STMICROELECTRONICS ALTAIR05T

ALTAIR05T-800
Off-line all-primary-sensing switching regulator
Features
■
Constant voltage and constant current output
regulation (CV/CC) with no optocoupler
■
Tight regulation also in presence of heavy load
transients
■
800 V avalanche rugged internal power section
■
Quasi-resonant (QR) operation
■
Low standby power consumption
■
Automatic self-supply
■
Input voltage feedforward for mainsindependent cc regulation
■
Output cable drop compensation
■
SO16 package
SO16N
Applications
■
AC-DC chargers for mobile phones and other
hand-held equipments
■
Compact SMPS that requires a precise current
and/or voltage regulation
Description
ALTAIR05T-800 is a high-voltage all-primary
sensing switcher intended for operating directly
from the rectified mains with minimum external
parts. It combines a high-performance lowvoltage PWM controller chip and an 800 V
avalanche-rugged power section in the same
package.
Figure 1.
Block diagram
+Vout
+Vin
Is tart -up
Vcc
Internal supply bus
PROTECTION &
FEEDFORWARD
LOGIC
DRAIN
SUPPLY
& UV LO
Vref
UVLO
Prot
CDC
Rcdc
Rzcd
IFF
Iout
ESTIMATE
ZCD/FB
BLANKING
TIME
Vc
STARTER
3.3 V
TURN-ON
LOGIC
Vc
DEMAG
LOGIC
Rfb
R
R
Q
Q
LEB
+
R
S
Q
1V
Iref
-
+
S/H
S
S
Intern.
supp ly
bus
I FF
-
UVLO
R
+
Prot
+
2.5 V
RFF
COMP
GND
IREF
Rcomp
Cref
SOURCE
Rsense
Ccomp
October 2010
Doc ID 17957 Rev 1
1/28
www.st.com
28
Contents
ALTAIR05T-800
Contents
1
Device description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3
2
Pin connection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
3
Maximum ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
3.1
Absolute maximum ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
3.2
Thermal data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
4
Electrical characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7
5
Application information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11
5.1
Power section and gate driver . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
5.2
High-voltage start-up generator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
5.3
Zero current detection and triggering block . . . . . . . . . . . . . . . . . . . . . . . 13
5.4
Constant voltage operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
5.5
Constant current operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
5.6
Voltage feedforward block . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
5.7
Cable drop compensation (CDC) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
5.8
Burst-mode operation at no load or very light load . . . . . . . . . . . . . . . . . . 20
5.9
Soft-start and starter block . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20
5.10
Hiccup mode OCP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
5.11
Layout recommendations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
6
Typical application . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23
7
Package mechanical data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24
8
Order codes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26
9
Revision history . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27
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Doc ID 17957 Rev 1
ALTAIR05T-800
1
Device description
Device description
The device combines two silicon in the same package: a low voltage PWM controller and
an 800 V avalanche rugged power section.
The controller chip is a current-mode specifically designed for offline quasi-resonant flyback
converters.
The device features a unique characteristic: it is capable of providing constant output
voltage (CV) and constant output current (CC) regulation using primary-sensing feedback.
This eliminates the need for the optocoupler, the secondary voltage reference, as well as the
current sensor, still maintaining quite accurate regulation also in presence of heavy load
transients. Additionally, it is possible to compensate the voltage drop on the output cable, so
as to improve CV regulation on the external accessible terminals.
Quasi-resonant operation is guaranted by means of a transformer demagnetization sensing
input that turns on the power section. The same input serves also the output voltage
monitor, to perform CV regulation, and the input voltage monitor, to achieve mainsindependent CC regulation (line voltage feedforward).
The maximum switching frequency is top-limited below 166 kHz, so that at medium-light
load a special function automatically lowers the operating frequency still maintaining the
valley switching operation. At very light load, the device enters a controlled burst-mode
operation that, along with the built-in high-voltage start-up circuit and the low operating
current, helps minimize the standby power.
Although an auxiliary winding is required in the transformer to correctly perform CV/CC
regulation, the chip is able to power itself directly from the rectified mains. This is useful
especially during CC regulation, where the flyback voltage generated by the winding drops
below UVLO threshold. However, if ultra-low no-load input consumption is required to
comply with the most stringent energy-saving recommendations, then the device needs to
be powered via the auxiliary winding.
