STMICROELECTRONICS TEA2164

TEA2164
SWITCH MODE POWER SUPPLY PRIMARY CIRCUIT
.
.
.
..
..
POSITIVE AND NEGATIVE OUTPUT CURRENT UP TO 1.2A AND – 1.7A
A TWO LEVEL COLLECTOR CURRENT LIMITATION
COMPLETE TURN OFF AFTER LONG DURATION OVERLOADS
UNDER AND OVER VOLTAGE LOCK-OUT
SOFT START BY PROGRESSIVE CURRENT
LIMITATION
DOUBLE PULSE SUPPRESSION
BURST MODE OPERATION UNDER STANDBY CONDITIONS
DESCRIPTION
In a master slave architecture, the TEA2164 control
IC achieves the slave function. Primarily designed
for TV receivers and monitors applications, this
circuit provides an easy synchronization and smart
solution for low power stand by operation.
Located at the primary side the TEA2164 Control
IC ensures :
- the power supply start-up
- the power supply control under stand-by conditions
- the process of the regulation signals sent by the
master circuit located at the secondary side
- directbase drive of the bipolar switching transistor
- the protection of the transistor and the power
supply under abnormal conditions.
For more details, refer to application note AN409.
POWERDIP16
(Plastic Package)
ORDER CODE : TEA2164
PIN CONNECTIONS
GROUND
1
16
V CC SUPPLY VOLTAGE
I COPY
2
15
OUTPUT STAGE POSITIVE SUPPLY VOLTAGE
LONG CAPACITOR OVERLOAD CAPACITO R
3
14
OUTPUT (BASE CURRENT)
SUBSTRATE
4
13
SUBSTRATE
SUBSTRATE
5
12
SUBSTRATE
PULSE INPUT
6
11
IC
OSCILLATOR TIMING RESISTOR
7
10
LOW FREQUENCY OSCILLATOR CAPACITOR
OSCILLATOR TIMING CAPACITOR
8
9
December 1992
SENSE
2164-01.EPS
(max.)
FEEDBACK INPUT IS BURST MODE
1/15
TEA2164
2164-02.EPS
BLOCK DIAGRAM
2/15
TEA2164
2164-03.EPS
Figure 1 : Simplified Application Diagram
Symbol
VCC
Parameter
Positive Power Supply V16-V1
Value
Unit
18
V
V+
Positive Power Supply of the Output Stage V15-V1
18
V
V–
Negative Power Supply V4, 5, 12, 13-V1
–5
V
Total Power Supply V16-V4, 5, 12, 13 or V15-V4, 5, 12, 13
20
V
Iout+
Positive Output Current
1.5
A
Iout–
Negative Output Current
VCC - V–
V+ - V–
Tj
Tstag
Operating Junction Temperature
Storage Temperature Range
2
A
150
°C
– 40, + 150
°C
Value
Unit
11
°C/W
2164-01.TBL
ABSOLUTE MAXIMUM RATINGS
Symbol
Rth(j-c)
Parameter
Junction Case Thermal Resistance
2164-04.EPS
MAXIMUM POWER DISSIPATION
3/15
2164-02.TBL
THERMAL DATA
TEA2164
RECOMMANDED OPERATING CONDITIONS
Positive Power Supply
V–
VCC – V–
Iout+
Iout–
Fsw
Ro
Negative Power Supply (absolute value) (note 1)
Total Power Supply
Positive Output Current
Negative Output Current
Switching Frequency
Oscillator Resistor Range
Co
C1
Oscillator Capacitor Range
Starting Oscillator Capacitor Range
C2
Repetitive Overload Protection Capacitor
1
22
Vin
Toper
Parameter
Min.
Typ.
10
Max.
14
Unit
V
V
V
A
A
khz
30
5
18
1.2
1.7
50
150
470
0.1
2700
4.7
0
Input Pulses Amplitude (peak) (derivated pulses - time constant = 1 µs)
Operating Ambiant Temperature
kΩ
pF
µF
0.5
1
µF
V
– 20
70
°C
2164-03.TBL
Symbol
VCC
V CC-
TEA2164
4
V CC-
IB > 0
13
5
12
14
1
13
TEA2164
4
IB < 0
14
5
IB
I
1
capacitive
coupling
2164-05.EPS
12
IB < 0
IB < 0
ELECTRICAL OPERATING CHARACTERISTICS
Tamb = 25oC, VCC = 10V, VCC- = 0V, potentials referenced to ground (Pin 1)
(unless otherwise specified)
Symbol
Parameter
Min.
