Datasheet TDA3561A Datasheet (Philips)

INTEGRATED CIRCUITS

DATA SH EET

TDA3561A

PAL decoder

Product specification
File under Integrated Circuits, IC02

September 1982

Philips Semiconductors Product specification

PAL decoder TDA3561A

GENERAL DESCRIPTION

The TDA3561A is a decoder for the PAL colour television standard. It combines all functions required for the identification
and demodulation of PAL signals. Furthermore it contains a luminance amplifier, an RGB-matrix and amplifier. These
amplifiers supply output signals up to 5 V peak-to-peak (picture information) enabling direct drive of the discrete output
stages. The circuit also contains separate inputs for data insertion, analogue as well as digital, which can be used for
text display systems (e.g. (Teletext/broadcast antiope), channel number display, etc. Additional to the TDA3560, the
circuit includes the following features:

• The peak white limiter is only active during the time that the 9,3 V level at the output is exceeded. The start of the
limiting function is delayed by one line period. This avoids peak white limiting by test patterns which have abrupt
transitions from colour to white signals.

• The brightness control is obtained by inserting a variable pulse in the luminance channel. Therefore the ratio of
brightness variation and signal amplitude at the three outputs will be identical and independent of the difference in gain
of the three channels. Thus discolouring due to adjustment of contrast and brightness is avoided.

• Improved suppression of the internal RGB signals when the device is switched to external signals, and vice versa.

• Non-synchronized external RGB signals do not disturb the black level of the internal signals.

• Improved suppression of the residual 4,4 MHz signal in the RGB output stages.

• Cascoded stages in the demodulators and burst phase detector minimize the radiation of the colour demodulator

inputs.

• High current capability of the RGB outputs and the chrominance output.

QUICK REFERENCE DATA

Supply voltage V
Supply current I
Luminance input signal (peak-to-peak value) V
Chrominance input signal (peak-to-peak value) V
Data input signals (peak-to-peak value) V

1−27

1

10-27(p-p)
3-27(p-p)
13, 15, 17-27(p-p)

type. 12 V
typ. 85 mA
typ. 0,45 V
55 to 1100 mV
typ. 1 V

RGB output signals at nominal contrast

and saturation (peak-to-peak value) V

12, 14, 16-27(p-p)

typ. 5,25 V
Contrast control range typ. 20 dB
Saturation control range min. 50 dB
Input voltage for data insertion V
Blanking input voltage V
Burst gating and black-level gating input voltage V

9-27
8-27
8−27

min. 0,9 V

typ. 1,5 V

typ. 7 V

PACKAGE OUTLINE

28-lead DIL; plastic (SOT 117); SOT117-1; 1996 November 21.

September 1982 2

Philips Semiconductors Product specification

PAL decoder TDA3561A

September 1982 3

Fig.1 Block diagram.

Philips Semiconductors Product specification

PAL decoder TDA3561A

RATINGS

Limiting values in accordance with the Absolute Maximum System (IEC 134)

Supply voltage V
Total power dissipation; see also Fig.2 P
Storage temperature range T
Operating ambient temperature range T

THERMAL RESISTANCE

P
tot
stg
amb

= V

1-27

max. 13,2 V

max. 1,7 W

−25 to + 150 °C

−25 to + 65 °C

From junction to ambient R

th j-a

= 50 K/W

CHARACTERISTICS

V

P=V1-27

= 12 V; T

Supply voltage V

=25°C; unless otherwise specified

amb

P=V1−27

typ. 12 V

8 to 13,2 V

Supply current

Total power dissipation P

tot

typ. 85 mA
< 115 mA
typ. 1,0 W

< 1,4 W
Luminance input (pin 10)
Input voltage (peak-to-peak value); note 1 V

Input level before clipping V
Input current; input level 2 V, clamp not active I

10-27(p-p)
10−27

10

typ. 0,45 V

< 2V

typ. 0,15 µA

< 1 µA
Contrast control range (see Fig.3) −17 to + 3dB
Control voltage for 40 dB attenuation V
Input current contrast control at V

