POWERINT TNY254G

TNY253/254/255
TinySwitch™ Family
Energy Efficient, Low Power Off-line Switchers
Product Highlights
Lowest Cost, Low Power Switcher Solution
• Lower cost than RCC, discrete PWM and other integrated/hybrid solutions
• Cost effective replacement for bulky linear adapters
• Lowest component count
• Simple ON/OFF control – no loop compensation devices
• No bias winding – simpler, lower cost transformer
• Allows simple RC type EMI filter for up to 2 W from
universal input or 4 W from 115 VAC input
Extremely Energy Efficient
• Consumes only 30/60 mW at 115/230 VAC with no load
• Meets Blue Angel, Energy Star, Energy 2000 and 200 mW
European cell phone requirements for standby
• Saves $1 to $4 per year in energy costs (at $0.12/kWHr)
compared to bulky linear adapters
• Ideal for cellular phone chargers, standby power supplies for
PC, TV and VCR, utility meters, and cordless phones.
High Performance at Low Cost
• High-voltage powered – ideal for charger applications
• Very high loop bandwidth provides excellent transient
response and fast turn on with practically no overshoot
• Current limit operation rejects line frequency ripple
• Glitch free output when input is removed
• Built-in current limit and thermal protection
• 44 kHz operation (TNY253/4) with snubber clamp reduces EMI and video noise in TVs and VCRs
• Operates with optocoupler or bias winding feedback
Description
The TinySwitch family uses a breakthrough design to provide
the lowest cost, high efficiency, off-line switcher solution in
the 0 to 10 W range. These devices integrate a 700 V power
MOSFET, oscillator, high-voltage switched current source,
current limit and thermal shutdown circuitry. They start-up
and run on power derived from the DRAIN voltage, eliminating the need for a transformer bias winding and the associated
circuitry. And yet, they consume only about 80 mW at no load,
from 265 VAC input. A simple ON/OFF control scheme also
eliminates the need for loop compensation.
+
Wide-Range
High-Voltage
DC Input
+
DC
Output
–
D
TinySwitch
EN
BP
S
–
PI-2178-022699
Figure 1. Typical Standby Application.
TinySwitch Selection Guide
Recommended Range
for Lowest System Cost*
ORDER
PART
NUMBER
PACKAGE
TNY253P
DIP-8
TNY253G
SMD-8
TNY254P
DIP-8
TNY254G
SMD-8
TNY255P
DIP-8
TNY255G
SMD-8
230 VAC or
115 VAC
w/Doubler
85-265
VAC
0-4 W
0-2 W
2-5 W
1-4 W
4-10 W
3.5-6.5 W
Table 1. *Please refer to the Key Application Considerations section
for details.
The TNY253 and TNY254 switch at 44 kHz to minimize EMI
and to allow a simple snubber clamp to limit DRAIN spike
voltage. At the same time, they allow use of low cost EE16 core
transformers to deliver up to 5 W. The TNY253 is identical to
TNY254 except for its lower current limit, which reduces output
short-circuit current for applications under 2.5 W. TNY255
uses higher switching rate of 130 kHz to deliver up to 10 W
from the same low cost EE16 core for applications such as PC
standby supply. An EE13 or EF13 core with safety spaced
bobbin can be used for applications under 2.5 W. Absence of
a bias winding eliminates the need for taping/margins in most
applications, when triple insulated wire is used for the secondary. This simplifies the transformer construction and reduces cost.
February 2012
TNY253/254/255
REGULATOR
5.8 V
BYPASS
DRAIN
UNDERVOLTAGE
OSCILLATOR
5.8 V
5.1 V
+
+
-
-
VI
LIMIT
CLOCK
50 μA
DCMAX
THERMAL
SHUTDOWN
S
Q
R
Q
LEADING
EDGE
BLANKING
1.5 V + VTH
SOURCE
ENABLE
PI-2197-061898
Figure 2. Functional Block Diagram.
Pin Functional Description
DRAIN (D) Pin:
Power MOSFET drain connection. Provides internal operating
current for both start-up and steady-state operation. BYPASS (BP) Pin:
Connection point for an external bypass capacitor for the internally generated 5.8 V supply. Bypass pin is not intended for
sourcing supply current to external circuitry.
ENABLE (EN) Pin:
The power MOSFET switching can be terminated by pulling
this pin low. The I-V characteristic of this pin is equivalent to
a voltage source of approximately 1.5 V with a source current
clamp of 50 µA.
SOURCE (S) Pin:
Power MOSFET source connection. Primary return.
TinySwitch Functional Description
TinySwitch is intended for low power off-line applications. It
combines a high-voltage power MOSFET switch with a power
supply controller in one device. Unlike a conventional PWM
(Pulse Width Modulator) controller, the TinySwitch uses a
simple ON/OFF control to regulate the output voltage.
The TinySwitch controller consists of an Oscillator, Enable
(Sense and Logic) circuit, 5.8 V Regulator, Undervoltage circuit,
2
Rev E
02/12
BYPASS 1
8
SOURCE
SOURCE 2
7
SOURCE
SOURCE 3
6
SOURCE
ENABLE 4
5
DRAIN
P Package (DIP-8)
G Package (SMD-8)
PI-2199-031501
Figure 3. Pin Configuration.
Hysteretic Over Temperature Protection, Current Limit circuit,
Leading Edge Blanking, and a 700 V power MOSFET. Figure
2 shows a functional block diagram with the most important
features.
Oscillator
The oscillator frequency is internally set at 44 kHz (130 kHz
for the TNY255). The two signals of interest are the Maximum Duty Cycle signal (DMAX) which runs at typically 67%
duty cycle and the Clock signal that indicates the beginning of
each cycle. When cycles are skipped (see below), the oscillator frequency doubles (except for TNY255 which remains at
130 kHz). This increases the sampling rate at the ENABLE
pin for faster loop response.