In addition to these functions that optimize power handling under different operating
conditions, the device offers protection features that considerably increase end-product’s
safety and reliability: auxiliary winding disconnection - or brownout – detection and shorted
secondary rectifier - or transformer’s saturation – detection. All of them are auto restart
mode.
Doc ID 17957 Rev 1
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Pin connection
2
ALTAIR05T-800
Pin connection
Figure 2.
Pin connection (top view)
SOURCE
1
16
DRAIN
SOURCE
2
15
DRAIN
Vcc
3
14
DRAIN
GND
4
13
DRAIN
IREF
5
12
N.C.
ZCD/FB
6
11
N.A.
COMP
7
10
N.A.
CDC
8
9
N.A.
Note:
The copper area for heat dissipation has to be designed under the drain pins
Table 1.
Pin functions
N.
1, 2
Function
Power section source and input to the PWM comparator. The current flowing in the MOSFET
is sensed through a resistor connected between the pin and GND. The resulting voltage is
compared with an internal reference (0.75V max.) to determine MOSFET’s turn-off. The pin
SOURCE
is equipped with 250 ns blanking time after the gate-drive output goes high for improved
noise immunity. If a second comparison level located at 1V is exceeded the IC is stopped and
restarted after Vcc has dropped below 5V.
3
Vcc
Supply Voltage of the device. An electrolytic capacitor, connected between this pin and
ground, is initially charged by the internal high-voltage start-up generator; when the device is
running the same generator keeps it charged in case the voltage supplied by the auxiliary
winding is not sufficient. This feature is disabled in case a protection is tripped. Sometimes a
small bypass capacitor (0.1 µF typ.) to GND might be useful to get a clean bias voltage for
the signal part of the IC.
4
GND
Ground. Current return for both the signal part of the IC and the gate drive. All of the ground
connections of the bias components should be tied to a trace going to this pin and kept
separate from any pulsed current return.
IREF
CC regulation loop reference voltage. An external capacitor has to be connected between
this pin and GND. An internal circuit develops a voltage on this capacitor that is used as the
reference for the MOSFET’s peak drain current during CC regulation. The voltage is
automatically adjusted to keep the average output current constant.
5
4/28
Name
Doc ID 17957 Rev 1
ALTAIR05T-800
Table 1.
N.
Pin connection
Pin functions (continued)
Name
Function
6
ZCD/FB
Transformer’s demagnetization sensing for quasi-resonant operation. Input/output voltage
monitor. A negative-going edge triggers MOSFET’s turn-on. The current sourced by the pin
during ON-time is monitored to get an image of the input voltage to the converter, in order to
compensate the internal delay of the current sensing circuit and achieve a CC regulation
independent of the mains voltage. If this current does not exceed 50µA, either a floating pin
or an abnormally low input voltage is assumed, the device is stopped and restarted after Vcc
has dropped below 5V. Still, the pin voltage is sampled-and-held right at the end of
transformer’s demagnetization to get an accurate image of the output voltage to be fed to the
inverting input of the internal, transconductance-type, error amplifier, whose non-inverting
input is referenced to 2.5V. Please note that the maximum IZCD/FB sunk/sourced current has
to not exceed ±2 mA (AMR) in all the Vin range conditions (85-265 Vac). No capacitor is
allowed between the pin and the auxiliary transformer.
7
COMP
Output of the internal transconductance error amplifier. The compensation network is placed
between this pin and GND to achieve stability and good dynamic performance of the voltage
control loop.
8
CDC
Cable drop compensation input. During CV regulation this pin, capable of sinking current,
provides a voltage lower than the internal reference voltage (2.5V) by an amount proportional
to the dc load current. By connecting a resistor between this pin and ZCD/FB, the CV
regulation setpoint is increased proportionally. This allows that the voltage drop across the
output cable be compensated and, ideally, that zero load regulation at the externally available
terminals be achieved. Leave the pin open if the function is not used.
9-11
N.A
Not available. These pins must be left not connected
12
N.C
Not internally connected. Provision for clearance on the PCB to meet safety requirements.
13 to 16
DRAIN
Drain connection of the internal power section. The internal high-voltage start-up generator
sinks current from this pin as well. Pins connected to the internal metal frame to facilitate
heat dissipation.