=3 V I

7−27

7-27

7

typ. 1,2 V

< 10 µA

Chrominance amplifier

Input voltage (peak-to-peak value); note 2 V

(p-p) typ. 550 mV

3-27

55 to 1100 mV
Input impedance |Z

Input capacitance C

3−27

3−27

|

typ. 9 kΩ

6 to 12 kΩ

typ. 4 pF

< 6pF
A.C.C. control range > 30 dB
Change of the burst signal at the output

over the whole control range < 1,5 dB

Gain at nominal contrast/saturation

pin 3 to pin 28; note 3 > 32 dB

Output signal (peak-to-peak value)

at nominal contrast/saturation;

V

28-27(p-p)

typ. 1,7 V

burst signal: 0,5 V peak to peak

September 1982 4

Philips Semiconductors Product specification

PAL decoder TDA3561A

Maximum output voltage (peak-to-peak value)

=2 kΩ V

R

L

28-27(p-p)

Distortion of chrominance amplifier
at V

28-27(p-p)

= 2 V up to V

3-27(p-p)

= 1 V d

Frequency response between 0 and 5 MHz −2dB
Saturation control range (see Fig.4) > 50 dB
Input current saturation control at V

=3 V I

6−27

6

Tracking between luminance and chrominance

with contrast control over a range of 10 dB < 2dB

Cross-coupling between luminance

and chrominance amplifier; note 10 <−46 dB

Signal-to-noise ratio

at nominal input signal; note 11 S/N > 56 dB

Phase shift between burst and chrominance

at nominal contrast/saturation ∆ ϕ < ± 5
Output impedance of chrominance amplifier Z
Maximum output current I

 typ. 25 Ω

28-27

28

Reference part

Phase locked loop:

− catching range; note 4 > 500 Hz

− phase shift; note 5 < 5°

Oscillator:

− temperature coefficient of oscillator frequency; note 4 typ. −1,5 Hz/K

− frequency deviation for V

− input resistance (pin 26) R

− input capacitance (pin 26) C

− output resistance (pin 25) R

− output voltage (peak-to-peak value; pin 25) V

changing from 10 to 13,2 V; note 4 typ. 40 Hz

P

26-27

26-27

25-27

25−27(p-p)

A.C.C. generation:

− reference voltage (pin 4) V

− control voltage at nominal input signal (pin 2) V

− control voltage without chrominance input (pin 2) V

− colour-off voltage (pin 2) V

− colour-on voltage (pin 2) V

− identification-on voltage (pin 2) V

4−27
2−27
2−27
2−27
2−27
2−27

typ. 4,0 V

typ. 1,5 %

< 5%

< 15 µA

o

< 15 mA

typ. 700 Hz

typ. 340 Ω

260 to 420 Ω

< 10 pF
typ. 150 Ω

100 to 200 Ω

typ. 700 mV

typ. 4,9 V
typ. 5,1 V
typ. 2,65 V
typ. 3,15 V
typ. 3,4 V
typ. 1,9 V

September 1982 5

Philips Semiconductors Product specification

PAL decoder TDA3561A

− change in burst amplitude with supply voltage (± 10%) proportional

− change in burst amplitude with temperature

− voltage at pin 5 at nominal input signal V

5−27

Demodulator part

Input burst signal amplitude (peak-to-peak value)

between pins 21 and 22; note 6 V
Input impedance between pins 21 and 22 Z

21−22(p-p)

 typ. 2 kΩ

21−22

Ratio of demodulated signals for equal input

signals at pins 21 and 22

(B-Y)/(R-Y) typ. 1,78 ± 10%

(G-Y)/(R-Y); no (B-Y) signal typ. −0,51 ± 10%

(G-Y)/(B-Y); no (R-Y) signal typ. −0,19 ± 25%

V

16 27–

-----------------­V

12 27–

V

14 27–

-----------------­V

12 27–

V

14 27–

-----------------­V

16 27–

Frequency response between 0 and 1 MHz −3dB
Cross talk between colour demodulated signals > 40 dB
Phase difference between (R-Y) signal

and (R-Y) reference signal < 5°
Phase difference between (R-Y) typ. 90°

and (B-Y) reference signals 85 to 95°

typ. 0,1 %/K
< 0,25 %/K
typ. 5 V

typ. 100 mV

R.G.B. matrix and amplifiers

Output voltage (peak-to-peak value)

at nominal luminance/contrast typ. 5,4

(black to white); note 3 V

12,14,16-27(p-p)