Enable (Sense and Logic)
The ENABLE pin circuit has a source follower input stage set
at 1.5 V. The input current is clamped by a current source set
at 50 µA with 10 µA hysteresis. The output of the enable sense
TNY253/254/255
circuit is sampled at the rising edge of the oscillator Clock
signal (at the beginning of each cycle). If it is high, then the
power MOSFET is turned on (enabled) for that cycle, otherwise
the power MOSFET remains in the off state (cycle skipped). Since the sampling is done only once at the beginning of each
cycle, any subsequent changes at the ENABLE pin during the
cycle are ignored.
5.8 V Regulator
The 5.8 V regulator charges the bypass capacitor connected to
the BYPASS pin to 5.8 V by drawing a current from the voltage
on the DRAIN, whenever the MOSFET is off. The BYPASS pin
is the internal supply voltage node for the TinySwitch. When
the MOSFET is on, the TinySwitch runs off of the energy stored
in the bypass capacitor. Extremely low power consumption of
the internal circuitry allows the TinySwitch to operate continuously from the current drawn from the DRAIN pin. A bypass
capacitor value of 0.1 µF is sufficient for both high frequency
de-coupling and energy storage.
Undervoltage
The undervoltage circuitry disables the power MOSFET when
the BYPASS pin voltage drops below 5.1 V. Once the BYPASS
pin voltage drops below 5.1 V, it has to rise back to 5.8 V to
enable (turn-on) the power MOSFET.
Hysteretic Over Temperature Protection
The thermal shutdown circuitry senses the die junction temperature. The threshold is set at 135 °C with 70 °C hysteresis. When the junction temperature rises above this threshold
(135 °C) the power MOSFET is disabled and remains disabled
until the die junction temperature falls by 70 °C, at which point
it is re-enabled.
Current Limit
The current limit circuit senses the current in the power
MOSFET. When this current exceeds the internal threshold
(ILIMIT), the power MOSFET is turned off for the remainder of
that cycle.
The leading edge blanking circuit inhibits the current limit
comparator for a short time (tLEB) after the power MOSFET
is turned on. This leading edge blanking time has been set so
that current spikes caused by primary-side capacitance and
secondary-side rectifier reverse recovery time will not cause
premature termination of the switching pulse.
TinySwitch Operation
TinySwitch is intended to operate in the current limit mode.
When enabled, the oscillator turns the power MOSFET on at the
beginning of each cycle. The MOSFET is turned off when the
current ramps up to the current limit. The maximum on-time
of the MOSFET is limited to DCMAX by the oscillator. Since
the current limit and frequency of a given TinySwitch device
are constant, the power delivered is proportional to the primary
inductance of the transformer and is relatively independent of
the input voltage. Therefore, the design of the power supply
involves calculating the primary inductance of the transformer
for the maximum power required. As long as the TinySwitch
device chosen is rated for the power level at the lowest input
voltage, the calculated inductance will ramp up the current to
the current limit before the DCMAX limit is reached.
Enable Function
The TinySwitch senses the ENABLE pin to determine whether
or not to proceed with the next switch cycle as described earlier. Once a cycle is started TinySwitch always completes the cycle
(even when the ENABLE pin changes state half way through the
cycle). This operation results in a power supply whose output
voltage ripple is determined by the output capacitor, amount of
energy per switch cycle and the delay of the ENABLE feedback.
The ENABLE signal is generated on the secondary by comparing
the power supply output voltage with a reference voltage. The
ENABLE signal is high when the power supply output voltage
is less than the reference voltage. In a typical implementation, the ENABLE pin is driven by
an optocoupler. The collector of the optocoupler transistor is
connected to the ENABLE pin and the emitter is connected to
the SOURCE pin. The optocoupler LED is connected in series
with a Zener across the DC output voltage to be regulated. When the output voltage exceeds the target regulation voltage
level (optocoupler diode voltage drop plus Zener voltage), the
optocoupler diode will start to conduct, pulling the ENABLE
pin low. The Zener could be replaced by a TL431 device for
improved accuracy. The ENABLE pin pull-down current threshold is nominally
50 µA, but is set to 40 µA the instant the threshold is exceeded. This is reset to 50 µA when the ENABLE pull-down current
drops below the current threshold of 40 µA.
ON/OFF Control
The internal clock of the TinySwitch runs all the time. At the
beginning of each clock cycle the TinySwitch samples the
ENABLE pin to decide whether or not to implement a switch
cycle. If the ENABLE pin is high (< 40 µA), then a switching
cycle takes place. If the ENABLE pin is low (greater than
50 µA) then no switching cycle occurs, and the ENABLE pin
status is sampled again at the start of the subsequent clock cycle.
At full load TinySwitch will conduct during the majority of
its clock cycles (Figure 4). At loads less than full load, the
TinySwitch will “skip” more cycles in order to maintain voltage regulation at the secondary output (Figure 5). At light
load or no load, almost all cycles will be skipped (Figure 6). A small percentage of cycles will conduct to support the power
consumption of the power supply.
Rev E
02/12
3
TNY253/254/255
V
EN
V
EN
CLOCK
CLOCK
DC
DC
MAX
MAX
IDRAIN
IDRAIN
VDRAIN
VDRAIN
PI-2259-061298
PI-2255-061298
Figure 4. TinySwitch Operation at Heavy Load.
Figure 5. TinySwitch Operation at Medium Load.
The response time of TinySwitch ON/OFF control scheme is
very fast compared to normal PWM control. This provides high
line ripple rejection and excellent transient response.
rejection and relatively constant power delivery independent
of the input voltage.
Power Up/Down
TinySwitch requires only a 0.1 µF capacitor on the BYPASS
pin. Because of the small size of this capacitor, the power-up
delay is kept to an absolute minimum, typically 0.3 ms (Figure 7). Due to the fast nature of the ON/OFF feedback, there is
no overshoot at the power supply output. During power-down,
the power MOSFET will switch until the rectified line voltage
drops to approximately 12 V. The power MOSFET will then
remain off without any glitches (Figure 8).