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Maximum ratings
ALTAIR05T-800
3
Maximum ratings
3.1
Absolute maximum ratings
Table 2.
Symbol
VDS
ID
Eav
Absolute maximum ratings
Pin
Value
Unit
-1 to 800
V
1,2, 13-16 Drain current
1
A
1,2, 13-16 Single pulse avalanche energy (Tj = 25°C, ID = 1A)
50
mJ
1,2, 13-16 Drain-to-source (ground) voltage
Vcc
3
Supply voltage (Icc < 25mA)
Self limiting
V
IZCD/FB
6
Zero current detector current
±2
mA
---
7, 8
-0.3 to 3.6
V
ICDC
8
Maximum sunk current
200
µA
Power dissipation @TA = 50°C
0.9
W
Junction temperature range
-25 to 150
°C
Storage temperature
-55 to 150
°C
Ptot
Tj
Tstg
3.2
Analog inputs and outputs
Thermal data
Table 3.
Symbol
6/28
Parameter
Thermal data
Parameter
Max. value Unit
Rth j-pin Thermal resistance, junction-to-pin
10
Rth j-amb Thermal resistance, junction-to-ambient
110
Doc ID 17957 Rev 1
°C/W
ALTAIR05T-800
4
Electrical characteristics
Electrical characteristics
(TJ = -25 to 125 °C, Vcc = 14 V; unless otherwise specified)
Table 4.
Electrical characteristics
Symbol
Parameter
Test condition
Min. Typ. Max. Unit
Power section
V(BR)DSS Drain-source breakdown
IDSS
RDS(on)
Coss
ID< 100 µA; Tj = 25 °C
800
V
VDS = 750 V; Tj = 125 °C
(See Figure 4 and note)
Off state drain current
80
Id=100 mA; Tj = 25 °C
11
14
Id=100 mA; Tj = 125 °C
22
28
Drain-source ON-state resistance
µA
Ω
Effective (energy-related) output capacitance (See Figure 3)
High-voltage start-up generator
VStart
Min. Drain start voltage
Icharge < 100 µA
40
50
60
V
Icharge
Vcc startup charge current
VDRAIN> VStart; VCC<VCCOn
Tj = 25 °C
4
5.5
7
mA
9.5
10.5
11.5
(1)
VCCrestart Vcc restart voltage (Vcc falling)
V
After protection tripping
5
Supply voltage
Vcc
Operating range
After turn-on
VccOn
Turn-on threshold
(1)
12
Turn-off threshold
(1)
Zener voltage
Icc = 20 mA
VccOff
VZ
11.5
23
V
13
14
V
9
10
11
V
23
25
27
V
(See Figure 5)
200
300
µA
Supply current
Iccstart-up Start-up current
Iq
Quiescent current
(See Figure 6)
1
1.4
mA
Icc
Operating supply current @ 50 kHz
(See Figure 7)
1.4
1.7
mA
Fault quiescent current
During hiccup and brownout
(See Figure 8)
250
350
µA
100
125
175
µs
400
500
700
µs
0.1
1
µA
3.3
3.6
V
Iq(fault)
Start-up timer
TSTART
Start timer period
TRESTART Restart timer period during burst mode
Zero current detector
IZCDb
Input bias current
VZCD = 0.1 to 3 V
VZCDH
Upper clamp voltage
IZCD = 1 mA
Doc ID 17957 Rev 1
3.0
7/28
Electrical characteristics
Table 4.
