Philips TEA152x Technical data
INTEGRATED CIRCUITS
DATA SH EET
TEA152x family
TM
STARplug
Product specification
File under Integrated Circuits, IC11
2000 Sep 08
Philips Semiconductors Product specification
STARplug
FEATURES
• Designed for general purpose supplies up to 50 W
• Integrated power switch:
– TEA1520: 48 Ω; 650 V
– TEA1521: 24 Ω; 650 V
– TEA1522: 12 Ω; 650 V
– TEA1523: 6.5 Ω; 650 V
– TEA1524: 3.4 Ω; 650 V.
• Operates from universal AC mains supplies
(80 to 276 V)
• Adjustable frequency for flexible design
• RC oscillator for load insensitive regulation loop
constant
• Valley switching for minimum switch-on loss (not
implemented in TEA152xAJM versions)
• Frequency reduction at low power output makes low
standby power possible (<100 mW)
• Adjustable overcurrent protection
• Under voltage protection
• Temperature protection
• Short circuit winding protection
• Simple application with both primary and secondary
(opto) feedback
• Available in 8-pin DIP, 14-pin SO and 9-pin DBS
packages.
GENERAL DESCRIPTION
The TEA152x family is a Switched Mode Power
Supply (SMPS) controller IC that operates directly from
the rectified universal mains.Itis implemented in the high
voltage EZ-HV SOI process, combined with a low voltage
BICMOS process. The device includes a high voltage
power switch and a circuit for start-up directly from the
rectified mains voltage.
TM
TEA152x family
A dedicated circuit for valley switching is built in (not
implemented in TEA152xAJM versions), which makes a
very efficient slim-line electronic powerplug concept
possible.
Initsmostbasicversionofapplication,theTEA152xfamily
acts as a voltage source. Here, no additional secondary
electronics are required. A combined voltage and current
source can be realized with minimum costs for external
components. Implementation of the TEA152x family
renders an efficient and low cost power supply system.
Table 1 Available type numbers
R
DS(on)
48 Ω TEA1520P TEA1520T −
24 Ω TEA1521P TEA1521T −
12 Ω TEA1522P TEA1522T TEA1522AJM
6.5 Ω TEA1523P TEA1523T TEA1523AJM
3.4 Ω TEA1524P − TEA1524AJM
APPLICATIONS
Typical application areas for the STARplug
• Chargers
• Adapters
• STB (Set Top Box)
• DVD
• CD(R)
• TV/monitor standby supplies
• PC peripherals
• Microcontroller supplies in home applications and small
portable equipment, etc.
DIP8 SO14 DBS9P
TM
are:
2000 Sep 08 2
Philips Semiconductors Product specification
STARplug
TM
TEA152x family
QUICK REFERENCE DATA
SYMBOL PARAMETER CONDITIONS MIN. TYP. MAX. UNIT
V
drain(max)
maximum voltage at the DRAIN
Tj>0°C −−650 V
pin
R
DS(on)
V
CC(max)
f
osc
I
drain
drain-source on-state resistance
of TEA1520
drain-source on-state resistance
of TEA1521
drain-source on-state resistance
of TEA1522
drain-source on-state resistance
of TEA1523
drain-source on-state resistance
of TEA1524
maximum supply voltage −−40 V
frequency range of oscillator 10 100 200 kHz
supply current drawn from DRAIN
Tj=25°C; I
T
= 100 °C; I
j
T
=25°C; I
j
= 100 °C; I
T
j
T
=25°C; I
j
T
= 100 °C; I
j
=25°C; I
T
j
T
= 100 °C; I
j
T
=25°C; I
j
T
= 100 °C; I
j
= −0.06 A − 48 55.2 Ω
source
= −0.06 A − 68 78.2 Ω
source
= −0.125 A − 24 27.6 Ω
source
= −0.125 A − 34 39.1 Ω
source
= −0.25 A − 12 13.8 Ω
source
= −0.25 A − 17 19.6 Ω
source
= −0.5 A − 6.5 7.5 Ω
source
= −0.5 A − 9.0 10.0 Ω
source
= −1.0 A − 3.4 3.9 Ω
source
= −1.0 A − 4.8 5.5 Ω
source
no auxiliary supply − 1.5 − mA
pin
T
amb
ambient temperature −20 − +85 °C
ORDERING INFORMATION
TYPE
NUMBER
NAME DESCRIPTION VERSION
PACKAGE
TEA152xP DIP8 plastic dual in-line package; 8 leads (300 mil) SOT97-1
TEA152xT SO14 plastic small outline package; 14 leads; body width 3.9 mm SOT108-1
TEA152xAJM DBS9P plastic DIL-bent-SIL power package; 9 leads (lead length
SOT523-1
12/11 mm); exposed die pad
2000 Sep 08 3
Philips Semiconductors Product specification
STARplug
BLOCK DIAGRAM
handbook, full pagewidth
CC
1
2
V
GND
TM
TEA152x
SUPPLY
LOGIC
VALLEY
TEA152x family
8
7
100 mV
DRAIN
n.c.
RC
REG
3
4
stop
OSCILLATOR
low freq
F
1.8 U
2.5 V
10x
PWM
THERMAL
SHUTDOWN
POWER-UP
RESET
PROTECTION
LOGIC
overcurrent
short circuit winding
blank
0.5 V
0.75 V
MGT419
6
5
SOURCE
AUX
The valley switching circuit is not implemented in the TEA152xAJM versions.
The pinning shown in this diagram is the pinning of the DIP8 package. For the pinning of
the other packages, see the relevant pinning tables and pin configurations.
Fig.1 Block diagram.