Bias Winding Eliminated
TinySwitch does not require a bias winding to provide power
to the chip. Instead it draws the power directly from the
DRAIN pin (see Functional Description above). This has two
main benefits. First for a nominal application, this eliminates
the cost of an extra bias winding and associated components. Secondly, for charger applications, the current-voltage characteristic often allows the output voltage to fall to low values
while still delivering power. This type of application normally
requires a forward-bias winding which has many more associated components, none of which are necessary with TinySwitch.
Current Limit Operation
Each switching cycle is terminated when the DRAIN current
reaches the current limit of the TinySwitch. For a given primary
inductance and input voltage, the duty cycle is constant. However, duty cycle does change inversely with the input voltage
providing “voltage feed-forward” advantages: good line ripple
4
Rev E
02/12
44 kHz Switching Frequency (TNY253/254)
Switching frequency (with no cycle skipping) is set at 44 kHz. This provides several advantages. At higher switching frequencies, the capacitive switching losses are a significant proportion
of the power losses in a power supply. At higher frequencies,
the preferred snubbing schemes are RCD or diode-Zener clamps. However, due to the lower switching frequency of TinySwitch ,
it is possible to use a simple RC snubber (and even just a capacitor alone in 115 VAC applications at powers levels below 4 W).
Secondly, a low switching frequency also reduces EMI filtering
requirements. At 44 kHz, the first, second and third harmonics are all below 150 kHz where the EMI limits are not very
restrictive. For power levels below 4 W it is possible to meet
worldwide EMI requirements with only resistive and capacitive filter elements (no inductors or chokes). This significantly
reduces EMI filter costs.
Finally, if the application requires stringent noise emissions
(such as video applications), then the TNY253/254 will allow
more effective use of diode snubbing (and other secondary
snubbing techniques). The lower switching frequency allows
RC snubbers to be used to reduce noise, without significantly
impacting the efficiency of the supply.
130 kHz Switching Frequency (TNY255)
The switching frequency (with no cycle skipping) is set at
130 kHz. This allows the TNY255 to deliver 10 W while still
using the same size, low cost transformer (EE16) as used by
the TNY253/254 for lower power applications.
PI–2253-062398
TNY253/254/255
V
EN
CLOCK
DC
V
IN
MAX
IDRAIN
0V
VDRAIN
0V
0
.2
.4
.6
.8
1
Time (ms)
VDRAIN
PI-2261-061198
Figure 6. TinySwitch Operation at Light Load.
PI–2251-062398
Figure 7. TinySwitch Power-Up Timing Diagram.
V
IN
BYPASS Pin Capacitor
The BYPASS pin uses a small 0.1 µF ceramic capacitor for
decoupling the internal power supply of the TinySwitch.
Application Examples
12 V
0V
VDRAIN
Television Standby
TinySwitch is an ideal solution for low cost, high efficiency standby power supplies used in consumer electronic products
such as TVs. Figure 9 shows a 7.5 V, 1.3 W flyback circuit that
uses TNY253 for implementing a TV standby supply. The circuit
operates from the DC high-voltage already available from the
main power supply. This input voltage can range from 120 to
375 VDC depending on the input AC voltage range that the TV
is rated for. Capacitor C1 filters the high-voltage DC supply,
and is necessary only if there is a long trace length from the
source of the DC supply to the inputs of the TV standby circuit. The high-voltage DC bus is applied to the series combination
of the primary winding of T1 and the integrated high-voltage
MOSFET inside the TNY253. The low operating frequency of
the TNY253 (44 kHz), allows a low cost snubber circuit C2 and
R1 to be used in place of a primary clamp circuit. In addition
to limiting the DRAIN turn off voltage spike to a safe value,
the RC snubber also reduces radiated video noise by lowering
the dv/dt of the DRAIN waveform, which is critical for video
applications such as TV and VCR. On fixed frequency PWM
and RCC circuits, use of a snubber will result in an undesirable fixed AC switching loss that is independent of load. The
ON/OFF control on the TinySwitch eliminates this problem
by scaling the effective switching frequency and therefore, 12 V
0V
0
100
200
300
400
500
Time (ms)
Figure 8. TinySwitch Power Down Timing Diagram.
switching loss linearly with load. Thus the efficiency of the
supply stays relatively constant down to a fraction of a watt of
output loading.
The secondary winding is rectified and filtered by D1 and C4 to
create the 7.5 V output. L1 and C5 provide additional filtering. The output voltage is determined by the sum of the optocoupler
U2 LED forward drop (~ 1 V) and Zener diode VR1 voltage. The resistor R2, maintains a bias current through the Zener to
improve its voltage tolerance.
10 W Standby
The TNY255 is ideal for standby applications that require up
to 10 W of power from 230 VAC or 100/115 VAC with doubler
circuit. The TNY255 operates at 130 kHz as opposed to 44 kHz
for TNY253/254. The higher frequency operation allows the
Rev E
02/12
5
TNY253/254/255
1
+
T1
D1
1N4934
L1
15 μH
10
+ 7.5 V
C5
47 μF
10 V
C4
330 μF
10 V
8
4
Optional
DC IN
120 - 375
VDC
C1
0.01 μF
1 kV
R1
100 Ω
1/2 W
TinySwitch
U1
TNY253P
D
RTN
U2
SFH615-2
EN
BP
R2
1 kΩ
S
C3
0.1 μF
C2
56 pF
1 kV
–
VR1
1N5235B
C6
680 pF
Y1 Safety
PI-2246-082898
Figure 9. 1.3 W TV Standby Circuit using TNY253.