ALTAIR05T-800
Electrical characteristics (continued)
Symbol
Parameter
Test condition
Min. Typ. Max. Unit
VZCDL
Lower clamp voltage
IZCD = - 1 mA
-90
-60
-30
mV
VZCDA
Arming voltage
positive-going edge
100
110
120
mV
VZCDT
Triggering voltage
negative-going edge
50
60
70
mV
IZCDON
Min. source current during MOSFET ON-time
-25
-50
-75
µA
TBLANK
Trigger blanking time after MOSFET’s turn-off
VCOMP ≥ 1.3V
6
VCOMP = 0.9V
30
IZCD = 1mA
45
µs
Line feedforward
RFF
Equivalent feedforward resistor
Ω
Transconductance error amplifier
Tj = 25°C (1)
2.46
Tj = -25 to 125°C and
Vcc=12V to 23V (1)
2.42
1.3
VREF
Voltage reference
gm
Transconductance
∆ICOMP = ±10 µA
VCOMP = 1.65 V
Gv
Voltage gain
Open loop
GB
Gain-bandwidth product
2.5
2.54
V
2.58
2.2
3.2
mS
73
dB
500
KHz
Source current
VZCD = 2.3V, VCOMP = 1.65V
70
100
µA
Sink current
VZCD = 2.7V, VCOMP = 1.65V
400
750
µA
VCOMPH
Upper COMP voltage
VZCD = 2.3 V
2.7
V
VCOMPL
Lower COMP voltage
VZCD = 2.7 V
0.7
V
1
V
65
mV
ICOMP
VCOMPBM Burst-mode threshold
Hys
Burst-mode hysteresis
CDC function
VCDC
CDC voltage reference
VCOMP = 1.1V, ICDC = 1µA (1)
2.4
2.5
2.6
V
VCOMP = VCOMPL (1)
1.5
1.6
1.7
V
0.192
0.2
0.208
V
200
250
300
ns
Current reference
VIREFx
Maximum value
VCREF
Current reference voltage
Current sense
tLEB
Leading-edge blanking
td(H-L)
Delay-to-output
VCSx
VCSdis
300
Max. clamp value
dVcs/dt = 200 mV/µs
Hiccup-mode OCP level
(1)
1. Parameters tracking each other
8/28
Doc ID 17957 Rev 1
(1)
ns
0.7
0.75
0.8
V
0.92
1
1.08
V
ALTAIR05T-800
Figure 3.
Electrical characteristics
COSS output capacitance variation
500
C OSS (pF)
400
300
200
100
0
0
25
50
75
100
125
150
V DS (V)
Figure 4.
Off state drain and source current test circuit
14 V
VD D
CDC
2. 5V
F B /Z C D
+
Ids s
D R AI N
C U R R EN T
C ON TR OL
C OMP
Note:
A
GN D
IR E F
Vin
75 0V
SOU R C E
The measured IDSS is the sum between the current across the start-up resistor and the
effective MOSFET’s off state drain current.
Figure 5.
Start-up current test circuit
Ic cst art-up
FB/ ZC D
1 1.8 V
VDD
CDC
2. 5V
A
+
D R AIN
C U R R EN T
C ON TR OL
C OMP
IR EF
Doc ID 17957 Rev 1
GN D
SOU R C E
9/28
Electrical characteristics
Figure 6.
ALTAIR05T-800
Quiescent current test circuit
Iq_ m eas
A
VD D
CDC
2.5 V
F B/ Z C D
D R AI N
+
C U R R EN T
C ON TR OL
-
3 3k
C OMP
I R EF
GN D
SOU R C E
0 .8 V
3V
Figure 7.
1 4V
10 k
0.2 V
Operating supply current test circuit
Ic c
1. 5k
2W
15V
A
27 k
VD D
CDC
22 0k
2. 5V
F B /Z C D
10 k
1 0k
+
C U R R EN T
C ON TR OL
-
150V
C OMP
Note:
SOU R C E
5. 6
2. 8V
-5V
The circuit across the ZCD pin is used for switch-on synchronization
Figure 8.
Quiescent current during fault test circuit
I q(f au lt )
2. 5V
F B/ Z C D
A
14V
VDD
CDC
+
D R AIN
C U R R EN T
C ON TR OL
C OMP
10/28
GN D
I R EF
10
50 kH z
D R AIN
IR EF
Doc ID 17957 Rev 1
GN D
SOU R C E
ALTAIR05T-800
5
Application information
Application information
The device is an off-line all-primary sensing switching regulator, based on quasi-resonant
flyback topology.
Depending on converter’s load condition, the device is able to work in different modes (see
Figure 9):
1.
QR mode at heavy load. Quasi-resonant operation lies in synchronizing MOSFET's
turn-on to the transformer’s demagnetization by detecting the resulting negative-going
edge of the voltage across any winding of the transformer. Then the system works
close to the boundary between discontinuous (DCM) and continuous conduction
(CCM) of the transformer. As a result, the switching frequency is different for different
line/load conditions (see the hyperbolic-like portion of the curves in Figure 9). Minimum
turn-on losses, low EMI emission and safe behavior in short circuit are the main
benefits of this kind of operation.
