PHILIPS SAA5290PS

INTEGRATED CIRCUITS
DATA SHEET
SAA5290
One page Economy Teletext/TV
microcontroller
Preliminary specification
File under Integrated Circuits, IC02
Philips Semiconductors
February 1995
Philips Semiconductors
Preliminary specification
One page Economy Teletext/TV
microcontroller
SAA5290
FEATURES
General
• Complete one page teletext decoder and TV
microcontroller in a single 52-pin package
• Eastern European, Western European and Turkish
language variants covered in one device
DESCRIPTION
• Double size, double width and double height character
capability for On-Screen Display (OSD)
The SAA5290 is a single-chip one page teletext decoder
and television control microcontroller. The device will
decode 625-line based World System Teletext
transmissions and provides television control functions
and On-Screen Display (OSD) functions.
• Enhanced display features including meshing and
shadowing
• Separate display and acquisition timing for increased
flexibility
The teletext decoder hardware is a derivative of the
SAA5254 (IVT1.1X), and the TV control functionality
provided by an on-chip industrial standard 80C51
microcontroller. A single-page static RAM is included
on-board providing a complete one page teletext decoder
and OSD memory.
• Minimum peripheral component count
• 525 line and 625 line display synchronization
• Standby mode through power-down of teletext and
analog hardware.
Microcontroller
The SAA5290 is available as a mask-programmed ROM
version. An EEPROM version is also available for product
development. Both versions are available in an SDIP52
package.
• 16 kbytes masked ROM (16 kbytes EEPROM variant for
product development)
• 256 bytes of on-chip RAM
• Six 6-bit Pulse Width Modulators (PWM) and one 14-bit
precision PWM
• 4-bit Digital-to-Analog Converter (DAC) and comparator
with a 3-input multiplexer allowing implementation of 3
Analog-to-Digital Converters (ADC) in software
• 2 high current (10 mA) open-drain outputs
• Interrupt logic 0 triggered on rising and falling edges,
providing pulse-width measurement for remote control
decoding
• Master and slave bit-level I2C-bus hardware.
ORDERING INFORMATION
PACKAGE
TYPE NUMBER
SAA5290ZP/nnn(1)
SAA5290ZP/NVI(2)
MEMORY
NAME
DESCRIPTION
VERSION
ROM
SDIP52
plastic shrink dual in-line package; 52 leads (600 mil)
SOT247-1
EEPROM
SDIP52
plastic shrink dual in-line package; 52 leads (600 mil)
SOT247-1
Notes
1. nnn is a three-digit number referencing the microcontroller program ROM mask.
2. I is a digit number referring to the language variant of the SAA5290ZP/NV.
February 1995
2
Philips Semiconductors
Preliminary specification
One page Economy Teletext/TV
microcontroller
SAA5290
QUICK REFERENCE DATA
SYMBOL
PARAMETER
MIN.
TYP.
MAX.
UNIT
VDD
supply voltage
4.5
5.0
5.5
V
IDDM
microcontroller supply current
−
25
40
mA
IDDA
analog supply current
−
35
50
mA
IDDT
teletext supply current
−
20
30
mA
fxtal
crystal frequency
−
12
−
MHz
Tamb
operating ambient temperature
−20
−
+70
°C
BLOCK DIAGRAM
BLACK
handbook, full pagewidth
25
IREF
VDDA
V DDT
38
39
26
VDDM
44
37
CVBS0
CVBS1
2
23, 24
TELETEXT
ACQUISITION
DATA SLICER
36
DISPLAY
TIMING
27
3
PAGE
RAM
ACQUISITION
TIMING
34, 33, 32
35
DISPLAY
29
VSYNC
HSYNC
FRAME
R, G, B
VDS
COR
SAA5290
OSCIN
OSCOUT
OSCGND
41
31
42
RGBREF
OSCILLATOR
40
16K x 8
ROM
256 x 8
RAM
TEXT
INTERFACE
ANALOG-TODIGITAL
CONVERTER
PULSE
WIDTH
MODULATOR
data
RESET
80C51
MICROCONTROLLER
43
address
PORT 3
13
28
22
VSSD1
VSSD2
VSSA
PORT 2
5
9 to 12, 30
P3.0 to P3.4/
ADC0 to ADC2
8
1 to 8
P2.0 to P2.7
PWM
Fig.1 Block diagram.
February 1995
3
TIMER/
CTRS/ I 2 C
PORT 1
8
45 to 52
P1.0 to P1.7 / INT0,
INT1, T0, T1, SDA, SCL
PORT 0
8
14 to 21
P0.0 to P0.7
MLC102
Philips Semiconductors
Preliminary specification
One page Economy Teletext/TV
microcontroller
SAA5290
PINNING
SYMBOL
PIN
DESCRIPTION
P2.0/TPWM
1
P2.1/PWM0
2
P2.2/PWM1
3
PORT 2: 8-bit open-drain bidirectional port with alternative functions. P2.0/TPWM is the
output for the 14-bit high precision PWM. P2.1/PWM0 to P2.6/PWM5 are the outputs for
the 6-bit PWMs 0 to 5.
P2.3/PWM2
4
P2.4/PWM3
5
P2.5/PWM4
6
P2.6/PWM5
7
P2.7
8
P3.0/ADC0
9
P3.1/ADC1
10
P3.2/ADC2
11
P3.3
12
P3.4
30
PORT 3: 5-bit open-drain bidirectional port with alternative functions. P3.0/ADC0 to
P3.2/ADC2 are the inputs for the software ADC facility.
VSSD1
13
digital ground 1 for teletext and microcontroller circuits.
P0.0
14
P0.1
15
PORT 0: 8-bit open-drain bidirectional port. P0.5 and P0.6 have 10 mA current sinking
capability at 0.5 V for direct drive of LEDs.
P0.2
16
P0.3
17
P0.4
18
P0.5
19
P0.6
20
P0.7
21
VSSA
22
analog ground.
CVBS0
23
CVBS1
24
Composite video input. A positive-going 1 V (peak-to-peak) input is required, connected
via a 100 nF capacitor.
BLACK
25
Video black level storage input. This pin should be connected to VSSA via a 100 nF
capacitor.
IREF
26
Reference current input for analog circuits, connected to VSSA via a 27 kΩ resistor.
FRAME
27
De-interlace output synchronized with the VSYNC pulse to produce a non-interlaced
display by adjustment of the vertical deflection currents.
VSSD2
28
Digital ground 2.
COR
29
Open-drain, active LOW output which allows selective contrast reduction of the TV
picture to enhance a mixed mode display.
RGBREF
31
DC input voltage to define the output HIGH level on the RGB pins.
B
32
Dot rate character output of the BLUE colour information.
G
33
Dot rate character output of the GREEN colour information.
R
34
Dot rate character output of the RED colour information.
VDS
35
Video/data switch push-pull output for dot rate fast blanking.
HSYNC
36
Horizontal sync dedicated input for a TTL-level version of the horizontal sync pulse. The
polarity of this pulse is programmable by register bit TXT1.H POLARITY.
February 1995
4
Philips Semiconductors
Preliminary specification
One page Economy Teletext/TV
microcontroller
SYMBOL
SAA5290
PIN
DESCRIPTION
VSYNC
37
Vertical sync dedicated input for a TTL-level version of the vertical sync pulse. The
polarity of this pulse is programmable by register bit TXT1.V POLARITY.
VDDA
38
+5 V analog power supply.
VDDT
39
+5 V teletext power supply.
OSCGND
40
Crystal oscillator ground.
OSCIN
41
12 MHz crystal oscillator input.
OSCOUT
42
12 MHz crystal oscillator output.
RESET
43
If the reset input is HIGH for 2 machine cycles (24 oscillator periods) while the oscillator
is running, the SAA5290 is reset. This pin should be connected to VDDM via a 2.2 µF
capacitor.
VDDM
44
+5 V microcontroller power supply.
P1.0/INT1
45
P1.1/T0
46
P1.2/INT0
47
P1.3/T1
48
PORT 1: 8-bit open-drain bidirectional port with alternative functions. P1.0/INT1 is
external interrupt 1 which can be triggered on the rising and falling edge of the pulse.