1
R1
150 kΩ
1W
240 - 375
VDC
C1
0.01 μF
1 kV
10
D2
SB540
TinySwitch
U1
TNY255P
L1
10 μH
C4
2700 μF
6.3 V
C2
4700 pF
1 kV
4
D1
1N4937
Optional
T1
D
+5V
C5
220 μF
10 V
8
RTN
EN
BP
R2
68 Ω
U2
LTV817
S
C3
0.1 μF
VR1
1N5229B
PI-2242-082898
Figure 10. 10 W Standby Supply Circuit.
use of a low cost EE16 core transformer up to the 10 W level. Figure 10 shows a 5 V, 10 W circuit for such an application. The circuit operates from the high-voltage DC supply already
available from the main power supply. Capacitor C1 filters the
high-voltage DC supply, and is necessary only if there is a long
trace length from the source of the DC supply to the inputs of
the standby circuit. The high-voltage DC bus is applied to the
primary winding of T1 in series with the integrated high-voltage
MOSFET inside the TNY255. The diode D1, capacitor C2 and
resistor R1 comprise the clamp circuit that limits the turn-off
voltage spike on the TinySwitch DRAIN pin to a safe value. The secondary winding is rectified and filtered by D2 and C4
to provide the 5 V ouput. Additional filtering is provided by
L1 and C5. The output voltage is determined by the sum of the
6
Rev E
02/12
optocoupler U2 LED forward drop (~ 1 V) and Zener diode
VR1 voltage. The resistor R2, maintains a bias current through
the Zener to improve its voltage tolerance. For tighter tolerance,
a TL431 precision reference IC feedback circuit may be used.
Cellular Phone Charger
The TinySwitch is well suited for applications that require a
constant voltage and constant current output. TinySwitch is
always powered from the input high-voltage, therefore it does
not require bias winding for power. Consequently, its operation is not dependent on the level of the output voltage. This
allows for constant current charger designs that work down to
zero volts on the output.
TNY253/254/255
T1
1
D1
1N4005
85 - 265
VAC
R2
100 kΩ
1W
D2
1N4005
C1
6.8 μF
400 V
RF1
10 Ω
D5
FR201
C5
220 μF
25 V
D
EN
U2
LTV817
BP
R7
100 Ω
R9
47 Ω
Q1
2N3904
C3
0.1 μF
R1
1.2 kΩ
D4
1N4005
RTN
R8
820 Ω
S
L1
560 μH
+ 5.2 V
C6
220 μF
16 V
5
2
D6
1N4937
Fusible
D3
1N4005
L2
3.3 μH
C4
2200 pF
TinySwitch
U1
TNY254P
C2
4.7 μF
400 V
10
R3
22 Ω
VR1
1N5230B
4.7 V
R5
18 Ω
1/8 W
R4
1Ω
1W
C8
2.2 nF
Y1 Safety
R6
0.82 Ω
1/2 W
PI-2244-082898
Figure 11. 3.6 W Constant Voltage-Constant Current Cellular Phone Charger Circuit.
T1
1
10
D3
1N3934
D1
1N4004
6
5
C1
2.2 μF
200 V
115 VAC
± 15%
RF1
1.8 Ω
+9V
C6
100 μF
16V
D2
1N4004
C2
2.2 μF
200 V
C4
68 pF
1 KV
TinySwitch
U1
TNY253P
R2
100 Ω
D
VR1
1N5239B
RTN
EN
BP
S
C3
0.1 μF
C5
2.2 nF
Y1 Safety
Fusible
PI-2190-031501
Figure 12. 0.5 W Open Loop AC Adapter Circuit.
Figure 11 shows a 5.2 V, 3.6 W cellular phone charger circuit
that uses the TNY254 and provides constant voltage and constant
current output over an universal input (85 to 265 VAC) range. The AC input is rectified and filtered by D1 - D4, C1 and C2
to create a high-voltage DC bus connected to T1 in series with
the high-voltage MOSFET inside the TNY254. The inductor
L1 forms a π-filter in conjunction with C1 and C2. The resistor
R1 damps resonances in the inductor L1. The low frequency of
operation of TNY254 (44 kHz) allows use of the simple π-filter
described above in combination with a single Y1-capacitor C8
to meet worldwide conducted EMI standards. The diode D6,
capacitor C4 and resistor R2 comprise the clamp circuit that
limits the turn-off voltage spike on the TinySwitch DRAIN pin
to a safe value. The secondary winding is rectified and filtered
by D5 and C5 to provide the 5.2 V output. Additional filtering
is provided by L2 and C6. The output voltage is determined
by the sum of the optocoupler U2 LED forward drop (~ 1 V)
and Zener diode VR1 voltage. The resistor R8, maintains a
bias current through the Zener to improve its voltage tolerance.
A simple constant current circuit is implemented using the VBE
of transistor Q1 to sense the voltage across the current sense
resistor R4, which can be made up of one or more resistors to
Rev E
02/12
7
TNY253/254/255
achieve the appropriate value. R3 is a base current limiting
resistor. When the drop across R4 exceeds the VBE of transistor
Q1, it turns on and takes over the control of the loop by driving
the optocoupler LED. R6 drops an additional voltage to keep
the control loop in operation down to zero volts on the output. With the output shorted, the drop across R4 and R6 (~ 1.5 V) is
sufficient to keep the Q1 and LED circuit active. Resistors R7
and R9 limit the forward current that could be drawn through
VR1 by Q1 under output short-circuit conditions, due to the
voltage drop across R6 and R4.
AC Adapter
Many consumer electronic products utilize low power 50/60 Hz
transformer based AC adapters. The TinySwitch can cost effectively replace these linear adapters with a solution that is
lighter, smaller and more energy efficient . Figure 12 shows a
9 V, 0.5 W AC adapter circuit using the TNY253. This circuit
operates from a 115 VAC input. To save cost, this circuit runs
without any feedback, in discontinuous conduction mode to
deliver constant power output relatively independent of input voltage. The output voltage is determined by the voltage
drop across Zener diode VR1. The primary inductance of the
transformer is chosen to deliver a power that is in excess of the
required output power by at least 50% to allow for component
tolerances and to maintain some current through the Zener VR1
at full load. At no load, all of the power is delivered to the Zener
which should be rated and heat sinked accordingly. In spite of
a constant power consumption from the mains input, this solution is still significantly more efficient than linear adapters up
to output power levels of approximately 1 W.