Typ.
Max.
Unit
8
5
2
9
6.2
2.8
9.6
7.4
3.5
V
V
V
14.8
0.5
15.5
0.8
16.2
1.5
V
mA
POWER SUPPLY
VCC (start)
VCC (stop)
∆VCC
Vccmax
Iccstart
Starting Voltage (VCC increasing)
Stopping Voltage (VCC decreasing)
Hysteresis (VCC start – VCC stop)
Overvoltage Lock-out
Starting Positive Supply Current
CURRENT LIMITATION AND PROTECTION (pin 11)
VCM1
Pulse by Pulse Current Limitation Threshold
720
840
970
mV
VCM2
Current Monitoring 2nd Threshold
1200
300
1350
500
1500
700
mV
mV
700
– 20
2.4
10
900
50
3
20
1100
130
3.6
30
mV
mV
V
µA
50
80
110
µA
19.3
21
22.7
60
70
85
µs
%
∆VCM
∆VCM = VCM2 – VCM1
VCM3
VCM3-VCM1
VC2
I3 disch
I3 ch.
Repetitive Overcurrent Threshold (pin 11)
(VCM3-VCM1)
Lock-out Voltage on Pin 3
Capacitor C2 Discharge Current (synchronized mode)
Capacitor C2 Charge Current
OSCILLATOR, MAX DUTY CYCLE, SYNCHRONIZATION
To
Ton(max)
4/15
Oscillator Initial Accuracy RT = 50 K, CT = 1 nF
Maximum Duty Cycle (Tsyn = 1.05 To)
2164-04.TBL
REPETITIV E OVERCURRENT PROTECTION
TEA2164
ELECTRICAL OPERATING CHARACTERISTICS (continued)
Symbol
Parameter
Min.
Typ.
Max.
Unit
OSCILLATOR, MAX DUTY CYCLE, SYNCHRONIZATION (continued)
Tsyn
TO
Synchronization Window
1.0
1.5
I14/I 2
IBON
Ic Copy Current Gain
Base Current Starting Pulse
1000
300
mA
13
%
VERY LOW FREQUENCY OSCILLATOR
Burst Duty Cycle
I. FIELD OF APPLICATION
The TEA2164 control circuit has been designed
primarily for discontinuous mode flyback built with
a master-slave architecture, whatever the field of
application.
But due to its capability to synchronize the transistor switching-off with an external signal (line flyback) and due to an adaptedburst-mode operation
for a low power stand-by operation, the TEA2164
offers a smart solution for monitors and TV sets
applications.
Power supply main features :
- maximum output power 140W (transistor forced
gain : 3.5)
Figure 2 : Master Slave Power Supply Architecture
2164-05.TBL
OUTPUT STAGE
- stand-by mode output power (1W ≤ Psb ≤ 6W ;
efficiency > 50%)
- operating frequency up to 50kHz
- power-switch : bipolar transistor
Adapted master-circuit :
Monitor application
→
Standard TV application →
Digital TV application
→
TEA5170
TEA2028B
TEA2029C
TEA2128
TEA5170
TEA5170
(TEA2028B, TEA2029C and TEA2128 are deflection processors with built-in PWM generator).
AUDIO
OUTPUT
STAGE
Muting
Control
R
P1
MAINS
INPUT
Synchronization
SCANNING
DEVICE
Remote
Stand-by
P2
C
VOLTAGE
REGULATOR
Remote
Stand-by
V CC
TEA2164
µP
TEA5170
V CC
INFRA-RED
RECEIVER
PWM
Small signal primary ground
Power primary ground
Secondary ground (isolated from mains)
2164-06.EPS
P1 : Output voltage adjustement in normal mode
P2 : Output voltage adjustement in stand-by
5/15
TEA2164
II. GENERAL DESCRIPTION
In a master slave architecture, the TEA2164 Control IC, located at the primary side of an off line
power supply achieves the slave function ; whereas
the master circuit is located at the secondary side.
The link between both circuits is realized by a small
pulse transformer (Figure 3).
2164-07.EPS
Figure 3 : System Description Waveforms
6/15
TEA2164
In the operation of the master-slave architecture,
four majors cases must be considered :
- normal operating
- stand-by mode
- power supply start-up
- abnormal conditions : off load, short circuit, ...