P1.1/T0 is the counter/timer 0. P1.2/INT0 is external interrupt 0. P1.3/T1 is the
counter/timer 1. P1.6/SCL is the serial clock input for I2C-bus. P1.7/SDA is the serial
data port for the I2C-bus.
P1.6/SCL
49
P1.7/SDA
50
P1.4
51
P1.5
52
February 1995
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Philips Semiconductors
Preliminary specification
One page Economy Teletext/TV
microcontroller
SAA5290
handbook, halfpage
P2.0/TPWM
1
52
P2.1/PWM0
2
51 P1.4
P2.2/PWM1
3
50
P1.7/SDA
P2.3/PWM2
4
49
P1.6/SCL
P2.4/PWM3
5
48
P1.3/T1
P2.5/PWM4
6
47
P1.2/INT0
P2.6/PWM5
7
46
P1.1/T0
P2.7
8
45
P1.0/INT1
P3.0/ADC0
9
44
VDDM
P3.1/ADC1
10
43
RESET
P3.2/ADC2
11
42
OSCOUT
P3.3
12
41 OSCIN
VSSD1
13
P1.5
40 OSCGND
SAA5290
P0.0
14
39 VDDT
P0.1
15
38 VDDA
P0.2 16
37 VSYNC
P0.3 17
36 HSYNC
P0.4 18
35 VDS
P0.5
19
34 R
P0.6
20
33 G
P0.7
21
32 B
VSSA
22
31 RGBREF
CVBS0
23
30 P3.4
CVBS1
24
29 COR
BLACK
25
28 VSSD2
IREF
26
27 FRAME
MLC103
Fig.2 Pin configuration.
February 1995
6
Philips Semiconductors
Preliminary specification
One page Economy Teletext/TV
microcontroller
SAA5290
QUALITY AND RELIABILITY
This device will meet Philips Semiconductors General Quality Specification for Business group “Consumer Integrated
Circuits SNW-FQ-611-Part E” (see “Quality Reference Handbook”, order number 9398 510 63011). The principal
requirements are shown in Tables 1 to 4.
Group A
Table 1 Acceptance tests per lot
REQUIREMENTS(1)
TEST
Mechanical
cumulative target: <80 ppm
Electrical
cumulative target: <80 ppm
Group B
Table 2 Processability tests (by package family)
REQUIREMENTS(1)
TEST
Solderability
<7% LTPD
Mechanical
<15% LTPD
Solder heat resistance
<15% LTPD
Group C
Table 3 Reliability tests (by process family)
TEST
CONDITIONS
REQUIREMENTS(1)
Operational life
168 hours at Tj = 150 °C
<1500 FPM; equivalent to
<100 FITS at Tj = 70 °C
Humidity life
temperature, humidity, bias
1000 hours, 85 °C, 85% RH
(or equivalent test)
<2000 FPM
Temperature cycling performance
Tstg(min) to Tstg(max)
<2000 FPM
Table 4 Reliability tests (by device type)
TEST
ESD and latch-up
CONDITIONS
ESD Human body model
2000 V, 100 pF, 1.5 kΩ
<15% LTPD
ESD Machine model
200 V, 200 pF, 0 Ω
<15% LTPD
latch-up 100 mA, 1.5 × VDD
(absolute maximum)
<15% LTPD
Notes to Tables 1 to 4
1. ppm = fraction of defective devices, in parts per million.
LTPD = Lot Tolerance Percent Defective.
FPM = fraction of devices failing at test condition, in Failures Per Million.
FITS = Failures In Time Standard.
February 1995
REQUIREMENTS(1)
7
Philips Semiconductors
Preliminary specification
One page Economy Teletext/TV
microcontroller
SAA5290
LIMITING VALUES
In accordance with Absolute Maximum Rating System (IEC 134).
SYMBOL
PARAMETER
CONDITIONS
MIN.
MAX.
UNIT
VDD
supply voltage (all supplies)
−0.3
+6.5
VI
input voltage (any input)
note 1
−0.3
VDD + 0.5 V
VO
output voltage (any output)
note 1
−0.3
VDD + 0.5 V
V
IO
output current (each output)
−
±10
mA
IIOK
DC input or output diode current
−
±20
mA
∆VSS
difference between VSSD, VSSA and OSCGND
−
±0.1
V
∆VDD
difference between VDDM, VDDT and VDDA
−
±0.1
V
Tamb
operating ambient temperature
−20
+70
°C
Tstg
storage temperature
−55
+125
°C
note 2
Notes
1. This maximum value has an absolute maximum of 6.5 V independent of VDD.
2. Except in standby mode.
CHARACTERISTICS
VDD = 5 V ± 10%; VSS = 0 V; Tamb = −20 to +70 °C; unless otherwise specified.
SYMBOL
PARAMETER
CONDITIONS
MIN.
TYP.
MAX.
UNIT
Supplies
VDD
supply voltage (VDD to VSS)
4.5
5.0
5.5
V
IDDM
microcontroller supply current
−
25
40
mA
IDDA
analog supply current
−
35
50
mA
IDDT
teletext supply current
−
20
30
mA
Digital inputs
RESET
VIL
LOW level input voltage
−0.3
−
0.2VDD − 0.1 V
VIH
HIGH level input voltage
0.7VDD
−
VDD + 0.3
ILI
input leakage current
CI
input capacitance
VI = 0 to VDD
V
−10
−
+10
µA
−
−
4
pF
HSYNC AND VSYNC
Vthf
switching threshold falling
0.2VDD
−
−
V
Vthr
switching threshold rising
−
−
0.8VDD
V
VHYS
hysteresis voltage
−
0.33VDD
−
V
CI
input capacitance
−
−
4
pF
February 1995
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Philips Semiconductors
Preliminary specification
One page Economy Teletext/TV
microcontroller
SYMBOL
PARAMETER
SAA5290
CONDITIONS
MIN.
TYP.
MAX.
UNIT
Digital outputs
R, G AND B (note 1)
VOL
LOW level output voltage
IOL = 2 mA
0
−
0.2
V
VOH
HIGH level output voltage
IOH = −2 mA
VRGBREF
− 0.3
VRGBREF
VRGBREF
+ 0.4
V
|ZO|
output impedance
−
−
150
Ω
CL
load capacitance
−
−
50
pF
IO
DC output current
−
−
−4
mA
tr
output rise time
between 10% and 90%; −
CL = 50 pF
−
20
ns
tf
output fall time
between 90% and 10%; −
CL = 50 pF
−
20
ns
−
−
VDD
V
0
−
0.5
V
COR (OPEN-DRAIN OUTPUT)
VOH
HIGH level pull-up output
voltage
VOL
LOW level output voltage
IOL
LOW level output current
−
−
2
mA
CL
load capacitance
−
−
25
pF
IOL = 2 mA
VDS
VOL
LOW level output voltage
IOL = 1.6 mA
0
−
0.2
V
VOH
HIGH level output voltage
IOH = −1.6 mA
VDD − 0.3
−
VDD + 0.4
V
CL
load capacitance
−
−
50
pF
tr
output rise time
between 10% and 90%; −
CL = 50 pF
−
20
ns
tf
output fall time
between 90% and 10%; −
CL = 50 pF
−
20
ns
−
−
20
ns
R, G, B AND VDS
tskew
skew delay between any two
pins
FRAME
VOH
HIGH level output voltage
IOL = 8 mA
0
−
0.5
V
VOL
LOW level output voltage
IOL = −8 mA
VDD − 0.5
−
VDD
V
IOL
LOW level output current
−8
−
+8
mA
CL
load capacitance
−
−
100
pF
February 1995
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Philips Semiconductors
Preliminary specification
One page Economy Teletext/TV
microcontroller
SYMBOL
PARAMETER
SAA5290
CONDITIONS
MIN.
TYP.
MAX.