4,5 to 6,3 V

Output voltage (peak-to-peak value) of the RED

channel at nominal contrast/saturation and

no luminance signal at the input, (R-Y) signal

V

12-27(p-p)

typ. 5,25 V

3,7 to 6,7 V

Maximum peak white level; note 7 typ. 9,3 V

9,0 to 9,6 V

Maximum output current I

12,14,16

< 15 mA

Black level at the output for a

brightness control voltage of 2 V V

12,14,16-27

typ. 2,6 V

Difference in black level between the three

channels at an output level of 3 V; note 8 ∆V < 200 mV
Black level shift with vision contents < 40 mV
Brightness control voltage range see Fig.5

September 1982 6

V

Philips Semiconductors Product specification

PAL decoder TDA3561A

Input current brightness control I

11

Variation of black level with temperature ∆V

Variation of black level with contrast control ∆V

< 50 µA
typ. 0,35 mV/K
< 1,0 mV/K
typ. 10 mV

< 200 mV
Relative spread between the R, G and B output signals < 10 %
Relative black-level variation between the three channels typ. 0 mV

during variation of contrast and supply voltage < 20 mV

Differential black-level drift over a

temperature range of 40 °C typ. 0 mV

< 20 mV
Blanking level at the RGB outputs typ. 2,1 V

1,9 to 2,3 V

Difference in blanking level

of the three channels typ. 0 mV

Differential blanking level drift

over a temperature range of 40 °C typ. 0 mV

Tracking of output black level

with supply voltage typ. 1,1

∆

-----------

V

V

bl

P

×

----------

V

VP∆

bl

Signal-to-noise ratio of output signals;

note 11 S/N > 62 dB

Residual 4,4 MHz signal at RGB outputs typ. 40 mV

(peak-to-peak value) < 150 mV

Residual 8,8 MHz signal and higher harmonics typ. 75 mV

at the RGB outputs (peak-to-peak value) < 150 mV

Output impedance of RGB outputs Z

12,14,16-27

 typ. 50 Ω

Frequency response of total luminance and

RGB amplifier circuits for f = 0 to 5 MHz <−3dB
Signal insertion (pins 13,15 and 17)
Input signals (peak-to-peak value) for

V

an RGB output voltage of 5 V peak-to-peak 0,85 to 1,1 V

13,15,17-27(p-p)

typ. 1 V

Difference between the black levels of the

RGB signals and the inserted signals

∆V < 260 mV

at the output; note 9
Output rise time t

Differential delay time for the three channels t
Input current I

r

d

13,15,17

typ. 40 ns
<80 ns
typ. 0 ns
<40 ns
< 10 µA

September 1982 7

Philips Semiconductors Product specification

PAL decoder TDA3561A

Data blanking (pin 9)
Input voltage for no data insertion V

Input voltage for data insertion V
Maximum input voltage V
Delay of data blanking t
Input current I
Input impedance Z

9-27
9−27

9−27
d
9

 typ. 10 kΩ

9-27

Suppression of the internal RGB signals

when V

> 0,9 V > 46 dB

9−27

Sandcastle input (pin 8)
Level at which the RGB blanking

is activated V

8-27

Level at which burst gating and
clamping pulse are separated V

8-27

Delay between black level clamping and

burst gating pulse t

d

Input current for:

= 0 to 1 V −I

V

8-27

= 1 to 8,5 V I

V

8-27

= 8,5 to 12 V I

V

8-27

8
8
8

Notes to the characteristics

1. Signal with the negative-going sync; amplitude includes sync pulse amplitude.

2. Indicated is a signal for a colour bar with 75% saturation, so chrominance to burst ratio is 2,2 : 1.

3. Nominal contrast is specified as the maximum contrast −3 dB and nominal saturation as the maximum saturation

−6 dB.