The AC input is rectified by diodes D1 and D2. D2 is used to
reduce conducted EMI by only allowing noise onto the neutral
line during diode conduction. The rectified AC is then filtered
by capacitors C1 and C2 to generate a high-voltage DC bus,
which is applied to the series combination of the primary winding of T1 and the high-voltage MOSFET inside the TNY253. The resistor R2 along with capacitors C1 and C2 form a π-filter
which is sufficient for meeting EMI conducted emissions at
these power levels. C5 is a Y capacitor which is used to reduce
common mode EMI. Due to the 700 V rating of the TinySwitch
MOSFET, a simple capacitive snubber (C4) is adequate to limit
the leakage inductance spike in 115 VAC applications, at low
power levels. The secondary winding is rectified and filtered
by D3 and C6.
Key Application Considerations
For the most up to date information visit our Web site
at: www.powerint.com
Design
Output Power Range
The power levels shown in the TinySwitch Selection Guide
(Table 1) are approximate, recommended output power ranges
that will provide a cost optimum design and are based on
following assumptions:
1. The minimum DC input voltage is 90 V or higher for 85 VAC
input or 240 V or higher for 230 VAC input or 115 VAC
input with a voltage doubler.
2. The TinySwitch is not thermally limited - the source
pins are soldered to sufficient copper area to keep the die
temperature at or below 100 °C. This limitation does not usually apply to TNY253 and TNY254.
The maximum power capability of a TinySwitch depends on
the thermal environment, transformer core size and design
(continuous or discontinuous), efficiency required, minimum
specified input voltage, input storage capacitance, output voltage, output diode forward drop, etc., and can be different from
the values shown in the selection guide. Audible Noise
At loads other than maximum load, the cycle skipping mode
operation used in TinySwitch can generate audio frequency
components in the transformer. This can cause the transformer
to produce audio noise. Transformer audible noise can be
reduced by utilizing appropriate transformer construction
techniques and decreasing the peak flux density. For more
information on audio suppression techniques, please check
the Application Notes section on our Web site at
www.powerint.com. Ceramic capacitors that use dielectrics such as Z5U, when used
in clamp and snubber circuits, can also generate audio noise
due to electrostriction and piezo-electric effects. If this is the
case, replacing them with a capacitor having a different type
of dielectric is the simplest solution. Polyester film capacitor
is a good alternative.
Short-Circuit Current
The TinySwitch does not have an auto-restart feature. As a
result, TinySwitch will continue to deliver power to the load
during output short-circuit conditions. In the worst case, peak
short-circuit current is equal to the primary current limit (ILIMIT)
multiplied by the turns ratio of the transformer (Np/Ns). In
a typical design the average current is 25 to 50% lower than
this peak value. At the power levels of TinySwitch this is
8
Rev E
02/12
TNY253/254/255
Safety Spacing
Input Filter Capacitor
Output Filter Capacitor
Transformer
+
HV
SEC
PRI
–
S
D
TOP VIEW
Y1Capacitor
TinySwitch
CBP
Optocoupler
BP
S
EN
–
DC +
OUT
Maximize hatched copper
areas (
) for optimum
heat sinking
PI-2176-071398
Figure 13. Recommended PC Layout for the TinySwitch.
easily accommodated by rating the output diode to handle the
short-circuit current. The short-circuit current can be minimized
by choosing the smallest (lowest current limit) TinySwitch for
the required power.
Layout
Single Point Grounding
Use a single point ground connection at the SOURCE pin for
the BYPASS pin capacitor and the Input Filter Capacitor (see
Figure 13).
Primary Loop Area
The area of the primary loop that connects the input filter capacitor, transformer primary and TinySwitch together, should
be kept as small as possible.
Primary Clamp Circuit
A clamp or snubber circuit is used to minimize peak voltage
and ringing on the DRAIN pin at turn-off. This can be achieved
by using an RC snubber for less than 3 W or an RCD clamp
as shown in Figure 13 for higher power. A Zener and diode
clamp across the primary or a single 550 V Zener clamp from
DRAIN to SOURCE can also be used. In all cases care should
be taken to minimize the circuit path from the snubber/clamp
components to the transformer and TinySwitch.
Thermal Considerations
Copper underneath the TinySwitch acts not only as a single
point ground, but also as a heatsink. The hatched area shown
in Figure 13 should be maximized for good heat-sinking of
TinySwitch and output diode. Y Capacitor
The placement of the Y capacitor should be directly from the
primary single point ground to the common/return terminal on
the secondary side. Such placement will maximize the EMI
benefit of the Y capacitor.
Optocoupler
It is important to maintain the minimum circuit path from
the optocoupler transistor to the TinySwitch ENABLE and
SOURCE pins to minimize noise coupling.
Output Diode
For best performance, the area of the loop connecting the
secondary winding, the Output Diode and the Output Filter
Capacitor, should be minimized. See Figure 13 for optimized
layout. In addition, sufficient copper area should be provided
at the anode and cathode terminals of the diode to adequately
heatsink the diode under output short-circuit conditions.
Input and Output Filter Capacitors
There are constrictions in the traces connected to the input and
output filter capacitors. These constrictions are present for two
reasons. The first is to force all the high frequency currents
to flow through the capacitor (if the trace were wide then it
could flow around the capacitor). Secondly, the constrictions
minimize the heat transferred from the TinySwitch to the input
filter capacitor and from the secondary diode to the output filter
capacitor. The common/return (the negative output terminal
in Figure 13) terminal of the output filter capacitor should be
connected with a short, low resistance path to the secondary
winding. In addition, the common/return output connection
should be taken directly from the secondary winding pin and
not from the Y capacitor connection point.
Rev E
02/12
9
TNY253/254/255
ABSOLUTE MAXIMUM RATINGS(1)
DRAIN Voltage........................................... -0.3 V to 700 V
Peak DRAIN Current (TNY253/4).............400 (500) mA(6)
Peak DRAIN Current (TNY255)................530 (660) mA(6)
ENABLE Voltage............................................ -0.3 V to 9 V
ENABLE Current.................................................... 100 mA
BYPASS Voltage............................................. -0.3 V to 9 V
1. All voltages referenced to SOURCE, TA = 25 °C.
2. Normally limited by internal circuitry.
3. 1/16" from case for 5 seconds.