UNIT
Digital input/outputs
P0.0 TO P0.4, P0.7, P1.0 TO P1.5, P2.0 TO P2.7 AND P3.0 TO P3.5
VIL
LOW level input voltage
−0.3
VIH
HIGH level input voltage
0.2VDD + 0.9 −
CI
input capacitance
VOL
LOW level output voltage
CL
load capacitance
IOL = 3.2 mA
−
0.2VDD − 0.1 V
VDD + 0.3
V
−
−
4
pF
0
−
0.45
V
−
−
50
pF
−
0.2VDD − 0.1 V
P0.5 AND P0.6
VIL
LOW level input voltage
−0.3
VIH
HIGH level input voltage
0.2VDD + 0.9 −
VDD + 0.3
V
CI
input capacitance
−
−
4
pF
VOL
LOW level output voltage
0
−
0.45
V
CL
load capacitance
−
−
50
pF
IOL = 10 mA
P1.6 AND P1.7
VIL
LOW level input voltage
−0.3
−
+1.5
V
VIH
HIGH level input voltage
3.0
−
VDD + 0.3
V
CI
input capacitance
−
−
5
pF
VOL
LOW level output voltage
0
−
0.5
V
CL
load capacitance
−
−
400
pF
tf
output fall time
−
−
200
ns
IOL = 3 mA
between 3 and 1 V
Analog inputs
CVBS0 AND CVBS1
Vsync
sync voltage amplitude
0.1
0.3
0.6
V
Vvid(p-p)
video input voltage amplitude
(peak-to-peak value)
0.7
1.0
1.4
V
Zsource
source impedance
−
−
250
Ω
VIH
HIGH level input voltage
3.0
−
VDD + 0.3
V
|ZI|
input impedance
2.5
5.0
−
kΩ
CI
input capacitance
−
−
10
pF
resistor to ground
−
27
−
kΩ
IREF
Rgnd
RGBREF (note 1)
VI
input voltage
−0.3
−
VDD
V
II
DC input current
−
−
12
mA
February 1995
10
Philips Semiconductors
Preliminary specification
One page Economy Teletext/TV
microcontroller
SYMBOL
PARAMETER
SAA5290
CONDITIONS
MIN.
TYP.
MAX.
UNIT
ADC0, ADC1 AND ADC2
VIL
LOW level input voltage
−0.3
−
VDD
V
Analog input/output
BLACK
Cblack
storage capacitor to ground
−
100
−
nF
Vblack
black level voltage for nominal
sync amplitude
1.8
2.15
2.5
V
ILI
input leakage current
−10
−
+10
µA
Crystal oscillator
OSCIN
VIL
LOW level input voltage
−0.3
−
0.2VDD − 0.1 V
VIH
HIGH level input voltage
0.7VDD
−
VDD + 0.3
V
CI
input capacitance
−
−
10
pF
fosc
crystal oscillator frequency
−
12
−
MHz
CO
output capacitance
−
−
10
pF
−
12
−
MHz
OSCOUT
CRYSTAL SPECIFICATION (note 2)
fxtal
nominal frequency
CL
load capacitance
−
32
−
pF
C1
series capacitance
Tamb = 25 °C
−
18.5
−
fF
C0
parallel capacitance
Tamb = 25 °C
−
4.9
−
pF
Rr
resonance resistance
Tamb = 25 °C
Ω
Txtal
temperature range
Xj
adjustment tolerance
Xd
drift
Tamb = 25 °C
−
35
−
−20
+25
+70
°C
10−6
−
−
±50 ×
−
−
±30 × 10−6
Notes
1. All RGB current is sourced from the RGBREF pin. The maximum effective series resistance between RGBREF and
the R, G and B pins is 150 Ω.
2. Crystal order number 4322 143 05561.
February 1995
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Philips Semiconductors
Preliminary specification
One page Economy Teletext/TV
microcontroller
SAA5290
Table 5 Characteristics for the I2C-bus interface
SYMBOL
PARAMETER
INPUT
OUTPUT
I2C-BUS SPECIFICATION
SCL timing
tHD;STA
START condition hold time
≥4.0 µs
note 1
≥4.0 µs
tLOW
SCL LOW time
≥4.7 µs
note 1
≥4.7 µs
tHIGH
SCL HIGH time
≥4.0 µs
≥4.0 µs; note 2
≥4.0 µs
trC
SCL rise time
≤1.0 µs
note 3
≤1.0 µs
tfC
SCL fall time
≤0.3 µs
≤0.3 µs; note 4
≤0.3 µs
≥250 ns
note 1
≥250 ns
≥0 ns
note 1
≥0 ns
SDA timing
tSU;DAT1
data set-up time
tHD;DAT
data hold time
tSU;STA
repeated START set-up time
≥4.7 µs
note 1
≥4.7 µs
tSU;STO
STOP condition set-up time
≥4.0 µs
note 1
≥4.0 µs
tBUF
bus free time
≥4.7 µs
note 1
≥4.7 µs
trD
SDA rise time
≤1.0 µs
note 3
≤1.0 µs
tfD
SDA fall time
≤0.3 µs
≤0.3 µs; note 4
≤0.3 µs
Notes
1. This parameter is determined by the user software. It must comply with the I2C-bus specification.
2. This value gives the auto-clock pulse length which meets the I2C-bus specification for the special crystal frequency.
Alternatively, the SCL pulse must be timed by software.
3. The rise time is determined by the external bus line capacitance and pull-up resistor. It must be less than 1 µs.
4. The maximum capacitance on bus lines SDA and SCL is 400 pF.
repeated START condition
START or repeated START condition
START condition
STOP condition
t SU;STA
t rD
0.7V DD
SDA
(input / output)
0.3VDD
t fD
t rC
t BUF
t fC
t SU;STO
0.7VDD
SCL
(input / output)
0.3VDD
t HD;STA
t LOW
t HIGH
t SU;DAT1
t HD;DAT
dth
Fig.3 I2C-bus interface timing.
February 1995
12
t SU;DAT3
t SU;DAT2
MLC104
Philips Semiconductors
Preliminary specification
One page Economy Teletext/TV
microcontroller
SAA5290
FUNCTIONAL DESCRIPTION
OFF-CHIP MEMORY
Introduction
The SAA5290 does not support the use of off-chip
program memory or off-chip data memory. This means
that the SAA5290 does not have any of EA, RD, WR, ALE
or PSEN pins. The 4 MOVX instructions which move data
to and from external RAM should not be used.
The SAA5290 is an integrated teletext decoder and
microcontroller. The teletext decoder is derived from the
SAA5254 single page teletext decoder IC, with a number
of enhancements to increase its suitability for on-screen
display applications. The microcontroller is a derivative of
the industry standard 80C51 microcontroller. A block
diagram of the SAA5290 is given in Fig.1.
IDLE AND POWER-DOWN MODES
Idle and power-down modes are not supported by the
SAA5290. As a consequence, the respective bits in PCON
are not available.
Microcontroller
The functionality of the microcontroller used on the
SAA5290 is described here with reference to the industry
standard 80C51 microcontroller. A full description of its
functionality can be found in the handbook 80C51-based
8-bit microcontrollers IC20. Using the 80C51 as a
reference, the changes made for the SAA5290 fall into two
categories, features not supported by the SAA5290 and
features found on the SAA5290 but not supported by the
80C51.
UART FUNCTION
The 80C51 UART is not available in the SAA5290. As a
consequence the SCON and SBUF SFRs are removed
and the ES bit in the IE SFR is unavailable.
Additional features for the SAA5290
The following features are provided by the SAA5290 in
addition to the standard 80C51 features.
80C51 features not supported by the SAA5290
INTERRUPTS
INTERRUPT PRIORITY
The IP SFR is not implemented and all interrupts are
treated with the same priority level. The SAA5290 retains
the normal prioritization of interrupts within a level.
The external INT1 interrupt is modified to generate an
interrupt on both the rising and falling edges of the INT1
pin, when EX1 bit is set. This facility allows for software
pulse width measurement for handling of a remote control.
Table 6
BIT LEVEL I2C-BUS INTERFACE
Interrupts and their vector addresses
Reset
000H
External INT0
003H
Timer 0
00BH
External INT1
013H
The bit-level serial I/O supports the I2C-bus. P1.6/SCL and
P1.7/SDA are the serial I/O pins. These two pins meet the
I2C-bus specification concerning the input levels and
output drive capability. Consequently, these pins have an
open-drain output configuration. All the four following
modes of the I2C-bus are supported.
