNT state the line counter will be reset half a line after the start of the vertical sync pulse of the video input signal.
December 1992 8
Philips Semiconductors Product specification
PAL/NTSC/SECAM decoder/sync processor
TDA9141
When the controller is in the NEAR_NORM state it will move to the COUNT state if it detects the vertical sync pulse within the NEAR_NORM window (i.e. 622 < LC < 628). If no vertical sync pulse is detected, the controller will move back to the COUNT state when the line counter reaches LC = 628. The line counter will then be reset. When the controller is in the NO_NORM state it will move to the COUNT state when it detects a vertical sync pulse and reset the line counter. If a vertical sync pulse is not detected before LC = 722 (if the Phase 1 loop is locked in forced mode) it will move to the COUNT state and reset the line counter. If the Phase 1 loop is not locked the controller will move back to the COUNT state when LC = 628. The forced mode option keeps the
controller in either the left-hand side (60 Hz) or the right-hand side (50 Hz) of the state diagram.
Figure 6 illustrates the state diagram of the norm counter which is an up/down counter that counts up if it finds a vertical sync pulse within the selected window. In the NEAR_NORM and NORM states the first correct vertical sync pulse after one or more incorrect vertical sync pulses is processed as an incorrect pulse. This procedure prevents the system from staying in the NEAR_NORM or NORM state if the vertical sync pulse is correct in the first field and incorrect in the second field. If no vertical sync pulse is found in the selected window this will always result in a down pulse for the norm counter.
Output port and input/output port
Two stand-alone ports are available for external use. These ports are I
2
C-bus controlled, the output port by bus bit OPB and the input/output port by bus bit OPA. Bus bit OPA is an open-drain output, to enable input port functioning. The pin status is read out by bus via output bit IP.
Sandcastle
Figure 7 illustrates the timing of the acquisition sandcastle (ASC) and the V
A
pulse with respect to the input signal. The sandcastle signal is in accordance with the 2-level 5 V sandcastle format. An external vertical guard current can overrule the sink current to enable blanking purposes.
Loading...
+ 17 hidden pages