Storage Temperature....................................... -65 to 150 °C
Operating Junction Temperature(2) . ............... -40 to 150 °C
Lead Temperature(3) ..................................................260 °C
Thermal Impedance (θJA)...................70 °C/W(4), 55 °C/W(5)
Thermal Impedance (θJC)........................................ 11 °C/W
4. Soldered to 0.36 sq. inch (232 mm2), 2 oz. (610 gm/m2) copper clad.
5. Soldered to 1 sq. inch (645 mm2), 2 oz. (610 gm/m2) copper clad.
6. The higher peak drain current is allowed while the drain voltage is simultaneously less than 400 V.
Conditions
Parameter
SOURCE = 0 V; TJ = -40 to 125 °C
See Figure 14
(Unless Otherwise Specified)
Symbol
fOSC
Maximum
Duty Cycle
DCMAX
ENABLE Pin Turnoff
Threshold Current
IDIS
ENABLE Pin
Hysteresis Current
IHYS
ENABLE Pin
Voltage
VEN
ENABLE ShortCircuit Current
IENSC
DRAIN
Supply Current
IS2
ICH1
BYPASS Pin
Charge Current
BYPASS Pin
Voltage
BYPASS
Hysteresis
10
Rev E
02/12
TJ = 25 °C
S1 Open
IS1
ICH2
Units
TNY253
TNY254
TNY255
TNY253
TNY254
TNY255
TJ = -40 °C to 125 °C
40 44
48
kHz
130
115
140
666871
%
64
69
67
TJ = 125 °C
-68
-68
-50
-30
-45
-52
See Note A
-15-10 -5
µA
µA
1.101.451.80
V
VEN = 0 V, TJ = -40 °C to 125 °C
-58 -42
-25
µA
VEN = 0 V, TJ = 125 °C
-58
-45
-38
TNY253 160 200
VEN = 0 V
TNY254
µA
(MOSFET Not Switching)
170
215
TNY255
See Note B
TNY253
ENABLE Open
140
180
TNY254 (MOSFET Switching)
µA
See Note B, C
TNY255
215 265
TNY253
-2.0
-3.5
VBP = 0 V, TJ = 25 °C TNY254 -5.0
mA
See Note D, E
-6.0
-3.0
TNY255
-4.5
TNY253
-1.0
-2.5
VBP = 4 V, TJ = 25 °C See TNY254 -4.0
mA
Note D, E
TNY255
-4.8
-1.8
-3.3
See Note D
Max
IEN = -25 µA
VBP
VBPH
Typ
CONTROL FUNCTIONS
Output
Frequency
Min
5.6
5.8
6.1
V
0.60
0.72
0.85
V
Conditions
Parameter
Symbol SOURCE = 0 V; TJ = -40 to 125 °C
See Figure 14
(Unless Otherwise Specified)
TNY253/254/255
Min
Typ
Max
Units
CIRCUIT PROTECTION
Current Limit
ILIMIT
Note F
di/dt = 12.5 mA/µs
TJ = 25 °C
TNY253
135150165
di/dt = 25 mA/µs
TJ = 25 °C
TNY254
230255280
di/dt = 80 mA/µs
TJ = 25 °C
TNY255
255280310
Initial Current
IINIT
Limit
Leading Edge
Blanking Time
See Figure 17
TJ = 25 °C
TJ = 25 °C
tLEB
Current Limit
Delay
Thermal Shutdown
Temperature
tILD
TJ = 25 °C
See Note G
TNY253
TNY254
TNY255
TNY253
TNY254
TNY255
Thermal Shutdown
Hysteresis
mA
0.65 x
mA
I
LIMIT(MIN)
170240
ns
170 215
200250
100150
ns
125135145
°C
°C
70
OUTPUT
ON-State
RDS(ON)
Resistance
OFF-State Drain
IDSS
Leakage Current
Breakdown
BVDSS
Voltage
Rise Time
Fall Time
TNY253/TNY254
ID = 25 mA
TNY255
ID = 33 mA
TJ = 25 °C
TJ = 100 °C
TJ = 25 °C
TJ = 100 °C
VBP = 6.2 V, VEN = 0 V, VDS = 560 V, TJ = 125 °C
VBP = 6.2 V, VEN = 0 V, IDS = 100 µA, TJ = 25 °C
tR
tF
Measured with Figure 10
Schematic.
31 36
5060
Ω
23 27
37 45
µA
50
V
700
50
50
ns
ns
Rev E
02/12
11
TNY253/254/255
Conditions
Parameter
Symbol SOURCE = 0 V; TJ = -40 to 125 °C
See Figure 14
(Unless Otherwise Specified)
Min
Typ
Max
Units
OUTPUT (cont.)
DRAIN Supply
Voltage
Output Enable
Delay
tEN
Output Disable
Setup Time
tDST
TNY253
TNY254
TNY255
50
V
14
µs
10
0.5 µs
NOTES:
A. For a threshold with a negative value, negative hysteresis is a decrease in magnitude of the corresponding threshold.
B. Total current consumption is the sum of IS1 and IDSS when ENABLE pin is shorted to ground (MOSFET not switching) and the sum of IS2 and IDSS when ENABLE pin is open (MOSFET switching).
C. Since the output MOSFET is switching, it is difficult to isolate the switching current from the supply current at the
DRAIN. An alternative is to measure the BYPASS pin current at 6.2 V.
D. BYPASS pin is not intended for sourcing supply current to external circuitry.
E. See typical performance characteristics section for BYPASS pin start-up charging waveform.
F. For current limit at other di/dt values, refer to current limit vs. di/dt curve under typical performance characteristics.
G. This parameter is derived from the change in current limit measured at 5X and 10X of the di/dt shown in the ILIMIT specification.