Timer 1
01BH
• Master transmitter
I2C-bus
053H
• Master receiver
EVENT
PROGRAM MEMORY ADDRESS
• Slave transmitter
February 1995
13
Philips Semiconductors
Preliminary specification
One page Economy Teletext/TV
microcontroller
SAA5290
• Slave receiver.
LED SUPPORT
I2C-bus
hardware,
The advantages of the bit-level
compared with a full software I2C-bus implementation are:
Port pins P0.5 and P0.6 have a 10 mA current sinking
capability to enable LEDs to be driven directly.
• The hardware can generate the SCL pulse
PWM DACS
• Testing a single bit (RBF or WBF respectively) is
sufficient as a check for error-free transmission.
The SAA5290 has six 6-bit PWM DACs and one14-bit
PWM DAC. These allow direct control of other parts of the
television.
I2C-bus
hardware operates on serial bit level
The bit-level
and performs the following functions:
The low resolution 6 bit DACs are controlled by their
corresponding SFR (PWM0 to PWM5) and are connected
as alternative outputs of Port P2. The port bit
corresponding to the PWM should be set to logic 1 for
correct operation of the PWM.
• Filtering the incoming serial data and clock signals
• Recognizing the START condition
• Generating a serial interrupt request SI after reception of
a START condition and the first falling edge of the serial
clock
• Recognizing the STOP condition
Table 7 Special Function Registers PWM0 to PWM5
• Recognizing a serial clock pulse on the SCL line
• Latching a serial bit on the SDA line (SDI)
• Stretching the SCL LOW period of the serial clock to
suspend the transfer of the next serial data bit
D7
D6
D5
D4
D3
D2
D1
D0
PWE
−
PV5
PV4
PV3
PV2
PV1
PV0
If the PWE bit for a particular port is set to logic 1, the PWM
is active and controls its assigned port pin. If the PWE bit
is set to logic 0 the corresponding port pin is controlled by
the bit in the corresponding port register for that port.
• Setting Read Bit Finished (RBF) when the SCL clock
pulse has finished and Write Bit Finished (WBF) if there
is no arbitration loss detected (i.e. SDA = logic 0 while
SDO = logic 1)
• Setting a Bus Busy (BB) flag on a START condition and
clearing this flag on a STOP condition
The output of the PWM is a pulse of period 21.33 µs with
a duty cycle determined by the binary value, PV5 to PV0,
multiplied by 0.33 µs. The 14 bit PWM is controlled with
SFR registers TDACL and TDACH.
• Releasing the SCL line and clearing the CLH, RBF and
WBF flags to resume transfer to the next serial data bit
Table 8 Special Function Register TDACL
• Setting a serial clock LOW-to-HIGH detected (CLH) flag
• Generating an automatic clock if the single bit data
register S1BIT is used in master mode.
D7
D6
D5
D4
D3
D2
D1
D0
TD7
TD6
TD5
TD4
TD3
TD2
TD1
TD0
D1
D0
TD13 TD12 TD11 TD10 TD9
TD8
The following functions must be done in software:
• Handling the I2C-bus START interrupts
Table 9 Special Function Register TDACH
• Converting serial data to parallel data when receiving
• Converting parallel data to serial data when transmitting
• Comparing the received slave address with its own
address
D6
PWE
−
D5
D4
D3
D2
If the PWE bit is set to logic 1, the TPWM is active and
controls Port P2.0. If the PWE bit is set to logic 0 the port
pin is controlled by the bit in the corresponding port
register for P2.0.
• Interpreting the acknowledge information
• Guarding the I2C-bus status if RBF or WBF = logic 0.
Additionally, if acting as master:
The output of the TPWM is a pulse of period 42.66 µs with
a duty cycle determined by the binary value, TD13 to TD7,
multiplied by 0.33 µs.
• Generating START and STOP conditions
• Handling bus arbitration
• Generating serial clock pulses if S1BIT is not used.
Three SFRs support the function of the bit-level I2C-bus
hardware, they are S1INT, S1BIT and S1SCS.
February 1995
D7
14
Philips Semiconductors
Preliminary specification
One page Economy Teletext/TV
microcontroller
SAA5290
The 7 least significant bits, TD6 to TD0, extend the HIGH
time of a proportion of the pulses by 0.33 µs. If the LSB is
set then 1 in 128 cycles is extended, if bit 1 is set then
1 in 64 cycles is extended, and so on.
SOFTWARE ADC
Up to 3 successive approximation ADCs can be
implemented in software by making use of the on-board
4-bit DAC and multiplexed voltage comparator. The
software ADC uses 3 analog inputs which are multiplexed
with P3.0 to P3.2.
The control of the ADC is achieved using the SAD SFR.
SAD.5 and SAD.6 select one of the three inputs to pass to
the comparator. The other input comes from the DAC
whose input is set by SAD bits 0 to 3. The output of the
comparator is SAD bit 7 and is valid by the next instruction
after starting the comparison by setting SAD.ST to logic 1.
Microcontroller interfacing
The 80C51 CPU communicates with the peripheral
functions using Special Function Registers (SFRs) which
are addressed as RAM locations. The registers in the
teletext decoder appear as normal SFRs in the
microcontroller memory map, but are written to using a
serial bus. This bus is controlled by dedicated hardware
which uses a simple handshake system for software
synchronization. The SFR memory map is given in
Table 10.
February 1995
15
February 1995
Port 0
Port 1
Port 2
Port 3
Power
Control
Program
Status Word
Pulse Width
Modulator 0
Pulse Width
Modulator 1
Pulse Width
Modulator 2
Pulse Width
Modulator 3
Pulse Width
Modulator 4
Pulse Width
Modulator 5
Serial I2C
data
P2(2)
P3(2)(3)
PCON(3)
PSW(2)
PWM0(3)
PWM1(3)
PWM2(3)
PWM3(3)
PWM4(3)
PWM5(3)
S1BIT(3)
Low byte
DPL
P1(2)
High byte
DPH
P0(2)
Data Pointer
(2 bytes):
DPTR:
Interrupt
Enable
B register
IE(2)(3)
Accumulator
B(2)
DESCR.
ACC(2)
SYMBOL
16
D9H
PV5
PV5
PV5
PV5
PV5
PV5
∗
∗
∗
∗
∗
∗
∗
∗
SDI/
SDO
PWE
PWE
PWE
PWE
PWE
PWE
F0
AC
D5
∗
CY
∗
∗
−
D6
−
−
A5
95
∗
PV4
PV4
PV4
PV4
PV4
PV4
RS1
D4
∗
B4
A4
94
84
∗
85
AC
∗
−
−
F4
E4
AD
−
−
F5
E5
D7
A6
96
A7
97
86
ES1
87
AE
EA
−
−
AF
−
F6
E6
−
F7
E7
MSB
∗
PV3
PV3
PV3
PV3
PV3
PV3
RS0
D3
GF1
B3
A3
93
83
ET1
AB
−
−
F3
E3
∗
PV2
PV2
PV2
PV2
PV2
PV2
0V
D2
GF0
B2
A2
92
82
EX1
AA
−
−
F2
E2
∗
PV1
PV1
PV1
PV1
PV1
∗
PV0
PV0
PV0
PV0
PV0
PV0
P
∗
∗
B0
A0
90
80
D0
PV1
LSB
EX0
A8
−
−
F0
E0
D1
∗
B1
A1
91
81
ET0
A9
−
−
F1
E1
BIT ADDRESS, SYMBOL OR ALTERNATIVE PORT FUNCTION
00H
−
−
−
−
−
−
000000X0B
XXXX00XXB
XXX11111B
FFH
FFH
FFH
X0H
00H
00H
00H
00H
RESET
VALUE
(HEX)
One page Economy Teletext/TV
microcontroller
DEH
DDH
DCH
D7H
D6H
D5H
D0H
87H
B0H
A0H
90H
80H
A8H
82H
83H
F0H
E0H
DIRECT
ADDR.