4. All frequency variations are referred to the 4,4 MHz carrier frequency.

5. For ± 400 Hz deviation of the oscillator frequency.

6. These signal amplitudes are determined by the a.c.c. circuit of the reference part.

7. When this level is exceeded, the amplitude of the output signal is reduced via a discharge of the capacitor at pin 7
(contrast control). The start of the peak white limiting action has a delay of one line period.

8. The variation of the black level depends directly on the gain of each channel during brightness control in the three
channels. As a consequence, the black levels at the outputs (for output levels above or below 3 V) can have a
difference which exceeds 200 mV. Because the amplitude and the black level change with brightness control have
a direct relationship, no discolouring can occur, caused by adjustment of contrast and brightness.

9. This difference occurs when the source impedance of the data signal inputs is 150Ω and the black level clamp pulse
duration is 4 µs (sandcastle pulse). A lower difference is obtained when the impedance is lower.

10. Cross-coupling is measured under the following condition. Input signals nominal, contrast and saturation such that
nominal output signals are obtained. The signals at the output at which no signal should be available must be
compared with the nominal output signal at that output.

11. The signal-to-noise ratio is specified as peak-to-peak signal with respect to r.m.s. noise.

< 0,4 V
> 0,9 V
< 3V
< 20 ns
< 35 µA

typ. 1,5 V

1 to 2 V

typ. 7,0 V
6, 5 to 7,5 V

typ. 0,4 µs

< 1mA
typ. 20 µA
< 2mA

September 1982 8

Philips Semiconductors Product specification

PAL decoder TDA3561A

Fig.2 Power derating curve. Fig.3 Contrast control voltage range.

Fig.4 Saturation control voltage range. Fig.5 Brightness control voltage range.

September 1982 9

Philips Semiconductors Product specification

PAL decoder TDA3561A

APPLICATION INFORMATION

Fig.6 Application circuit.

Adjustments (see Fig.6)

C1 8,8 MHz oscillator
L1 phase delay line = 10,7 µH
L2 nominal value = 10,7 µH
L3 4,4 MHz chrominance input filter = 10,7 µH=L1
L4 4,4 MHz trap in luminance signal line = 5,6 µH
L5 delay equalization = 66,1 µH
P1 amplitude of direct chroma signal
R1

R2

For a video input voltage of 1 V peak-to-peak: R3 can be omitted; R4 = 1 kΩ; R5 must be short-circuited; R6 = 1 kΩ.

September 1982 10

field blanking x field blanking amplitude 2,0 V to 6,5 V.

R1

---------------------­R1 R2+

Philips Semiconductors Product specification

PAL decoder TDA3561A

APPLICATION INFORMATION

The function is described against the corresponding pin
number.

1. + 12 V power supply

The circuit gives good operation in a supply voltage range
between 8 and 13,2 V provided that the supply voltage for
the controls is equal to the supply voltage for the
TDA3561A. All signal and control levels have a linear
dependency on the supply voltage. The current taken by
the device at 12 V is typically 85 mA. It is linearly
dependent on the supply voltage.

2. Control voltage for identification

This pin requires a detection capacitor of about 330 nF for
correct operation. The voltages available under various
signal conditions are given in the specification.

3. Chrominance input

The chroma signal must be a.c.-coupled to the input.
Its amplitude must be between 55 mV and 1100 mV
peak-to-peak (25 mV to 500 mV peak-to-peak burst
signal). All figures for the chroma signals are based on a
colour bar signal with 75% saturation, that is the
burst-to-chroma ratio of the input signal is 1 : 2,25.

