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TEA1623P-TEA1623PH
STARplug switched mode power supply controller IC
1. General descriptionThe TEA1623 is a Switched Mode Power Supply (SMPS) controller IC that operates
directly from rectified universal mains. It is 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. A dedicated circuit for valley switching is built in, which makes a
very efficient slim-line electronic power-plug concept possible.
In its most basic version of application, the TEA1623 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 TEA1623
renders an efficient and low cost power supply system.
2. Features and benefits Designed for general purpose power supplies Integrated power switch: 6.5 Ω and 650V Operates from universal AC mains supplies: 80 V to 276V Adjustable frequency for flexible design RC oscillator for stable output regulation Valley switching for minimum switch-on loss Frequency reduction at low power output for low standby power: < 100 mW Adjustable OverCurrent Protection (OCP) UnderVoltage Protection (UVP) Temperature protection Short-winding protection Safe restart mode for system fault conditions Simple application with both primary and secondary (opto) feedback Available in 8-pin and 16-pin DIP packages.
3. Applications Adapters Set-Top Box (STB) DVD VCD CD(R) PC Silverbox standby SMPS
TEA1623P; TEA1623PH
STARplug switched mode power supply controller IC
Rev. 3 — 30 August 2010 Product data sheet
NXP Semiconductors TEA1623P; TEA1623PH
STARplug switched mode power supply controller IC
4. Quick reference data
5. Ordering information
Table 1. Quick reference dataVCC(max) maximum supply voltage - - 40 V
VDRAIN(max) maximum DMOS power
transistor drain voltage >0°C - - 650 V
IDRAIN supply current drawn from
pin DRAIN
no auxiliary supply - 0.5 - mA
RDSon drain-source on-state
resistance
ISOURCE = −0.5A =25 °C- 6.5 7.5 Ω =100°C - 9.0 10.0 Ω
fosc oscillator frequency range 10 - 200 kHz
Table 2. Ordering informationTEA1623P DIP8 plastic dual in-line package; 8 leads (300 mil) SOT97-1
TEA1623PH DIP16 plastic dual in-line package; 16 leads (300 mil); long body SOT38-1
NXP Semiconductors TEA1623P; TEA1623PH
STARplug switched mode power supply controller IC
6. Block diagramNXP Semiconductors TEA1623P; TEA1623PH
STARplug switched mode power supply controller IC
7. Pinning information
7.1 Pinning
NXP Semiconductors TEA1623P; TEA1623PH
STARplug switched mode power supply controller IC
7.2 Pin description
8. Functional descriptionThe TEA1623 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 TEA1623 uses voltage mode control. The frequency is determined by the maximum
transformer demagnetizing time or the frequency 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.
8.1 Start-up and UnderVoltage LockOut (UVLO)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 VCC(start) level. The supply is taken over by the
auxiliary winding of the transformer as soon as VCC is high enough and the supply from
the line is stopped for high efficiency operation.
As soon as the voltage on pin VCC drops below the VCC(stop) level, the IC stops switching
and restarts from the rectified mains voltage.
8.2 OscillatorThe frequency of the oscillator is set by the external resistor and capacitor on pin RC. The
external capacitor is charged rapidly to the VRC(max) level and, starting from a new primary
stroke, it discharges to the VRC(min) level. Because the discharge is exponential, the
Table 3. Pin descriptionVCC 1 3 supply voltage
GND 2 4 ground 3 5 frequency setting
REG 4 6 regulation point
SGND - 8 signal ground; preferably connected
to pin GND
AUX 5 11 input for voltage from auxiliary
winding for timing (demagnetization)
SOURCE 6 12 source of internal MOS switch
n.c. 7 1, 2, 7, 9, 10, 13,
15, 16
not connected
DRAIN 8 14 drain of internal MOS switch; input for
start-up current and valley sensing
NXP Semiconductors TEA1623P; TEA1623PH
STARplug switched mode power supply controller ICrelative sensitivity of the duty factor to the regulation voltage 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.
To ensure that the capacitor can be charged within the charge time, the value of the
oscillator capacitor should be limited to approximately 1 nF.
8.3 Duty factor controlThe 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 (−2.5 V)
multiplied by the gain of the error amplifier (typical 20 dB or 10×).
The minimum duty factor of the switched mode power supply is 0 %. The maximum duty
factor is set to 75 % (typical value at 100 kHz oscillation frequency).
8.4 Valley switchingA new cycle is started at the primary stroke when the switch is switched on (see Figure 5).
After a certain time (determined by the RC oscillator voltage 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 , where:
Lp is the primary self inductance on the drain node.
Cp is the 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.
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 voltage N× Vo of 80 V. This voltage is the output voltage Vo
(see Figure 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.×-----------------------------
NXP Semiconductors TEA1623P; TEA1623PH
STARplug switched mode power supply controller IC
8.5 DemagnetizationThe system operates in discontinuous conduction mode all the time. As long as the
secondary stroke has not ended, the oscillator will not start a new primary stroke. During
the suppression time tsuppr, demagnetization recognition is suppressed. This suppression
may be necessary in applications where the transformer has a large leakage inductance
and at low output voltages.
NXP Semiconductors TEA1623P; TEA1623PH
STARplug switched mode power supply controller IC
8.6 Protection
8.6.1 Overcurrent protectionThe cycle-by-cycle peak drain current limit circuit uses the external source resistor RI (see
Figure 7) to measure the current. The circuit is activated after the leading edge blanking
time tleb. The protection circuit limits the source voltage to Vsource(max), and thus limits the
primary peak current.
8.6.2 Short-winding protectionThe short-winding protection circuit is also activated after the leading edge blanking time.