(HEX)
Table 10 SAA5290 Special Function Register map (note 1)
Philips Semiconductors
Preliminary specification
SAA5290
February 1995
E8H
Software
A to D
Stack Pointer 81H
Timer/counter 88H
control
TPWM
High byte
TPWM
Low byte
Timer 0
High byte
Timer 1
High byte
Timer 0
Low byte
Timer 1
Low byte
Timer/counter 89H
mode
Teletext
register 0
Teletext
register 1
Teletext
register 2
Teletext
register 3
SAD(2) (3)
SP
TCON(2)
TDACH
TDACL
TH0
TH1
17
TL0
TL1
TMOD
TXT0(3)
TXT1(3)
TXT2(3)
TXT3(3)
C3H
C2H
CH1
∗
∗
∗
∗
∗
∗
ACQ OFF
8-BIT
∗
GATE
−
−
−
−
TD3
TD11
IE1
8B
SAD3
EB
RBF
DB
∗
PRD4
∗
X26
PRD3
∗
FULL
FIELD
DISABLE DISPLAY
HDR
STATUS
ROLL
ROW
ONLY
AUTO
FRAME
∗
X24
POS
GATE
M0
−
M1
−
−
−
−
C/T
−
−
−
−
−
−
−
−
TD4
TD12
TR0
8C
ST
EC
BB
DC
∗
−
−
−
TD5
TD13
∗
TD6
TF0
8D
CH0
ED
CLH
DD
∗
TR1
TD7
PWE
TF1
8E
VHI
8F
EE
SCI/
SDO
EF
DE
SDI/
SDO
∗
DF
SI
MSB
∗
M1
−
−
−
−
TD1
TD9
IE0
89
SAD1
E9
STR
D9
∗
∗
M0
−
−
−
−
TD0
TD8
IT0
88
SAD0
E8
ENS
D8
∗
LSB
00H
00H
00H
00H
00H
00H
00H
00H
00H
07H
00H
−
−
RESET
VALUE
(HEX)
PRD2
SC2
PRD1
SC1
PRD0
SC0
00H
00H
FIELD
H
V
00H
POLARITY POLARITY POLARITY
DISABLE
FRAME
C/T
−
−
−
−
TD2
TD10
IT1
8A
SAD2
EA
WBF
DA
∗
BIT ADDRESS, SYMBOL OR ALTERNATIVE PORT FUNCTION
One page Economy Teletext/TV
microcontroller
C1H
C0H
8BH
8AH
8DH
8CH
D2H
D3H
D8H
S1SCS(2)(3) Serial I2C
control
DIRECT
ADDR.
(HEX)
DAH
DESCR.
Serial I2C
interrupt
S1INT(3)
SYMBOL
Philips Semiconductors
Preliminary specification
SAA5290
February 1995
18
Teletext
register 5
Teletext
register 6
Teletext
register 7
Teletext
register 8
Teletext
register 9
Teletext
register 10
Teletext
register 11
Teletext
register 12
Teletext
register 13
TXT5(3)
TXT6(3)
TXT7(3)
TXT8(3)
TXT9(3)
TXT10(3)
TXT11(3)
TXT12(3)
TXT13(2)(3)
B8H
CCH
CBH
CAH
C9H
C8H
C7H
C6H
C5H
C4H
DIRECT
ADDR.
(HEX)
BE
∗
∗
ROM
VER R4
D6
BF
625/525
SYNC
D7
∗
BD
ROM
VER R3
D5
C5
∗
BC
ROM
VER R2
D4
C4
∗
BB
ROM
VER R1
D3
C3
R3
∗
R4
∗
BA
ROM
VER R0
D2
C2
R2
∗
∗
A0
∗
CLEAR
MEM.
∗
∗
TEXT IN
TEXT IN
C MESH
ENABLE
∗
TEXT
OUT
TEXT
OUT
B MESH
ENABLE
∗
COR IN
COR IN
∗
∗
COR OUT
COR OUT
EAST/
WEST
SNG/DBL BOX ON
HEIGHT 24
BKGND
IN
BKGND
IN
∗
STATUS CURSOR CONCEAL TOP/
ROW
ON
/REVEAL BTM
TOP
BKGND
OUT
BKGND
OUT
∗
MSB
3. SFRs are modified or added to the 80C51 SFRs.
2. SFRs are bit addressable.
∗
B9
TXT ON
D1
C1
R1
∗
BOX ON
1-23
PICTURE
ON OUT
PICTURE
ON OUT
TRANS
ENABLE
BIT ADDRESS, SYMBOL OR ALTERNATIVE PORT FUNCTION
1. The star (∗) indicates these bits are inactive and must be written to logic 0 for future compatibility.
Notes
Teletext
register 4
DESCR.
TXT4(3)
SYMBOL
TXT
I/FACE
BUSY
B8
VIDEO
QUALITY
D0
C0
R0
CVBS0/
CVBS1
BOX ON 0
PICTURE
ON IN
PICTURE
ON IN
SHADOW
ENABLE
LSB
00H
00H
00H
00H
00H
00H
00000011B
00000011B
00H
RESET
VALUE
(HEX)
Philips Semiconductors
Preliminary specification
One page Economy Teletext/TV
microcontroller
SAA5290
Philips Semiconductors
Preliminary specification
One page Economy Teletext/TV
microcontroller
SAA5290
Table 11 SFR description
REGISTER
FUNCTION
IE - Interrupt Enable
EA
Disable all interrupts (logic 0) or use individual enable bits (logic 1).
ES1
I2C-bus interrupt enable (logic 1).
ET1
Enable Timer 1 overflow interrupt (logic 1).
EX1
Enable external interrupt 1 (logic 1).
ET0
Enable Timer 0 overflow interrupt (logic 1).
EX0
Enable external interrupt 0 (logic 1).
PCON - Power Control
GF0
General purpose flag bit 0.
GF1
General purpose flag bit 1.
PWM0 to PWM5 - 6-bit Pulse Width Modulator control registers
PWE
Activate this 6-bit PWM and take over port pin (logic 1).
PV0 to PV5
Value to output by this 6-bit PWM.
SAD - Software ADC control
VHI
Analog input voltage greater than DAC output voltage (logic 1).
CH0 and CH1
See Table 12.
ST
Initiate voltage comparison (logic 1). This is automatically reset.
SAD0 to SAD3
4-bit DAC input value. The DAC output of this value is compared with analog input voltage.
S1BIT - Serial I2C-bus data (READ)
SDI
I2C-bus data bit latched-in from SDA on the last rising edge of SCL.
S1BIT - Serial I2C-bus data (WRITE)
SDO
I2C-bus data bit output.
S1INT - Serial I2C-bus interrupt
SI
I2C-bus interrupt flag.
S1SCS - Serial I2C-bus control (READ)
SDI
Serial data input at SDA.
SCI
Serial clock input at SCL.
CLH
Clock LOW-to-HIGH transition flag.
BB
Bus busy flag.
RBF
Read bit finished flag.
WBF
Write bit finished flag.
STR
Clock stretching enable (logic 1).
ENS
Enable serial I/O (logic 1).
February 1995
19
Philips Semiconductors
Preliminary specification
One page Economy Teletext/TV
microcontroller
SAA5290
REGISTER
FUNCTION
S1SCS - Serial I2C-bus control (WRITE)
SDO
Serial data output at SDA.
SCO
Serial clock output at SCL.
CLH
Clock LOW-to-HIGH transition.
STR
Clock stretching enable (logic 1).
ENS
Enable serial I/O (logic 1).
TDACH - 14-bit PWM MSB register
PWE
Activate this 14-bit PWM and take over port pin (logic 1).
TD8 to TD13
6 LSBs of this value to be output by the 14-bit PWM.
TDACL - 14-bit PWM LSB register
TD0 to TD7
8 LSBs of this value to be output by the 14-bit PWM.
TXT0 - Teletext register 0 (WRITE only)
X24 POSITION
Store packet 24 in extension packet memory (logic 0) or page memory (logic 1).