4. Reference voltage A.C.C. detector

This pin must be decoupled by a capacitor of about 330
nF. The voltage at this pin is 4,9 V.

5. Control voltage A.C.C.

The A.C.C. is obtained by synchronous detection of the
burst signal followed by a peak detector. A good noise
immunity is obtained in this way and an increase of the
colour for weak input signals is prevented. The
recommended capacitor value at this pin is 2,2 µF.

6. Saturation control

The saturation control range is in excess of 50 dB.
The control voltage range is 2 to 4 V. Saturation control is
a linear function of the control voltage.

When the colour killer is active, the saturation control
voltage is reduced to a low level if the resistance of the
external saturation control network is sufficiently high.
Then the chroma amplifier supplies no signal to the
demodulator. Colour switch-on can be delayed by proper
choice of the time constant for the saturation control
setting circuit.

When the saturation control pin is connected to the power
supply the colour killer circuit is overruled so that the colour
signal is visible on the screen. In this way it is possible to
adjust the oscillator frequency without using a frequency
counter (see also pins 25 and 26).

7. Contrast control

The contrast control range is 20 dB for a control voltage
change from + 2 to + 4 V. Contrast control is a linear
function of the control voltage. The output signal is
suppressed when the control voltage is 1 V or less. If one
or more output signals surpasses the level of 9 V the peak
white limiter circuit becomes active and reduces the output
signals via the contrast control by discharging C2 via an
internal current sink.

8. Sandcastle and field blanking input

The output signals are blanked if the amplitude of the input
pulse is between 2 and 6,5 V. The burst gate and clamping
circuits are activated if the input pulse exceeds a level of
7,5 V.
The higher part of the sandcastle pulse should start just
after the sync pulse to prevent clamping of video signal on
the sync pulse. The width should be about 4 µs for proper
A.C.C. operation.

9. Video-data switching

The insertion circuit is activated by means of this input by
an input pulse between 1 V and 2 V. In that condition, the
internal RGB signals are switched off and the inserted
signals are supplied to the output amplifiers. If only normal
operation is wanted this pin should be connected to the
negative supply. The switching times are very short
(< 20 ns) to avoid coloured edges of the inserted signals
on the screen.

10. Luminance signal input

The input signal should have a peak-to-peak amplitude of
0,45 V (peak white to sync) to obtain a black-white output
signal to 5 V at nominal contrast. It must be a.c.-coupled to
the input by a capacitor of about 22 nF. The signal is
clamped at the input to an internal reference voltage.
A 1 kΩ luminance delay line can be applied because the
luminance input impedance is made very high.
Consequently the charging and discharging currents of the
coupling capacitor are very small and do not influence the
signal level at the input noticeably. Additionally the
coupling capacitor value may be small.

September 1982 11

Philips Semiconductors Product specification

PAL decoder TDA3561A

11. Brightness control

The black level of the RGB outputs can be set by the
voltage on this pin (see Fig.5). The black level can be set
higher than 4 V however the available output signal
amplitude is reduced (see pin 7). Brightness control also
operates on the black level of the inserted signals.

12, 14, 16. RGB outputs

The output circuits for red, green and blue are identical.
Output signals are 5,25 V (R, G and B) at nominal input
signals and control settings. The black levels of the three
outputs have the same value. The blanking level at the
outputs is 2,1 V. The peak white level is limited to 9,3 V.
When this level exceeded the output signal amplitude is
reduced via the contrast control (see pin 7).

13, 15, 17. Inputs for external RGB signals

The external signals must be a.c.-coupled to the inputs via
a coupling capacitor of about 100 nF. Source impedance
should not exceed 150 Ω. The input signal required for
a 5 V peak-to-peak output signal is 1 V peak-to-peak.
At the RGB outputs the black level of the inserted signal is
identical to that of normal RGB signals. When these inputs
are not used the coupling capacitors have to be connected
to the negative supply.