2.
Valley-skipping mode at medium/ light load. Depending on voltage on COMP pin, the
device defines the maximum operating frequency of the converter. As the load is
reduced MOSFET’s turn-on does not occur any more on the first valley but on the
second one, the third one and so on. In this way the switching frequency is no longer
increased (piecewise linear portion in Figure 9).
3.
Burst-mode with no or very light load. When the load is extremely light or disconnected,
the converter enters a controlled on/off operation with constant peak current.
Decreasing the load result in frequency reduction, which can go down even to few
hundred hertz, thus minimizing all frequency-related losses and making it easier to
comply with energy saving regulations or recommendations. Being the peak current
very low, no issue of audible noise arises.
Figure 9.
Multi-mode operation of ALTAIR05T-800
f osc
Input voltage
f sw
Valley-skipping
mode
Burst-mode
Quasi-resonant mode
0
Pin
Doc ID 17957 Rev 1
Pinmax
11/28
Application information
5.1
ALTAIR05T-800
Power section and gate driver
The power section guarantees safe avalanche operation within the specified energy rating
as well as high dv/dt capability. The Power MOSFET has a V(BR)DSS of 800 V min. and a
typical RDS(on) of 11 Ω.
The gate driver is designed to supply a controlled gate current during both turn-on and turnoff in order to minimize common mode EMI. Under UVLO conditions an internal pull-down
circuit holds the gate low in order to ensure that the power MOSFET cannot be turned on
accidentally.
5.2
High-voltage start-up generator
The HV current generator is supplied through the DRAIN pin and it is enabled only if the
input bulk capacitor voltage is higher than Vstart threshold, 50 VDC typically. When the HV
current generator is ON, the Icharge current (5.5 mA typical value) is delivered to the
capacitor on the VCC pin.
With reference to the timing diagram of Figure 10, when power is applied to the circuit and
the voltage on the input bulk capacitor is high enough, the HV generator is sufficiently
biased to start operating, thus it draws about 5.5 mA (typical) from the bulk capacitor. Most
of this current charges the bypass capacitor connected between the Vcc pin and ground and
make its voltage rise linearly.
As the Vcc voltage reaches the start-up threshold (13 V typ.) the chip starts operating, the
internal power MOSFET is enabled to switch and the HV generator is cut off. The IC is
powered by the energy stored in the Vcc capacitor.
The chip is able to power itself directly from the rectified mains: when the voltage on the VCC
pin falls below Vccrestart (10.5V typ.), during each MOSFET’s off-time the HV current
generator is turned on and charges the supply capacitor until it reaches the VCCOn
threshold.
In this way, the self-supply circuit develops a voltage high enough to sustain the operation of
the device. This feature is useful especially during CC regulation, when the flyback voltage
generated by the auxiliary winding alone may not be able to keep Vcc above VCCrestart.
At converter power-down the system loses regulation as soon as the input voltage falls
below VStart. This prevents converter’s restart attempts and ensures monotonic output
voltage decay at system power-down.
12/28
Doc ID 17957 Rev 1
ALTAIR05T-800
Application information
Figure 10. Timing diagram: normal power-up and power-down sequences
Vin
VStart
Vcc
t
VccON
Vccrestart
t
DRAIN
Icharge
t
5.5 mA
Normal operation
CV mode
Power-on
t
Power-off
Zero current detection and triggering block
The zero current detection (ZCD) and triggering blocks switch on the power MOSFET if a
negative-going edge falling below 50 mV is applied to the ZCD/FB pin. To do so, the
triggering block must be previously armed by a positive-going edge exceeding 100 mV.
This feature is used to detect transformer demagnetization for QR operation, where the
signal for the ZCD input is obtained from the transformer’s auxiliary winding used also to
supply the IC.
Figure 11. ZCD block, triggering block
R zcd
ZCD/FB
BLANKIN G
TIME
Z CD
CLAMP
STARTER
Rfb
Aux
TU RN- ON
LO GIC
110mV
60mV
S
+
5.3
Normal operation
CC mode
Q
Fr om CC/ CV Bloc k
LEB
To Dr iv er
R
Fr om OC P
The triggering block is blanked after MOSFET’s turn-off to prevent any negative-going edge
that follows leakage inductance demagnetization from triggering the ZCD circuit
erroneously.