470 Ω
5W
S2
470 Ω
D
EN
S
S
S
S
S
BP
S1
50 V
10 V
0.1 μF
NOTE: This test circuit is not applicable for current limit or output characteristic measurements.
PI-2211-061898
Figure 14. TinySwitch General Test Circuit.
12
Rev E
02/12
TNY253/254/255
DCMAX
t2
HV 90%
tP
t1
90%
DRAIN
VOLTAGE
ENABLE
tEN
t
D= 1
t2
1
tP =
for TNY253/254
2fOSC
10%
0V
t =
P
PI-2048-033001
PI-2194-062398
Figure 16. TinySwitch Output Enable Timing.
PI-2248-090198
DRAIN Current (normalized)
Figure 15. TinySwitch Duty Cycle Measurement.
1
for TNY255
fOSC
tLEB (Blanking Time)
1.3
1.2
1.1
1.0
0.9
0.8
0.7
0.6
0.5
0.4
0.3
0.2
0.1
IINIT(MIN)
ILIMIT(MAX) @ 25 °C
ILIMIT(MIN) @ 25 °C
0
0
1
2
3
4
5
6
7
8
Time (μs)
Figure 17. Current Limit Envelope.
Typical Performance Characteristics
BREAKDOWN vs. TEMPERATURE
1.2
PI-2238-033001
PI-2213-040901
1.1
FREQUENCY vs. TEMPERATURE
1.0
0.8
0.6
1.0
0.4
0.2
0
0.9
-50 -25
0
25
50
75 100 125 150
-50 -25
0
25
50
75
100 125
Rev E
02/12
13
TNY253/254/255
Typical Performance Characteristics (Continued)
TNY253 CURRENT LIMIT vs. di/dt
CURRENT LIMIT vs. TEMPERATURE
1.0
0.8
0.6
0.4
0.2
1.2
1.0
0.8
0.6
0.4
0.2
0.0
-50 -25
0
25
50
75
PI-2230-082798
1.2
1.4
Current Limit
(Normalized to 12.5 mA/s)
PI-2236-033001
1.4
0.0
100 125
0 12.5 25 37.5 50 62.5 75 87.5 100
di/dt in mA/s
TNY255 CURRENT LIMIT vs. di/dt
TNY254 CURRENT LIMIT vs. di/dt
1.0
0.8
0.6
0.4
0.2
PI-2234-082798
1.2
1.4
Current Limit
(Normalized to 80 mA/s)
PI-2232-082798
Current Limit
(Normalized to 25 mA/s)
1.4
1.2
1.0
0.8
0.6
0.4
0.2
0.0
0.0
0
50
100
150
200
0
250
160
480
640
800
di/dt in mA/s
di/dt in mA/s
OUTPUT CHARACTERISTIC
BYPASS PIN START-UP WAVEFORM
5
4
3
2
1
PI-2221-033001
6
300
250
Drain Current (mA)
PI-2240-082898
7
BYPASS Pin Voltage (V)
320
200
150
100
Scaling Factors:
TNY253
1.00
TNY254
1.00
TNY255
1.33
50
0
0
0
0.2
0.4
0.6
Time (ms)
14
Rev E
02/12
0.8
1.0
0
2
4
6
DRAIN Voltage (V)
8
10
TNY253/254/255
Typical Performance Characteristics (Continued)
COSS vs. DRAIN VOLTAGE
DRAIN CAPACITANCE POWER
Scaling Factors:
TNY253
1.00
TNY254
1.00
TNY255
1.33
40
Power (mW)
Scaling Factors:
TNY253
1.00
TNY254
1.00
TNY255
1.33
10
PI-2225-033001
50
PI-2223-033001
DRAIN Capacitance (pF)
100
30
20
10
1
0
200
0
600
400
0
DRAIN Voltage (V)
200
400
600
DRAIN Voltage (V)
PDIP-8 (P Package)
DIM
Inches
mm
A
B
C
G
H
J1
J2
K
L
M
N
P
Q
0.367-0.387
0.240-0.260
0.125-0.145
0.015-0.040
0.120-0.140
0.057-0.068
0.014-0.022
0.008-0.015
0.100 BSC
0.030 (MIN)
0.300-0.320
0.300-0.390
0.300 BSC
9.32-9.83
6.10-6.60
3.18-3.68
0.38-1.02
3.05-3.56
1.45-1.73
0.36-0.56
0.20-0.38
2.54 BSC
0.76 (MIN)
7.62-8.13
7.62-9.91
7.62 BSC
D S .004 (.10)
8
5
-E-
B
1
4
M
Notes:
1. Package dimensions conform to JEDEC
specification MS-001-AB for standard dual in-line
(DIP) package .300 inch row spacing (PLASTIC)
8 leads (issue B, 7/85).
2. Controlling dimensions are inches.
3. Dimensions shown do not include mold flash
or other protrusions. Mold flash or protrusions G
shall not exceed .006 (.15) on any side.
4. D, E and F are reference datums on the molded
body.
L
-D-
A
J1
N
C
-FH
J2
K
Q
P
P08A
PI-2076-040110
Rev E
02/12
15
TNY253/254/255
SMD-8 (G Package)
D S .004 (.10)
8
-E-
Inches
mm
A
B
C
G
H
J1
J2
J3
J4
K
L
M
P
α
0.367-0.387
0.240-0.260
0.125-0.145
0.004-0.012
0.036-0.044
0.057-0.068
0.048-0.053
0.032-0.037
0.007-0.011
0.010-0.012
0.100 BSC
0.030 (MIN)
0.372-0.388
0-8°
9.32-9.83
6.10-6.60
3.18-3.68
0.10-0.30
0.91-1.12
1.45-1.73
1.22-1.35
0.81-0.94
0.18-0.28
0.25-0.30
2.54 BSC
0.76 (MIN)
9.45-9.86
0-8°
.420
.046 .060
.060 .046
.080
Pin 1
4
L
.086
.186
-D-
A
M
E S .010 (.25)
P
B
1
DIM
5
.286
Solder Pad Dimensions
J1
C
K
-FJ3
J4
G08A
J2
.004 (.10)
α
.010 (.25) M A S
G
H
Notes:
1. Package dimensions conform to JEDEC
specification MS-001-AB (issue B, 7/85)
except for lead shape and size.