II.1. Normal Operating (master slave mode)
In this configuration, the master circuit generates a
pulse width modulatedsignal issued from the monitoring of the output voltage which needs the best
accuracy (in TV applications : the horizontal deflection stage supplyvoltage). The master circuit power
supply can be supplied by another output.
The PWM signal are sent towards the primary side
through small differentiating transformer. For the
TEA2164 positive pulses are transistor switchingon commands ; and negative pulses are transistor
switching-off commands (Figure 4). In this configuration, only by synchronizing the master oscillator,
the switching transistor may be synchronized with
an external signal.
II.2. Stand-by Mode
In this configuration the master circuit no longer
sends PWM signals, the structure is not synchronized ; and the TEA2164 operates in burst mode.
The average power consumption at the secondary
side may be very low 1W ≤ P ≤ 6W (as it is
consumed in TV set during stand by).
By action on the maximum duty cycle control, a
primary loop maintains a semi-regulation of the
output voltages. Voltage on feed-back is applied on
Pin 9.
Burst period is externally programmed by capacitor
C1.
II.3. Power Supply Start-up
After the mains have been switched-on, the VCC
storage capacitor of the TEA2164 is charged
through a high value resistor connected to the
rectified high voltage. When Vcc reaches VCC start
threshold (9V typ), the TEA2164 starts operating in
burst mode. Since available output power is low in
burst mode the output power consumption must
remain low before complete setting-up of output
voltage. In TV application it can be achieved by
maintaining the TV in stand-by mode during startup (Figure 6).
Figure 4 : Master Slave Mode Waveforms
Sync.
Pulses
Synchro.
PWM
Signal
MASTER
CIRCUIT
Pulse
Input
Base
Current
2164-08.EPS
SLAVE
CIRCUIT
7/15
TEA2164
2164-09.EPS
Figure 5 : Burst Mode Waveforms
Figure 6 : Power Supply Start-up
Tstart-up = Tch + T1
T1 : necessary time for voltage setting-up
d) Abnormal conditions : safety functions
Overvoltage Protection
When VCC exceeds VCC max, an internal flip-flop
stops output conduction signals. The circuit will
start again after the capacitor C1 discharge ; it
means : after loss of synchronization or after Vcc
stop crossing (Figure 7).
In flyback converters, this function protects the
power supply against output voltage runaway.
Under Voltage Lock-out
The TEA2164 control circuit stops operating when
VCC goes under VCC stop.
8/15
2164-10.EPS
Tch ≈ 1s (typ)
T1 ≈ 0.3s (typ)
Power Limitation, Current Protection, Long
Duration Overload Protection
- Output power limitation : by a pulse by pulse
collector current limitation the TEA2164 limits the
maximum output power. VCM1 is the corresponding voltage threshold, its detection is memorized
up to the next period.
- Current protection (transistor protection)
Under particular conditions a hard overload or
short circuit may induce a flux runaway in spite of
the current limitation (VCM1).
The TEA2164 control circuit features a second
current protection, VCM2. When this threshold is
reached an internal flip-flop memorizes it and
TEA2164
output conduction signals are inhibited. The circuit will send base drives again after capacitor C1
discharge (Figure 7).
- Long duration overload protection : (Figure 8)
An overload is detected when the sense-voltage
on Pin 11 reaches VCM3 before a negative pulse
has been applied to Pin 6. In this case the capacitor C2 (connected to Pin 3) is charged with I3 ch
up to the end of the period and discharged with I3
disch until a next VCM3 detector. By this way in
case of long duration overload, the capacitor
keeps charging at each period and its voltage
encreases gradually. When the voltage on Pin 3
exceeds VC2, the TEA2164 control circuit stops
sending base drives and memorizes this event.
No restart is allowed as long as Vpin 3 is higher
than VC2 and VCC higher than 4.8V.
* Remark :
- The harder is the overload the faster is the protection
- The capacitor keeps charging between two burst
after VCM2 detection.
2164-11.EPS
Figure 7 : Overvoltages Lock-out
2164-11.EPS
Figure 8 : Long Duration Overload Monitoring Circuit
2164-13.EPS
Figure 9 : Long Duration Overload Detection
9/15
TEA2164
2164-14.EPS
Figure 10 : Repetitive Over-current Protection
III. SWITCHING OSCILLATOR AND SYNCHRONIZATION
III.1. Switching oscillator
When the TEA2164 control circuit operates in burst
mode, the switching frequency is fixed by the free
frequency oscillator. The period is determined by
two external components CO and RO.