This blanking time is dependent on the voltage on COMP pin: it is TBLANK = 30 µs for VCOMP
= 0.9 V, and decreases almost linearly down to TBLANK = 6 µs for VCOMP = 1.3 V
Doc ID 17957 Rev 1
13/28
Application information
ALTAIR05T-800
The voltage on the pin is both top and bottom limited by a double clamp, as illustrated in the
internal diagram of the ZCD block of Figure 11. The upper clamp is typically at 3.3 V, while
the lower clamp is at -60 mV. The interface between the pin and the auxiliary winding is a
resistor divider. Its resistance ratio as well as the individual resistance values has to be
properly chosen (see “Section 5.4: Constant voltage operation” and “Section 5.6: Voltage
feedforward block”).
Please note that the maximum IZCD/FB sunk/sourced current has to not exceed ±2 mA
(AMR) in all the Vin range conditions (85-265 Vac). No capacitor is allowed between ZCD
pin and the auxiliary transformer.
The switching frequency is top-limited below 166 kHz, as the converter’s operating
frequency tends to increase excessively at light load and high input voltage.
A Starter block is also used to start-up the system, that is, to turn on the MOSFET during
converter power-up, when no or a too small signal is available on the ZCD pin.
The starter frequency is 2 kHz if COMP pin is below burst mode threshold, i.e. 1 V, while it
becomes 8 kHz if this voltage exceed this value.
After the first few cycles initiated by the starter, as the voltage developed across the auxiliary
winding becomes large enough to arm the ZCD circuit, MOSFET’s turn-on starts to be
locked to transformer demagnetization, hence setting up QR operation.
The starter is activated also when the IC is in CC regulation and the output voltage is not
high enough to allow the ZCD triggering.
If the demagnetization completes – hence a negative-going edge appears on the ZCD pin –
after a time exceeding time TBLANK from the previous turn-on, the MOSFET is turned on
again, with some delay to ensure minimum voltage at turn-on. If, instead, the negative-going
edge appears before TBLANK has elapsed, it is ignored and only the first negative-going
edge after TBLANK turns-on the MOSFET. In this way one or more drain ringing cycles is
skipped (“valley-skipping mode”, Figure 12) and the switching frequency is prevented from
exceeding 1/TBLANK.
Figure 12. Drain ringing cycle skipping as the load is progressively reduced
VDS
VDS
VDS
TON
TFW
TV
Tosc
t
t
Tosc
Pin = Pin'
(limit condition)
Tosc
Pin = Pin'' < Pin'
Pin = Pin''' < P in''
Note that when the system operates in valley skipping-mode, uneven switching cycles may
be observed under some line/load conditions, due to the fact that the OFF-time of the
MOSFET is allowed to change with discrete steps of one ringing cycle, while the OFF-time
needed for cycle-by-cycle energy balance may fall in between. Thus one or more longer
switching cycles is compensated by one or more shorter cycles and vice versa. However,
this mechanism is absolutely normal and there is no appreciable effect on the performance
of the converter or on its output voltage.
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ALTAIR05T-800
5.4
Application information
Constant voltage operation
The IC is specifically designed to work in primary regulation and the output voltage is
sensed through a voltage partition of the auxiliary winding, just before the auxiliary rectifier
diode.
Figure 13 shows the internal schematic of the constant voltage mode and the external
connections.
Figure 13. Voltage control principle: internal schematic
Rzcd
S/ H
-
EA
+
Rfb
+
Aux
2. 5V
D EMAG
LOGI C
To PWM Logic
CV
F rom Rsense
COMP
R
C
Due to the parasitic wires resistance, the auxiliary voltage is representative of the output just
when the secondary current becomes zero. For this purpose, the signal on ZCD/FB pin is
sampled-and-held at the end of transformer’s demagnetization to get an accurate image of
the output voltage and it is compared with the error amplifier internal reference.
The COMP pin is used for the frequency compensation: usually, an RC network, which
stabilizes the overall voltage control loop, is connected between this pin and ground.
The output voltage can be defined according the formula:
V REF
R FB = --------------------------------------------------------- ⋅ R ZCD
N AUX
-------------- ⋅ V OUT – V REF
N SEC
(1)
Where NSEC and NAUX are the secondary and auxiliary turn’s number respectively.
