Philips F21RE Service Manual page 94

EN 94 9. F21RE AB
The OTC also has a connection with the Front panel:
• Driving the "on" and "STANDBY" LEDs.
Service tip: The green LED gives a quick indication that
the 8V6 voltage is present.
• This chassis has an IR send-LED connected to pin 90 for
communication with DST or ComPair.
• The remote control signal comes in on pin 100.
Memory
The set software is in a 4 MB ROM (IC7002) and in a 32 KB
ROM inside the OTC. The level at pin 73 of the OTC
determines whether this internal software is used at start up.
This level is determined with R3026/3029. The external ROM
is driven via the OE and CS signals.
The Non Volatile Memory (NVM) IC7008 is a 32 KB version
M24C32W6, and is used to store
• Software identification.
• Operational hours.
• Error codes.
• Option codes.
• Presets.
• Alignments.
All ICs in this part are supplied with 3V3. For this, a 3V3
stabilizer is used (IC7009).
Monitor communication (UART/FSP)
In total, four versions of the Receiver box are realised. There is
an US and EU version (main difference is the HD part for US).
Furthermore, there will be version for the current 42" FTV1.9
monitor and a version for the new FM2x monitor range. The
difference between these versions is mainly the
communication between the Receiver box and monitor. See
table below:
Table 9-3 Overview UART diversity
Conn. 0303 F21R with FTV1.9 F21R with FM2x
Pin 4 Not used
Pin 11 CONFIG_IDENT
Pin 12 TXDO
Pin 15 RXDO
The Receiver box has to support both the FTV1.9 and the
FM2x plasma monitors. The communication protocol for the
FTV1.9 monitor is based on UART with a CONFIG_IDENT
signal. However, all FM2x monitors have a new improved
protocol called FSP (FTV System Protocol). Therefore, the pin
layout on the FTV monitor output connector has been changed.
1519
0303
10
9
4
FTV2.3
12
11
11
TO/FROM
FTV2.3
MONITOR
2 1
12
FTV1.9
4 3
15
FTV1.9
FTV1.9 FTV2.3
1 3 5 7 9 11
1519
2 4 6 8 10 12
Figure 9-9 Block Diagram UART Circuitry
Circuit Descriptions, List of Abbreviations, and IC Data Sheets
RXDO
TXDO
Not used
Not used
+5VSTB
3596
0355
7460
TXDO
TO µP
(SSP)
RXDO
3595 3577
+5VSTB
+5VSTB
7571
6571 3570 3576
8 7
one
shot
FTV2.3
7545
CONFIG_IDENT
6 5
FTV1.9
CL16532098_008.eps
180901
As the FM2x has no CONFIG_IDENT signal to "wake up" the
Receiver box, a "dummy" CONFIG_IDENT is derived from the
RXDO signal with the aid of a "one-shot generator" (item 7545).
In order to prevent the RXD-line from connecting to ground, a
protection circuit is added. This circuit puts the RXD-buffer into
tri-state if the input is connected to ground for more than 100
ms.
Because the diversity is realized with jumpers (connector
1519), there are no differences in panel stuffing for both
versions.
Teletext/On Screen Display (TXT/OSD)
The TXT/OSD-decoder in the OTC gets its video signal directly
on pin 5. The RGB-outputs are available on pins 77/78/79. Fast
blanking is realized by pin 80. The RAM (IC7001) of the
microprocessor is also used for the decoder.
Remote Control
The remote control uses RC6, because commands like "cursor
control in eight directions" are used.
For this chassis, there are three possible RC input sources:
• RC_MON (coming from monitor),
• RC_BOX (coming from box), and
• RC_EXT (coming from an external source; this is not
used).
The selection is performed as shown in the figure below:
0313-C RC_EXT
0308-6 RC_FRONT
0303-9 RC_MON
7749
7880
RC_EXT_PRESENT
7881
Figure 9-10 Block Diagram RC Selection Circuitry
When CONFIG_IDENT (for FTV1.9) or AYT (for FM2x) is
detected, the RC_MON is selected.
If there is no monitor connected, the RC_FRONT_SELECT
signal is always "low", so RC _MON cannot be selected (via
TS7749 and TS7751). After start up, when the I/O-expander is
not yet set via I2C, the RC_FRONT signal is connected to
RC_OUT.
7740
0
2
15
0
5
3
1
1
7884
7751
I2C
I/O expander
RC_EXT_PRESENT_N
CL16532098_007.eps
RC_OUT
to SSP
180901