AUTO FRAME
Frame output switched off automatically if any video displayed (logic 1).
DISABLE HDR ROLL Do not write rolling headers and time into memory (logic 1).
STATUS ROW ONLY Display only memory row (logic 1).
DISABLE FRAME
Frame output always LOW (logic 1).
TXT1 - Teletext register 1 (WRITE only)
8-BIT
Data in packets 0 to 24 written into memory without error checking (logic 1).
ACQ OFF
Prevent teletext acquisition section writing to memory (logic 1).
X26
Disable automatic processing of packet 26 data (logic 1).
FULL FIELD
Accept teletext on TV lines 2 to 22 only (logic 0) or on any line (logic 1).
FIELD POLARITY
VSYNC in first half of the line (logic 0) or second half of the line (logic 1) at start of even field.
H POLARITY
HSYNC input positive-going (logic 0) or negative-going (logic 1).
V POLARITY
VSYNC input positive-going (logic 0) or negative-going (logic 1).
TXT2 - Teletext register 2 (WRITE only)
SC0 to SC2
Start column at which page request data written into TXT3 SFR is placed.
TXT3 - Teletext register 3 (WRITE only)
PRD0 to PRD4
Page request data.
TXT4 - Teletext register 4 (WRITE only)
B MESH ENABLE
Enable meshing of area with black background (logic 1).
C MESH ENABLE
Enable meshing of area with other background colours (logic 1).
TRANS ENABLE
Black background colour is transparent i.e. video is displayed (logic 1).
SHADOW ENABLE
Enable south-east shadowing (logic 1).
EAST/WEST
Western European languages displayed (logic 0) or Eastern European languages displayed
(logic 1).
February 1995
20
Philips Semiconductors
Preliminary specification
One page Economy Teletext/TV
microcontroller
SAA5290
REGISTER
FUNCTION
TXT5 - Teletext register 5 (WRITE only)
BKGND OUT
Background colour displayed outside teletext boxes (logic 1).
BKGND IN
Background colour displayed inside teletext boxes (logic 1).
COR OUT
COR output active outside teletext boxes (logic 1).
COR IN
COR output active inside teletext boxes (logic 1).
TEXT OUT
Text displayed outside teletext boxes (logic 1).
TEXT IN
Text displayed inside teletext boxes (logic 1).
PICTURE ON OUT
Video picture displayed outside teletext boxes (logic 1).
PICTURE ON IN
Video picture displayed inside teletext boxes (logic 1).
TXT6 - Teletext register 6 (WRITE only)
−
This register has the same meaning as TXT5 but is only invoked if either newsflash (C5) or the
subtitle (C6) bit in Row 25 of the basic page memory is set.
TXT7 - Teletext register 7 (WRITE only)
STATUS ROW TOP
Display Row 24 below (logic 0) or above (logic 1) teletext page.
CURSOR ON
Display cursor at location pointed to by TXT9 and TXT10 (logic 1).
CONCEAL/REVEAL
Display characters in areas with the conceal attribute set (logic 1).
TOP/BOTTOM
Display Rows 0 to 11 (logic 0) or 12 to 23 (logic 1) when the double height bit is set.
SNG/DBL HEIGHT
Display each character at twice normal height (logic 1).
BOX ON 24
Enable teletext boxes in memory Row 24 (logic 1).
BOX ON 1-23
Enable teletext boxes in memory Rows 1 to 23 (logic 1).
BOX ON 0
Enable teletext boxes in memory Row 0 (logic 1).
TXT8 - Teletext register 8 (WRITE only)
CVBS0/CVBS1
CVBS0 input (logic 0) or CVBS1 (logic 1) inputs used for teletext.
TXT9 - Teletext register 9 (WRITE only)
CLEAR MEMORY
Write 20H into every location in teletext memory (logic 1).
A0
Access basic page memory (logic 0) or extension packet memory (logic 1) with TXT11 SFR.
R0 to R4
Memory row to be accessed with TXT11 SFR.
TXT10 - Teletext register 10 (WRITE only)
C0 to C5
Memory column to be accessed with TXT11 SFR.
TXT11 - Teletext register 11
D0 to D7
February 1995
data byte written to, or read from, teletext memory.
21
Philips Semiconductors
Preliminary specification
One page Economy Teletext/TV
microcontroller
SAA5290
REGISTER
FUNCTION
TXT12 - Teletext register 12 (READ only)
625/525 SYNC
A 625 line CVBS signal (logic 0), or a 525 line CVBS signal (logic 1) is being input.
ROM VER R0 to R4
Mask programmable to identify character set version.
TXT ON
Teletext power has been applied to the device (logic 1).
VIDEO QUALITY
CVBS input can be locked on by the teletext decoder (logic 1).
TXT13 - Teletext register 13 (READ only)
TXT I/FACE BUSY
Text interface busy and no access for either READ or WRITE is allowed to SFRs
TXT0 to TXT11 (logic 1). This register bit performs the software handshake to the teletext
control registers.
Table 12 CH1 and CH0 selection
CH1
CH0
INPUT PIN
0
0
none
0
1
ADC0
1
0
ADC1
1
1
ADC2
February 1995
22
Philips Semiconductors
Preliminary specification
One page Economy Teletext/TV
microcontroller
SAA5290
TELETEXT DECODER FUNCTIONAL DESCRIPTION
Data slicer
Acquisition timing
One is constant and is proportional to the difference
between the black level of the video and the slicing level.
The other is produced only when the video is below the
slicing level, and is also proportional to the difference
between the slicing level and the input, but has a
magnitude13 times greater.
The acquisition timing is generated from a logic level
positive-going composite sync signal ‘VCS’. This signal is
generated by the sync separator circuit which adaptively
slices the sync pulses at 50% of their height. It is able to do
this over a wide range of sync amplitudes by using the
same basic principle used on VIP1 (SAA5230) and VIP2
(SAA5231).
The black level is determined by a sync-gated peak
detector. The video is negatively peak detected into an
external capacitor (BLACK, pin 25), but not during the
sync pulse VCS. The two currents are integrated on the
CVBS input coupling capacitor and the net effect is to alter
the mean input voltage until the (fixed) slicing level is
correct.
Figure 4 is a block diagram showing the principles of
operation. It relies upon the fact that the ratio of the sync
width to the line time is approximately 13 : 1. In order to
slice the sync pulse at the correct 50% level two currents
are generated.
The acquisition clocking and timing are locked to the VCS
signal using a digital phased-locked-loop. The phase error
in the acquisition phase-locked-loop is detected by a
signal quality circuit which disables acquisition if poor
signal quality is detected.
The data slicer extracts the digital teletext data from the
incoming analog waveform. This is performed by sampling
the CVBS waveform and processing the samples to
extract the teletext data and clock.
VDD
handbook, full pagewidth
Vref
1/3Vi (mA)
CVBS
VCS
FILTER
Vref
(= slicing level)
FILTER
gated negative peak detector
1/39V i(mA)
BLACK
Vref
MLC105
Fig.4 Sync separator block diagram.
February 1995
23
Philips Semiconductors
Preliminary specification
One page Economy Teletext/TV
microcontroller
SAA5290
If the ‘DO CARE’ bit for part of the page number is set to
logic 0 then that part of the page number is ignored when
the acquisition section is deciding whether a page being
received off air should be stored or not. For example if the
‘DO CARE’ bits for the 4 subcode digits are all set to
logic 0 then every subcode version of the page will be
captured.
Teletext acquisition
The SAA5290 is able to acquire 625-line World System
Teletext. Teletext is acquired under control of the on-board
80C51 microcontroller. Pages are requested by writing a
series of bytes into the TXT3 SFR which corresponds to
the number of the page required. The bytes written into
TXT3 are put into a small RAM with an auto-incrementing
address. The start address for the RAM is set using the
SFR TXT2 register. Table 13 shows the contents of the
page request RAM.
When the ‘HOLD' bit is set to logic 0 the acquisition section
will not recognize any page as having the correct page
number and no pages will be captured.