The RZCD value can be defined depending on the application parameters (see “Section 5.6:
Voltage feedforward block”).
5.5
Constant current operation
Figure 14 presents the principle used for controlling the average output current of the
flyback converter.
Doc ID 17957 Rev 1
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Application information
ALTAIR05T-800
The output voltage of the auxiliary winding is used by the demagnetization block to generate
the control signal for the mosfet switch Q1. A resistor R in series with it absorbs a current
VC/R, where VC is the voltage developed across the capacitor CREF.
The flip-flop’s output is high as long as the transformer delivers current on secondary side.
This is shown in Figure 15.
The capacitor CREF has to be chosen so that its voltage VC can be considered as a
constant. Since it is charged and discharge by currents in the range of some ten µA (ICREF
is typically 20 µA) at the switching frequency rate, a capacitance value in the range 4.7-10
nF is suited for switching frequencies in the ten kHz.
The average output current can be expressed as:
N PRI
V CREF
I OUT = -------------- ⋅ ------------------------------------N SEC ( 2 ⋅ R SENSE )
(2)
Where NPRI is the primary's turns number.
This formula shows that the average output current does not depend anymore on the input
or the output voltage, neither on transformer inductance values. The external parameters
defining the output current are the transformer ratio n and the sense resistor RSENSE.
Figure 14. Current control principle
.
Ir ef
To PWM Logic
CC
+
R
F rom Rsense
R zcd
Q1
S
ZCD/FB
Q
DEMAG
LOGI C
R
Rfb
Aux
IREF
Cref
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ALTAIR05T-800
Application information
Figure 15. Constant current operation: Switching cycle waveforms
T
IP
t
Is
t
Q
t
I CREF
IC
ICRE F = −
5.6
VC
R
t
Voltage feedforward block
The current control structure uses the voltage VC to define the output current, according to
(2). Actually, the CC comparator is affected by an internal propagation delay Td, which
switches off the MOSFET with a peak current than higher the foreseen value.
This current overshoot is equal to:
∆IP =
VIN ⋅ Td
LP
(3)
Where LP is the primary inductance.
It introduces an error on the calculated CC setpoint, depending on the input voltage.
The device implements a Line Feedforward function, which solves the issue by introducing
an input voltage dependent offset on the current sense signal, in order to adjust the cycleby-cycle current limitation.
The internal schematic is shown in Figure 16.
Doc ID 17957 Rev 1
17/28
Application information
ALTAIR05T-800
Figure 16. Feedforward compensation: internal schematic
DRAIN
ZCD/FB
F eedf orward
Logic
.
Rfb
Aux
I FF
CC
Block
-
R zcd
CC
PWM
LOGI C
+
Rf f
SOURCE
Rsense
The RZCD resistor can be calculated as follows:
RZCD =
NAUX
⋅
LP ⋅ RFF
NPRI Td ⋅ RSENSE
(4)
In this case the peak drain current does not depend on input voltage anymore.
One more consideration concerns the RZCD value: during MOSFET’s ON-time, the current
sourced by the ZCD/FB pin, IZCD, is compared with an internal reference current IZCDON (-50
µA typical).
If IZCD < IZCDON, the brownout function is activated and the IC is shut-down.
This feature is especially important when the auxiliary winding is accidentally disconnected
and considerably increases the end-product’s safety and reliability.
5.7
Cable drop compensation (CDC)
The voltage control loop regulates the output voltage as seen across the output capacitor.
If an output cable is used to supply the load, the voltage at the externally available terminals
is dependent on the output current value. The CDC function compensates the voltage drop
across the cable, so ideally zero load regulation can be achieved also at the end of the
cable.
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Doc ID 17957 Rev 1
ALTAIR05T-800
Application information
Figure 17 presents the internal schematic.
Figure 17. CDC block: internal schematic
Dsec
Vout
Vout_reg
Rcable/2
N pr i
Nsec
Cout
R cable/ 2
Rzcd
GND
N aux
Viref
Rcdc
CDC
To C V Compar ator
CDC
LOGIC
Vr ef
ZCD/FB
F B Block
Rf b
COMP
During CV regulation, as the CDC block is capable of sinking current, a resistor connect
between its output and ZCD/FB pin allows to increase the CV setpoint, by providing a
voltage lower than the internal reference voltage by an amount proportional to the average
load current.