III.2. Synchronization
When the master-circuit starts to send pulses both
oscillators are not synchonuous. In order to avoid
any erratic conduction of the power transistor, the
first synchronization pulse will arrive simultanously
with the sawtooth return of the TEA2164 oscillator.
To get synchronization the free frequency must be
higher than the synchronization frequency.
TO < Tsync. < 1.50 TO
2164-15.EPS
Figure 11 : Free Frequency Running
2164-16.EPS
Figure 12 : Synchronization Pulse Shaper and Synchronization
10/15
TEA2164
(1) NORMAL OPERATION
(2) NEGATIVE PULSE MISSING
∆T : synchronization window
Transistor turn-off is ensured by VCM1 current limi tation crossing or by an internal tON (max.) limitation set by a 2.5V threshold
2164-17.EPS / 2164-18.EPS
Operation after synchronization
(3) ERRATIC POSITIVE PULSES
(4) Fsynchro < 0.65 Fo
P1 and P2 are masked due to the synchronization window
Signal S1 triggers burst oscillator capacitor discharge.
The TEA2164 restarts in burst-mode
2164-19.EPS
Operation after synchronization
Cases (2) (3) (4) do not occur in normal operating.
IV - MAXIMUM DUTY CYCLE LIMITATION
Burst mode : The maximum duty cycle is controlled
by the voltage on Pin 9 (Figure 13).
Synchronized mode : Normally the maximum duty
cycle is set by the master circuit. Oowever the
maximum conducting time will never exceed the
value given by the comparison of the oscillator
wave-form with the 2.5V internal threshold.
V - OUTPUT STAGE
TEA2164 output stage has been designed to drive
switching bipolar transistor.
- Each base drive begins with a positive pulse IBON
that realizes an efficient transistor turn-on.
- After the starting pulse I BON, the base current is
proportional to the collector current. The current
gain is easily fixed by a resistor R (Figure 14).
- A fast and safe transistor turn-off is realized by a
fast positive base current cut-off and by applying
a negative base drive which draws stored carriers. A typical 0.7s delay prevents from cross-conduction of positive and negative output stages.
Remark : In order to reduce power dissipation on
the positive output stage with the low gain transistors, for high base currents the positive output stage
operates in saturated mode (Figure 15). This can
be achieved by using a resistor between VCC and
V+.
11/15
TEA2164
2164-20.EPS
Figure 13 : Maximum Duty Cycle Limitation
Figure 14 : Output Stage Architecture and Base Drive
IB
I BON
V
16
t
15
CURRENT
MIRROR
I Cmax
IB
14
IC
Virtual
Ground
t
RS
V
2
I COPY
4-5-12-13
IC
RB
IB
≅ GF
RS =
IC
RB
IC
GF =
VI - MONITOR APPLICATIONS
In most of monitor applications, the power supply
must start-up under full load conditions and the
stand -by mode is no longer useful.
IB
=
V CM1
I Cmax
1000 x R S
2164-21.EPS
V CC
The energy of the starting burst must be high
enough to ensure start-up, then the capacitor C1
must be higher in these applications than on TV
application (typ. : 1µF).
2164-22.EPS
Figure 15 : Power Supply Start-up and Normal Operation
12/15
13
12
10
5
4
470kΩ
300kΩ
1nF
3
2
2164-23.EPS
2 µH
10Ω
220µ F
100kΩ
(2W)
1N4444
14
16
100Ω
6
15
2 x 47µF
(385V)
6.8Ω
1
330
Ω
390
Ω
11
TEA2164
4.7µF
9
7
8
12kΩ
Primary Ground (connected to mains)
Secondary ground(isolated from mains)
2.2µF
1.2nF
110kΩ
2.2Ω