Table 13 Register map for page requests (TXT3); note 1
START
COLUMN
0
PRD4
MAG1
MAG0
PT3
PT2
PT1
PT0
PU3
PU2
PU1
PU0
X
X
HT1
HT0
HU3
HU2
HU1
HU0
X
MT2
MT1
MT0
MU3
MU2
MU1
MU0
DO CARE
Minutes tens
6
MAG2
DO CARE
Hours units
5
HOLD
DO CARE
Hours tens
4
DO CARE
Minutes units
Note
1. X = don't care.
Page memory organization
The acquired teletext packets each contain 40 bytes of
data and one packet is stored in each row of the text
memory. The page memory organization is given in Fig.5.
Rows 0 to 23 form the teletext page; Row 24 is available
for status messages and FLOF/FASTEXT prompt
information.
February 1995
PRD0
DO CARE
Page units
3
PRD1
DO CARE
Page tens
2
PRD2
DO CARE
Magazine
1
PRD3
24
Philips Semiconductors
Preliminary specification
One page Economy Teletext/TV
microcontroller
handbook, full pagewidth
7 characters
for status
1
SAA5290
fixed character written by
hardware, alphanumerics white normally, alphanumerics green when
looking for display page
6 7 8
8 characters
usually rolling
(time)
31 32
39
24 characters from page header
rolling when display page looked for
MAIN PAGE DISPLAY AREA
0
1
2
3
4
5
to
20
21
22
23
24
25
PACKET X / 22
PACKET X / 23
PACKET X24 STORED HERE IF TXT0.7 = 1
10
14
10 bytes for
received
page information
ROW
14 bytes
free for use
by microcontroller
MLC106
Fig.5 Basic page memory organization.
ROW 0 (see Fig.5)
Packet 26 processing
Row 0 is for the page header. The first seven characters
(0 to 6) are free for status messages. Character 8 is an
alphanumeric white or green control character, written
automatically by SAA5290 to give a green rolling header
when a page is being looked for. The last eight characters
are for rolling time.
The SAA5290 contains on-board hardware processing of
Packet 26 data. If a character corresponding to that being
transmitted is available in the character set then the
correct character code is written into the display memory.
ROW 25 (see Fig.5)
The first 10 bytes of row 25 contain control data relating to
the received page as shown in Table 14. The remaining 14
bytes are free for use by the microcontroller.
PACKET X24 if TXT0.X24 POS = 0
0
PACKET X27 / 0
1
PACKETS 8 / 30 / 0 to 15
2
MLC107
Extension packet memory organization
If TXT0.X24 POS bit is set to logic 0, then Packet 24 is
written into Row 0 of the extension memory.
Fig.6 Organization of the extension memory.
Packet X27/0 is written to Row 1 of the extension memory,
with bytes 0 to 37 being Hamming checked automatically.
Packet 8/30 is written to Row 2 of the extension memory,
with bytes 0 to 6 being 8/4 Hamming checked, bytes
7 to 19 unchecked and bytes 20 to 39 odd parity checked.
February 1995
ROW
handbook, halfpage
25
Philips Semiconductors
Preliminary specification
One page Economy Teletext/TV
microcontroller
SAA5290
Table 14 Row 25 received control data format
ROW 25
D0
PU0
PT0
MU0
MT0
HU0
HT0
C7
C11
MAG0
0
D1
PU1
PT1
MU1
MT1
HU1
HT1
C8
C12
MAG1
0
D2
PU2
PT2
MU2
MT2
HU2
C5
C9
C13
MAG2
0
D3
PU3
PT3
MU3
C4
HU3
C6
C10
C14
0
0
D4
HAM.ER HAM.ER HAM.ER HAM.ER HAM.ER HAM.ER HAM.ER HAM.ER FOUND
0
D5
0
0
0
0
0
0
0
0
0
PBLF
D6
0
0
0
0
0
0
0
0
0
0
D7
0
0
0
0
0
0
0
0
0
0
Column
0
1
2
3
4
5
6
7
8
9
Table 15 Page number and sub-code for Table 14
BIT NAME
DESCRIPTION
Page number
MAG
magazine
PU
page units
PT
page tens
PBLF
page being looked for
HAM.ER
Hamming error in corresponding byte
Page sub-code
MU
minutes units
MT
minutes tens
HU
hours units
HT
hours tens
C4 to C14
transmitted control bits
February 1995
26
Philips Semiconductors
Preliminary specification
One page Economy Teletext/TV
microcontroller
SAA5290
Display
The capabilities of the display are based on the
requirements of level 1 teletext, with some enhancements
for use with locally generated On-Screen Displays (OSD).
The display character set is given in Fig.9. The character
set provided contains all the characters required to display
Eastern and Western European languages. Register bit
TXT4.EAST/ WEST sets whether Eastern or Western
languages are set with the C12 to C14 bits. In order to
make on-screen displays easy to use, the SAA5290
contains additional display attributes in Column 11.
The display consists of 25 rows each of 40 characters,
with the characters displayed being those from
Rows 0 to 24 of the basic page memory. The page
memory stores 8-bit character codes which correspond to
260 displayable characters and 44 control codes, normally
displayed as spaces. Each character is defined by a matrix
12 pixels high and 10 pixels deep. When displayed each
pixel is 0.5 µs wide and 1 TV line, in each field, high.
Control codes are categorized as ‘set at’ or ‘set after’.
‘Set at’ means the code has effect at the current character
position and ‘set after’ means they have effect from the
following character. Codes 11/0 to 11/7 are always
‘set at’. Codes 11/11 to 11/15 are ‘set after’ when defining
the start of an OSD box and ‘set at’ when ending an OSD
box. Codes 11/12 to 11/15 force a box condition allowing
on-screen display messages to be displayed without
having to erase the whole contents of the teletext page.
The SAA5290 signals the TV display circuits to display the
RGB outputs of the SAA5290 rather than video picture by
setting VDS HIGH. The way in which this signal is switched
is controlled by the TXT5 and TXT6 SFRs. There are three
control functions: background on, text on and picture on.
There are separate bits for each function for inside and
outside teletext boxes and if the newsflash or subtitle bits
are set. This allows the software to configure the type of
display required. The effect of the combination of these
bits is given in Table 16. The COR bits in Register 5 and
Register 6 control when the output is pulled LOW. This
output is intended to act on the TV display circuits to
reduce the contrast of the video display.
On-screen displays are only available in TV mode and not
in text mode. In mixed text and TV mode the displayed
screen is not defined if an OSD box is encountered in the
page memory.
Table 16 Display mode
PICTURE ON
TEXT ON
BACKGROUND ON
RESULT
0
0
X
text mode, black screen
0
1
0
text mode, background always black
0
1
1
text mode
1
0
X
TV mode
1
1
0
mixed mode and TV mode
1
1
1
text mode, TV picture outside text area
Display timing
The display circuitry is driven from the H/VSYNC inputs,
and is independent of the input video signal. Consequently
HSYNC and VSYNC are always required to slave
synchronize the display.
if the active edge of VSYNC is in the second half of a line
then the field is odd. The active edge is controlled with
TXT1.V POLARITY. With TXT0.AUTO FRAME LOW
FRAME is HIGH for an odd field and LOW for an even
field. With TXT0.AUTO FRAME HIGH FRAME is only
active when text is being displayed, when video is
displayed it is forced LOW. When TXT0.DISABLE FRAME
is HIGH FRAME is always LOW. If
TXT1.FIELD POLARITY is logic 1 then VSYNC is delayed
by 32 µs before being applied to the display timing circuits.
The FRAME output of the SAA5290 is provided to facilitate
de-interlacing the teletext display. The behaviour of
FRAME is controlled via the register bits
TXT0.DISABLE FRAME, TXT0.AUTO FRAME and
TXT1.FIELD POLARITY. If the active edge of VSYNC
occurs in the first half of a TV line then the field is even, and
February 1995
27
Philips Semiconductors
Preliminary specification
One page Economy Teletext/TV
microcontroller
SAA5290
Clock generator
circuitry. It is operated in parallel resonance. OSCIN is the
high gain amplifier input and OSCOUT is the output. To
drive the SAA5290 externally OSCIN is driven from an
external source and OSCOUT is left open-circuit.