If the source voltage exceeds the short-winding protection voltage Vswp, the TEA1623
stops switching. Only a power-on reset will restart normal operation. The short-winding
protection also protects in case of a secondary diode short circuit.
8.6.3 OverTemperature Protection (OTP)An accurate temperature protection is provided in the TEA1623. When the junction
temperature exceeds the thermal shut-down temperature, the IC stops switching. During
thermal protection, the IC current is lowered to the start-up current. The IC continues
normal operation as soon as the overtemperature situation has disappeared.
8.6.4 OverVoltage Protection (OVP)Overvoltage protection can be achieved in the application by pulling pin REG above its
normal operation level, or by keeping the level of pin AUX above Vdemag. The current
primary stroke is terminated immediately and no new primary stroke is started until the
voltage on pin REG drops to its normal operation level. Pin REG has an internal clamp.
The current feed into pin REG must be limited.
8.7 Characteristics of the complete power-plug
8.7.1 InputThe input voltage range comprises the universal AC mains from 80 V to 276V.
8.7.2 AccuracyThe accuracy of the complete converter, functioning as a voltage source with primary
sensing, is approximately 8 % (mainly dependent on the transformer coupling). The
accuracy with secondary sensing is defined by the accuracy of the external components.
For safety requirements in case of optocoupler feedback loss, the primary sensing
remains active when an overvoltage circuit is connected.
8.7.3 EfficiencyAn efficiency of 75 % at maximum output power can be achieved for a complete converter
designed for universal mains.
8.7.4 RippleA minimum ripple is obtained in a system designed for a maximum duty factor of 50%
under normal operating conditions and a minimized dead time. The magnitude of the
ripple in the output voltage is determined by the frequency and duty factor of the
converter, the output current level, and the value and ESR of the output capacitor.
NXP Semiconductors TEA1623P; TEA1623PH
STARplug switched mode power supply controller IC
9. Limiting values[1] Pins VCC and RC are not allowed to be current driven.
[2] Pins REG and AUX are not allowed to be voltage driven.
[3] Human body model: equivalent to discharging a 100 pF capacitor through a 1.5 kΩ series resistor.
[4] Machine model: equivalent to discharging a 200 pF capacitor through a 0.75 μH coil and a 10 Ω series resistor.
10. Thermal characteristics[1] Thermal resistance Rth(j-a) can be lower when pin GND is connected to sufficient copper area on the printed-circuit board. See the
TEA152x application note for details.
Table 4. Limiting valuesIn accordance with the Absolute Maximum Rating System (IEC 60134).
VoltageVCC supply voltage continuous [1] −0.4 +40 V
VRC oscillator input voltage [1] −0.4 +3 V
VSOURCE DMOS power transistor source
voltage −0.4 +5 V
VDRAIN DMOS power transistor drain
voltage
Tj > 0 °C −0.4 +650 V
CurrentIREG regulation input current [2] -6 mA
IAUX auxiliary winding input current [2] −10 +5 mA
IRC oscillator capacitor charge current −3- mA
ISOURCE source current −2+2 A
IDRAIN drain current −2+2 A
GeneralPtot total power dissipation
TEA1623P; Tamb <45 °C- 1.0 W
TEA1623PH; Tamb <50 °C- 1.7 W
Tstg storage temperature −55 +150 °C junction temperature −20 +145 °C
VESD electrostatic discharge voltage human body model[3]
pin DRAIN −1500 +1500 V
all other pins −2000 +2000 V
machine model[4]
all pins −200 +200 V
Table 5. Thermal characteristicsRth(j-a) thermal resistance from junction to ambient in free air [1] -
TEA1623P 100 K/W
TEA1623PH 55 K/W
NXP Semiconductors TEA1623P; TEA1623PH
STARplug switched mode power supply controller IC
11. CharacteristicsTable 6. CharacteristicsTamb = 25 °C; no overtemperature; all voltages are measured with respect to ground; currents are positive when flowing into
the IC, unless otherwise specified.
SuppliesSupply on pin VCC
VCC(start) start voltage 9 9.5 10 V
VCC(stop) stop voltage undervoltage lockout 7.0 7.5 8.0 V
ICC(operate) operating supply current normal operation - 1.3 1.9 mA
ICC(startup) start-up supply current start-up - 180 400 μA
ICC(ch) charging current VDRAIN >60V
VCC =0V −650 −520 −390 μA
VCC =8.5V −375 −275 −175 μA
Supply on pin DRAIN
IDRAIN supply current drawn from pin
DRAIN
no auxiliary supply - 0.5 - mA
with auxiliary supply; VDRAIN >60V - 30 125 μA
PWM modeδmin minimum duty factor - 0 - %
δmax maximum duty factor fosc= 100 kHz - 75 - %
Self-oscillating power supply modeVdemag demagnetization recognition
voltage level 100 150 mV
tsuppr time of suppression of transformer
ringing at start of secondary stroke
1.0 1.5 2.0 μs
Oscillator: pin RCVRC(min) minimum voltage of RC oscillator
setting 75 90 mV
VRC(max) maximum voltage of RC oscillator
setting
2.4 2.5 2.6 V
tRC(ch) RC charging time - 1 - μs
fosc oscillator frequency range 10 - 200 kHz
Duty factor regulator: pin REGVREG input voltage on pin REG 2.4 2.5 2.6 V
GV(erroramp) voltage gain of error amplifier - 20 - dB
VREG(clamp) clamping voltage on pin REG IREG =6mA - - 7.5 V
Valley switching recognitiondV/dtvalley valley recognition −102 - +102 V/μs
fvalley ringing frequency for valley
switching×Vo= 100V 200 550 800 kHz
td(valley-on) delay from valley recognition to
switch-on 150 - ns
Output stage (FET)IL(drain) drain leakage current VDRAIN= 650V - - 125 μA