25, 26. Reference oscillator

The frequency of the oscillator is adjusted by the variable
capacitor C1. For frequency adjustment interconnect pin
21 and pin 22. The frequency can be measured by
connecting a suitable frequency counter to pin 25.

28. Output of the chroma amplifier

Both burst and chroma signals are available at the output.
The burst-to-chroma ratio at the output is identical to that
at the input for nominal control settings. The burst signal is
not affected by the controls. The amplitude of the input
signal to the demodulator is kept constant by the A.C.C.
Therefore the output signal at pin 28 will depend on the
signal loss in the delay line.

18, 19, 20. Black level clamp capacitors

The black level clamp capacitors for the three channels are
connected to these pins. The value of each capacitor
should be about 100 nF.

21, 22. Inputs (B-Y) and (R-Y) demodulators

The input signal is automatically fixed to the required level
by means of the burst phase detector and A.C.C.
generator which are connected to pin 21 and pin 22. As the
burst (applied differentially to those pins) is kept constant
by the A.C.C., the colour difference signals automatically
have the correct value.

23, 24. Burst phase detector outputs

At these pins the output of the burst phase detector is
filtered and controls the reference oscillator. An adequate
catching range is obtained with the time constants given in
the application circuit (see Fig.6).

September 1982 12

Philips Semiconductors Product specification

PAL decoder TDA3561A

PACKAGE OUTLINE

handbook, full pagewidth

DIP28: plastic dual in-line package; 28 leads (600 mil)

SOT117-1

seating plane

L

Z

28

1

pin 1 index

D

A

2

A

A

1

e

b

w M

b

1

15

E

14

c

M

(e )

M

E

1

H

0 5 10 mm

scale

DIMENSIONS (inch dimensions are derived from the original mm dimensions)

A

A

A

UNIT

inches

Note

1. Plastic or metal protrusions of 0.25 mm maximum per side are not included.

max.

mm

OUTLINE
VERSION

SOT117-1

1 2

min.

max.

1.7

1.3

0.066

0.051

IEC JEDEC EIAJ

051G05 MO-015AH

b

b

1

0.53

0.38

0.020

0.014

0.32

0.23

0.013

0.009

REFERENCES

cD E weM

(1) (1)

36.0

35.0

1.41

1.34

September 1982 13

14.1

13.7

0.56

0.54

(1)

92-11-17
95-01-14

Z

max.

1.75.1 0.51 4.0

0.0670.20 0.020 0.16

L

3.9

3.4

EUROPEAN

PROJECTION

M

15.80

15.24

0.62

0.60

H

E

17.15

15.90

0.68

0.63

0.252.54 15.24

0.010.10 0.60

ISSUE DATE

e

1

0.15

0.13

Philips Semiconductors Product specification

PAL decoder TDA3561A

SOLDERING
Introduction

There is no soldering method that is ideal for all IC packages. Wave soldering is often preferred when through-hole and
surface mounted components are mixed on one printed-circuit board. However, wave soldering is not always suitable for
surface mounted ICs, or for printed-circuits with high population densities. In these situations reflow soldering is often
used.

This text gives a very brief insight to a complex technology. A more in-depth account of soldering ICs can be found in our

“IC Package Databook”

Soldering by dipping or by wave

The maximum permissible temperature of the solder is 260 °C; solder at this temperature must not be in contact with the
joint for more than 5 seconds. The total contact time of successive solder waves must not exceed 5 seconds.

The device may be mounted up to the seating plane, but the temperature of the plastic body must not exceed the
specified maximum storage temperature (T
be necessary immediately after soldering to keep the temperature within the permissible limit.

(order code 9398 652 90011).

). If the printed-circuit board has been pre-heated, forced cooling may

stg max

Repairing soldered joints

Apply a low voltage soldering iron (less than 24 V) to the lead(s) of the package, below the seating plane or not more
than 2 mm above it. If the temperature of the soldering iron bit is less than 300 °C it may remain in contact for up to
10 seconds. If the bit temperature is between 300 and 400 °C, contact may be up to 5 seconds.

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.

September 1982 14