2000 Sep 08 4
Philips Semiconductors Product specification
STARplug
TM
PINNING
PIN
SYMBOL
DESCRIPTION
TEA152xP TEA152xT TEA152xAJM
V
CC
GND
1 1 1 supply voltage
2
2, 3, 4, 5,
9 and 10
2
ground
RC 3 6 3 frequency setting
REG 4 7 4 regulation input
SGND
AUX
−−5
586
signal ground; connected to exposed die pad; must be
connected to pin 2
input for voltage from auxiliary winding for timing
(demagnetization)
SOURCE 6 11 7 source of internal MOS switch
n.c. 7 12 and 13 8 not connected
DRAIN
8149
drain of internal MOS switch; input for start-up current
and valley sensing
TEA152x family
handbook, halfpage
Fig.2 Pin configuration of TEA152xP.
handbook, halfpage
V
CC
RC
REG
V
CC
GND
GND
GND
GND
RC
REG
1
2
TEA152xP
3
4
1
2
3
4
TEA152xT
5
6
7
MGT420
MGT421
8
7
6
5
14
13
12
11
10
9
8
DRAIN
n.c.GND
SOURCE
AUX
DRAIN
n.c.
n.c.
SOURCE
GND
GND
AUX
handbook, halfpage
SOURCE
Fig.4 Pin configuration of TEA152xAJM.
V
CC
GND
RC
REG
SGND
AUX
n.c.
DRAIN
1
2
3
4
5
TEA152xAJM
6
7
8
9
MGT422
Fig.3 Pin configuration of TEA152xT.
2000 Sep 08 5
Philips Semiconductors Product specification
STARplug
TM
FUNCTIONAL DESCRIPTION
The TEA152x family is the heart of a compact flyback
converter, with the IC placed at the primary side. The
auxiliary winding of the transformer can be used for
indirect feedback to control the isolated output. This
additional winding also powers the IC. A more accurate
control of the output voltage and/or current can be
implemented with an additional secondary sensing circuit
and optocoupler feedback.
The TEA152x family uses voltage mode control. The
frequency is determined by the maximum transformer
demagnetizing time and the time of the oscillator. In the
first case, the converter operates in the Self Oscillating
Power Supply (SOPS) mode. In the latter case, it operates
at a constant frequency, which can be adjusted with
external components RRC and CRC. This mode is called
Pulse Width Modulation (PWM). Furthermore, a primary
stroke is started only in a valley of the secondary ringing.
This valley switching principle minimizes capacitive
switch-on losses.
Start-up and under voltage lock-out
Initially, the IC is self supplying from the rectified mains
voltage. The IC starts switching as soon as the voltage on
pin VCC passes the V
level. The supply is taken
CC(start)
over by the auxiliary winding of the transformer as soon as
VCCis high enough and the supply from the line is stopped
for high efficiency operation.
Whenforsomereasontheauxiliarysupplyisnotsufficient,
the high voltage supply also supplies the IC. As soon as
the voltage on pin VCCdrops below the V
CC(stop)
level, the
IC stops switching and restarts from the rectified mains
voltage.
Oscillator
The frequency of the oscillator is set by the external
resistor and capacitor on pin RC. The external capacitor is
charged rapidly to the V
new primary stroke, it discharges to the V
level and, starting from a
RC(max)
RC(min)
level.
Because the discharge is exponential, the relative
sensitivity of the duty factor to the regulationvoltage at low
duty factor is almost equal to the sensitivity at high duty
factors. This results in a more constant gain over the duty
factor range compared to PWM systems with a linear
sawtooth oscillator. Stable operation at low duty factors is
easily realized. For high efficiency, the frequency is
reduced as soon as the duty factor drops below a certain
value. This is accomplished by increasing the oscillator
charge time.
TEA152x family
Duty factor control
The duty factor is controlled by the internal regulation
voltage and the oscillator signal on pin RC. The internal
regulation voltage is equal to the external regulation
voltage (minus 2.5 V) multiplied by the gain of the error
amplifier (typical 20 dB (10 ×)).
Valley switching (not implemented in TEA152xAJM versions)
A new cycle is started when the primary switch is switched
on (see Fig.5). After a certain time (determined by the
oscillator voltage RC and the internal regulation level), the
switch is turned off and the secondary stroke starts. The
internal regulation level is determined by the voltage on
pin REG. After the secondary stroke, the drain voltage
shows an oscillation with a frequency of approximately
---------------------------------------------------2 π× LpCp×()×()
where L
parasitic capacitance on the drain node.
As soon as the oscillator voltage is high again and the
secondary stroke has ended, the circuit waits for a low
drain voltage before starting a new primary stroke.
Figure 5 shows the drain voltage together with the valley
signal, the signal indicating the secondary stroke and the
RC voltage.
The primary stroke starts some time before the actual
valley at low ringing frequencies, and some time after the
actual valley at high ringing frequencies. Figure 6 shows a
typical curve for a reflected output voltage N × V
This voltage is the output voltage Vo (see Fig.7)
transferred to the primary side of the transformer with the
factor N (determined by the turns ratio of the transformer).
Figure 6 shows that the system switches exactly at
minimum drain voltage for ringing frequencies of 480 kHz,
thus reducing the switch-on losses to a minimum.
At 200 kHz,the next primary stroke is started at 33°before
the valley. The switch-on losses are still reduced
significantly.
Demagnetization
Thesystemoperatesindiscontinuousconductionmodeall
the time. As long as the secondary stroke has not ended,
the oscillator will not start a new primarystroke. During the
first t
suppressed. This suppression may be necessary in
applications where the transformer has a large leakage
inductance and at low output voltages.
1
is the primary self inductance and Cp is the
p
seconds, demagnetization recognition is
suppr
of 80 V.
o
2000 Sep 08 6
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