2.2Ω
0.27Ω
100Ω
47µF
3 x 1N404
BA157
BA157
220Ω
BU508A
2
1
7
9
6
470Ω
10µ F
BA159
2.2nF
4.7µF
V CC
470µF
1000µF
100µF
V CC
1N4148
24
20
7
22
19
18
17
15
16
100nF
VIDEO
INPUT
27
23
VCR
Switch
13V
2N1711
MUTE OUT
&
50/60Hz
IDENTIFICATION
8.2k Ω
AGC
PULSE
15kΩ
1.5nF
15nF
330Ω
5.6kΩ
1.8kΩ
220Ω
3.9kΩ
5.6kΩ
503
kHz
150pF
+25V
470kΩ
10kΩ
680Ω
27Ω
33kΩ
+135V / 0.6A
HorizontalPhase
Adjust
BY218
BY218
BY218
220Ω
VCC
22
21
19
20
13
22nF
100nF
3
OREGA
G.4173.04
3.3nF
220nF
4 x 1N4007
26
150kΩ
14
22nF
220
µF
V CC
8
25
1.5kΩ
11
28
21
10kΩ
5
3
1
2
6
4
10
100kΩ
220pF
SUPER
SANDCASTLE
LINE
OUTPUT
FLYBACK
12
9
1k Ω
220pF
SMPS
Output Voltage
Adjust
TEA2029C
13
3.32kΩ (1%)
100nF
1kΩ
1k Ω
220VAC
MAINS INPUT
4.7nF
820 Ω
220Ω
1kΩ
100nF
1nF
1kΩ
FramePhase
Adjust
220 Ω
6.8kΩ
33 Ω
ESM
740
82kΩ
220Ω
BA157
EHT
TRANSFORMER
3.3kΩ
3.3kΩ
47nF
LINE
YOKE
E/W
CORRECTION
2.2kΩ
220kΩ
470nF
2.7MΩ
820 Ω
1kΩ
390Ω
6.8kΩ
FUSE 1.6A
200V
+24V
4.7 Ω
Frame
Amplitude
Adjust
FRAME
YOKE
120mH
60Ω
0.47µF
500µH
LINE FLYBACK
+24V
+200V
TEA2164
COMPLETE APPLICATION DIAGRAM (SMPS + DEFLECTION) (with stand-by function)
13/15
14/15
6
8
7
2164-24.EPS
f : 32kHz
560
pF
2%
4
9
10
P OUT : 120W
100kΩ
1%
100nF
1nF
V IN = 220 V AC
12
1nF
1
16V
330
Ω
2
15
18Ω
2.2µF
1N4148
14
16
120kΩ
(2W)
5.6Ω
(1W)
4 x 1N4007
150µ F
(385V)
330
Ω
11
13
68kΩ
4.7µF
3
TEA2164
5
P2
22kΩ
20%
0.24Ω (1W)
47µF
BZX85C-3V0
220µF
25V
4.7Ω (2W) BA157
100Ω
BA159
SGSF344
7
9
6
3
21
22
17
14
19
20
13
Pulse
Transformer
2.7nF
1kV
470Ω
(8W)
G4453-02
270Ω
BY218-100
BY218-100
PLR811
BY218-600
10µF
16V
1000µF
(40V)
1000µF
(25V)
470µF
(25V)
100µF
(250V)
25V
3
2
6
100kΩ
7
8
2.2kΩ
6.8kΩ
150pF
47nF
Stand-by
Control
1N4148
1
5
75kΩ
TEA5170
4
560
pF
560
pF
BC550C
10kΩ
7.5V
100kΩ
P1
100kΩ
Sync.
Input
135V
TEA2164
STAND-ALONE 32kHz POWER SUPPLY ELECTRICAL DIAGRAM
TEA2164
I
b1
L
a1
PACKAGE MECHANICAL DATA
16 PINS - PLASTIC POWERDIP
b
B
e
E
Z
e3
D
9
1
8
a1
B
b
b1
D
E
e
e3
F
i
L
Z
Min.
0.51
0.85
Millimeters
Typ.
Max.
1.4
Min.
0.020
0.033
0.5
0.38
Inches
Typ.
Max.
0.055
0.020
0.5
20
0.015
8.8
2.54
17.78
0.020
0.787
0.346
0.100
0.700
7.1
5.1
3.3
DIP16PW.TBL
Dimensions
PMDIP16W.EPS
F
16
0.280
0.201
0.130
1.27
0.050
Information furnished is believed to be accurate and reliable. However, SGS-THOMSON Microelectronics assumes no responsibility
for the consequences of use of such information nor for any infringement of patents or other rights of third parties which may result
from its use. No licence is granted by implication or otherwise under any patent or patent rights of SGS-THOMSON Microelectronics.
Specifications mentioned in this publication are subject to change without notice. This publication supersedes and replaces all
information previously supplied. SGS-THOMSON Microelectronics products are not authorized for use as critical components in life
support devices or systems without express written approval of SGS-THOMSON Microelectronics.
 1994 SGS-THOMSON Microelectronics - All Rights Reserved
Purchase of I2C Components of SGS-THOMSON Microelectronics, conveys a license under the Philips
I2C Patent. Rights to use these components in a I2C system, is granted provided that the system conforms to
the I2C Standard Specifications as defined by Philips.
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15/15