The oscillator circuit of the SAA5290 is a single-stage
inverting amplifier in a Pierce oscillator configuration. The
circuitry between OSCIN and OSCOUT is basically an
inverter biased to the transfer point. A crystal must be
used as the feedback element to complete the oscillator
handbook, halfpage
handbook, halfpage
OSCGND
C1
not connected
OSCGND
(1)
OSCIN
external clock
C2 (1)
not connected
OSCOUT
MLC110
OSCIN
OSCOUT
MLC111
(1) The values of C1 and C2 depend on the crystal specification:
C1 = C2 = 2CL.
Fig.7 Oscillator circuit.
February 1995
Fig.8 Oscillator circuit driven from external source.
28
February 1995
b
7
b
6
b5
b
4
0
0
1
1
1
1
1
1
1
1
1
1
1
0
0
1
0
1
1
0
0
0
0
1
0
0
1
0
0
0
0
0
29
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
3
2
1
0
graphics
magenta
graphics
cyan
alpha numerics
magenta
alpha numerics
cyan
F
E
D
C
B
A
9
black
back ground
new
back ground
hold
graphics
release
graphics
double
height
double
width
double
size
separated
graphics
contiguous
graphics
conceal
display
normal
height
start box
end box
steady
flash
graphics
blue
alpha numerics
blue
8
graphics
yellow
alpha numerics
yellow
graphics
white
graphics
green
alpha numerics
green
alpha numerics
white
graphics
red
alpha numerics
red
1
graphics
black
0
1
0
0
0
0
0
alpha numerics
black
0
7
6
5
4
r
o
w
column
0
2
0
0
1
2a
0
3
0
0
1
3a
1
0
0
0
0
5
1
0
1
6
0
1
1
6a
0
handbook, full pagewidth
7
0
1
1
7a
1
1
0
8
0
0
1
0
9
0
1
1
1
A
0
0
Fig.9 SAA5290 European character set.
4
1
1
B
0
1
double
size
OSD
double
width
OSD
double
height
OSD
normal
size
OSD
background
white
background
cyan
background
magenta
background
blue
background
yellow
background
green
back
ground
red
background
black
1
1
0
C
1
0
1
0
D
1
1
1
1
E
1
0
1
1
F
1
1
1
0
D
1
1
1
1
E
1
0
1
F
1
1
MLC108
1
One page Economy Teletext/TV
microcontroller
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
b 3 b 2 b1 b 0
B
I
T
S
Philips Semiconductors
Preliminary specification
SAA5290
CHARACTER SETS
Philips Semiconductors
Preliminary specification
One page Economy Teletext/TV
microcontroller
SAA5290
handbook, full pagewidth
CHARACTER POSITION (COLUMN / ROW)
PHCB
LANGUAGE
E/W C12 C13 C14 2 / 3
ENGLISH
0
0
0
0
GERMAN
0
0
0
1
SWEDISH
0
0
1
0
ITALIAN
0
0
1
1
FRENCH
0
1
0
0
SPANISH
0
1
0
1
TURKISH
0
1
1
0
ENGLISH
0
1
1
1
POLISH
1
0
0
0
GERMAN
1
0
0
1
ESTONIAN
1
0
1
0
GERMAN
1
0
1
1
GERMAN
1
1
0
0
SERBO-CROAT
1
1
0
1
CZECHOSLOVAKIA
1
1
1
0
RUMANIAN
1
1
1
1
2/4
4/0
5/B
5/C
5/D
5/E
5/F
6/0
7/B
7/C
7/D
7/E
MLC109
Fig.10 SAA5290 European national option characters.
February 1995
30
February 1995
31
VDD
VDD
CVBS (IF)
P1.4
P1.5
1 kΩ
Vafc
HSYNC
VDS
R
P0.2
P0.3
P0.4
P0.5
FRAME
IREF
Fig.11 Typical application diagram.
MLC112
V SSD2
BLACK
27 kΩ
COR
P3.4
CVBS1
CVBS0
RGBREF
B
P0.7
V SSA
G
P0.6
SAA5290
V DDA
VSYNC
P0.1
V DDT
OSCGND
P0.0
VSSD
VDD
100 nF
VDD
2.2 µF
4.7
kΩ
VDD
1
kΩ 10
kΩ
3.3
kΩ
VDD
100
nF
TV
control
signals
VDD
to TV's
display
circuits
line flyback
field flyback
47
µF
IR
RECEIVER
VDD
One page Economy Teletext/TV
microcontroller
CVBS (SCART)
100
nF
100 nF
OSCOUT
P3.2/ADC2
OSCIN
RESET
P3.1/ADC1
P3.3
V DDM
P3.0/ADC0
P1.0/INT1
P1.1/T0
P2.6/PWM5
P2.7
P2.5/PWM4 P1.2/INT0
volume (L)
P1.3/T1
P1.6/SCL
VDD
12 MHz
VSS SDA
volume (R)
P2.4/PWM3
100 nF
RC
SCL
A1
A2
VDD
A0
EEPROM
PCF8582E
P2.2/PWM1 P1.7/SDA
P2.1/PWM0
P2.0/TPWM
100
nF
VDD
hue
47
µF
VDD
P2.3/PWM2
PH2369
VDD
saturation
contrast
brightness
VDD
Vtune
40 V
handbook, full pagewidth
Philips Semiconductors
Preliminary specification
SAA5290
APPLICATION INFORMATION
February 1995
seating plane
Dimensions in mm.
3.2
2.8
32
14.1
13.7
0.18 M
0.51
min
4.57 5.08
max max
0.32 max
17.15
15.90
15.24
15.80
15.24
MSA267
One page Economy Teletext/TV
microcontroller
Fig.12 Plastic shrink dual in-line package; 52 leads (600 mil) SDIP52, SOT247-1.
26
1
1.3 max
0.53
max
27
1.778
(25x)
47.92
47.02
52
1.73
max
handbook, full pagewidth
Philips Semiconductors
Preliminary specification
SAA5290
PACKAGE OUTLINE
Philips Semiconductors
Preliminary specification
One page Economy Teletext/TV
microcontroller
SAA5290
specified storage maximum. If the printed-circuit board has
been pre-heated, forced cooling may be necessary
immediately after soldering to keep the temperature within
the permissible limit.
SOLDERING
Plastic dual in-line packages
BY DIP OR WAVE
The maximum permissible temperature of the solder is
260 °C; this temperature must not be in contact with the
joint for more than 5 s. The total contact time of successive
solder waves must not exceed 5 s.
REPAIRING SOLDERED JOINTS
Apply the soldering iron below the seating plane (or not
more than 2 mm above it). If its temperature is below
300 °C, it must not be in contact for more than 10 s; if
between 300 and 400 °C, for not more than 5 s.
The device may be mounted up to the seating plane, but
the temperature of the plastic body must not exceed the
DEFINITIONS
Data sheet status
Objective specification
This data sheet contains target or goal specifications for product development.
Preliminary specification
This data sheet contains preliminary data; supplementary data may be published later.
Product specification
This data sheet contains final product specifications.
Limiting values
Limiting values given are in accordance with the Absolute Maximum Rating System (IEC 134). Stress above one or
more of the limiting values may cause permanent damage to the device. These are stress ratings only and operation
of the device at these or at any other conditions above those given in the Characteristics sections of the specification
is not implied. Exposure to limiting values for extended periods may affect device reliability.
Application information
Where application information is given, it is advisory and does not form part of the specification.
LIFE SUPPORT APPLICATIONS
These products are not designed for use in life support appliances, devices, or systems where malfunction of these
products can reasonably be expected to result in personal injury. Philips customers using or selling these products for
use in such applications do so at their own risk and agree to fully indemnify Philips for any damages resulting from such
improper use or sale.
PURCHASE OF PHILIPS I2C COMPONENTS
Purchase of Philips I2C components conveys a license under the Philips’ I2C patent to use the
components in the I2C system provided the system conforms to the I2C specification defined by
Philips. This specification can be ordered using the code 9398 393 40011.
February 1995
33