2. Controlling dimensions are inches.
3. Dimensions shown do not include mold
flash or other protrusions. Mold flash or
protrusions shall not exceed .006 (.15) on
any side.
4. D, E and F are reference datums on the
molded body.
PI-2077-040110
Revision
16
Notes
Date
A
-
02/99
B
1. Leading edge blanking time (tLEB) typical and minimum values increased to improve design flexibility.
2. Minimum DRAIN supply current (IS1, IS2) eliminated as it has no design revelance.
07/01
C
1. Updated package reference.
2. Corrected VR1 in Figure 12.
3. Corrected storage temperature, θJA and θJC and updated nomenclature in parameter table.
4. Corrected spacing and font sizes in figures.
D
1. Corrected θJA for P/G package.
2. Updated DIP-8 and SMD-8 Package Drawings.
3. Figure 10 caption and text description modified.
04/03
E
1. Changed SOA limit.
02/12
Rev E
02/12
TNY253/254/255
Notes
Rev E
02/12
17
TNY253/254/255
For the latest updates, visit our website: www.powerint.com
Power Integrations reserves the right to make changes to its products at any time to improve reliability or manufacturability. Power
Integrations does not assume any liability arising from the use of any device or circuit described herein. POWER INTEGRATIONS MAKES
NO WARRANTY HEREIN AND SPECIFICALLY DISCLAIMS ALL WARRANTIES INCLUDING, WITHOUT LIMITATION, THE IMPLIED
WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE, AND NON-INFRINGEMENT OF THIRD PARTY RIGHTS.
Patent Information
The products and applications illustrated herein (including transformer construction and circuits external to the products) may be covered
by one or more U.S. and foreign patents, or potentially by pending U.S. and foreign patent applications assigned to Power Integrations. A
complete list of Power Integrations patents may be found at www.powerint.com. Power Integrations grants its customers a license under
certain patent rights as set forth at http://www.powerint.com/ip.htm.
Life Support Policy
POWER INTEGRATIONS PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES OR
SYSTEMS WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT OF POWER INTEGRATIONS. As used herein:
1. A Life support device or system is one which, (i) is intended for surgical implant into the body, or (ii) supports or sustains life, and (iii) whose failure to perform, when properly used in accordance with instructions for use, can be reasonably expected to result in significant
injury or death to the user.
2. A critical component is any component of a life support device or system whose failure to perform can be reasonably expected to cause
the failure of the life support device or system, or to affect its safety or effectiveness.
The PI logo, TOPSwitch, TinySwitch, LinkSwitch, DPA-Switch, PeakSwitch, CAPZero, SENZero, LinkZero, HiperPFS, HiperTFS, HiperLCS,
Qspeed, EcoSmart, Clampless, E-Shield, Filterfuse, StakFET, PI Expert and PI FACTS are trademarks of Power Integrations, Inc. Other
trademarks are property of their respective companies. ©2012, Power Integrations, Inc.
Power Integrations Worldwide Sales Support Locations
World Headquarters
5245 Hellyer Avenue
San Jose, CA 95138, USA.
Main: +1-408-414-9200
Customer Service:
Phone: +1-408-414-9665
Fax: +1-408-414-9765
e-mail: [email protected]
China (Shanghai)
Rm 1601/1610, Tower 1,
Kerry Everbright City
No. 218 Tianmu Road West,
Shanghai, P.R.C. 200070
Phone: +86-21-6354-6323
Fax: +86-21-6354-6325
e-mail: [email protected]
China (ShenZhen)
3rd Floor, Block A,
Zhongtou International Business
Center, No. 1061, Xiang Mei Rd,
FuTian District, ShenZhen,
China, 518040
Phone: +86-755-8379-3243
Fax: +86-755-8379-5828
e-mail: [email protected]
18
Rev E
02/12
Germany
Rueckertstrasse 3
D-80336, Munich
Germany
Phone: +49-89-5527-3910
Fax: +49-89-5527-3920
e-mail: [email protected]
India
#1, 14th Main Road
Vasanthanagar
Bangalore-560052 India
Phone: +91-80-4113-8020
Fax: +91-80-4113-8023
e-mail: [email protected]
Italy
Via De Amicis 2
20091 Bresso MI
Italy
Phone: +39-028-928-6000
Fax: +39-028-928-6009
e-mail: [email protected]
Japan
Kosei Dai-3 Bldg.
2-12-11, Shin-Yokomana,
Kohoku-ku
Yokohama-shi Kanagwan
222-0033 Japan
Phone: +81-45-471-1021
Fax: +81-45-471-3717
e-mail: [email protected]
Korea
RM 602, 6FL
Korea City Air Terminal B/D, 159-6
Samsung-Dong, Kangnam-Gu,
Seoul, 135-728, Korea
Phone: +82-2-2016-6610
Fax: +82-2-2016-6630
e-mail: [email protected]
Taiwan
5F, No. 318, Nei Hu Rd., Sec. 1
Nei Hu Dist.
Taipei, Taiwan 114, R.O.C.
Phone: +886-2-2659-4570
Fax: +886-2-2659-4550
e-mail: [email protected]
Europe HQ
1st Floor, St. James’s House
East Street, Farnham
Surrey GU9 7TJ
United Kingdom
Phone: +44 (0) 1252-730-141
Fax: +44 (0) 1252-727-689
e-mail: [email protected]
Applications Hotline
World Wide +1-408-414-9660
Singapore
51 Newton Road
Applications Fax
#15-08/10 Goldhill Plaza
World Wide +1-408-414-9760
Singapore, 308900
Phone: +65-6358-2160
Fax: +65-6358-2015
e-mail: [email protected]