If RCABLE is the total cable resistance, the resistor value can be calculated by using the
following equation:
2 ⋅ N SEC N SEC R SENSE ⋅ R ZCD
R CDC = ------------------------- ⋅ -------------- ⋅ -------------------------------------------N PRI
R CABLE
N AUX
(5)
In this equation RCABLE is the total resistance of the output cable.
The CDC block acts as an outer control loop with a positive feedback that changes the CV
setpoint. As such, it can impact on the overall system’s stability. In order to avoid any issue
that could make unstable the loop, the CV setpoint response time must be much slower than
that of the inner voltage loop.
For this purpose the CDC block is designed with a time response of a few ten ms. For the
same reason, the minimum voltage on CDC pin is bottom limited at to 2.25 V.
If the function is not required, the pin can be connected to ground or left open.
Doc ID 17957 Rev 1
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Application information
5.8
ALTAIR05T-800
Burst-mode operation at no load or very light load
When the voltage at the COMP pin falls 65 mV below a threshold fixed internally at a value,
VCOMPBM, the IC is disabled with the MOSFET kept in OFF state and its consumption
reduced at a lower value to minimize Vcc capacitor discharge.
In this condition the converter operates in burst-mode (one pulse train every TSTART=500
µs), with minimum energy transfer.
As a result of the energy delivery stop, the output voltage decreases: after 500 µs the
controller switches-on the MOSFET again and the sampled voltage on the ZCD pin is
compared with the internal reference. If the voltage on the EA output, as a result of the
comparison, exceeds the VCOMPL threshold, the device restarts switching, otherwise it stays
OFF for another 500 µs period.
In this way the converter works in burst-mode with a nearly constant peak current defined by
the internal disable level. Then a load decrease causes a frequency reduction, which can go
down even to few hundred hertz, thus minimizing all frequency-related losses and making it
easier to comply with energy saving regulations. This kind of operation, shown in the timing
diagrams of Figure 18 along with the others previously described, is noise-free since the
peak current is low
Figure 18. Load-dependent operating modes: timing diagrams
COMP
65 mV
hyster.
VCOMPL
IDS
Normal-mode
5.9
TSTART
TSTART
TSTART
Burst-mode
TSTART
Normal-mode
Soft-start and starter block
The soft start feature is automatically implemented by the constant current block, as the
primary peak current is limited from the voltage on the CREF capacitor.
During start-up, as the output voltage is zero, the IC starts in CC mode with no high peak
current operations. In this way the voltage on the output capacitor increases slowly and the
soft-start feature is ensured.
Actually the CREF value is not important to define the soft-start time, as its duration depends
on others circuit parameters, like transformer ratio, sense resistor, output capacitors and
load. The user can define the best appropriate value by experiments.
20/28
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ALTAIR05T-800
5.10
Application information
Hiccup mode OCP
The device is also protected against short circuit of the secondary rectifier, short circuit on
the secondary winding or a hard-saturated flyback transformer. A comparator monitors
continuously the voltage on the RSENSE and activates a protection circuitry if this voltage
exceeds 1 V.
To distinguish an actual malfunction from a disturbance (e.g. induced during ESD tests), the
first time the comparator is tripped the protection circuit enters a “warning state”. If in the
subsequent switching cycle the comparator is not tripped, a temporary disturbance is
assumed and the protection logic is reset in its idle state; if the comparator is tripped again a
real malfunction is assumed and the device is stopped.
This condition is latched as long as the device is supplied. While it is disabled, however, no
energy is coming from the self-supply circuit; hence the voltage on the VCC capacitor decays
and cross the UVLO threshold after some time, which clears the latch. The internal start-up
generator is still off, then the VCC voltage still needs to go below its restart voltage before the
VCC capacitor is charged again and the device restarted. Ultimately, this results in a lowfrequency intermittent operation (Hiccup-mode operation), with very low stress on the power
circuit. This special condition is illustrated in the timing diagram of Figure 19.
Figure 19. Hiccup-mode OCP: timing diagram
Secondary diode is shorted here
VCC
VccON
VccOFF
Vccrest
VSOURCE
Vcsdis
t
1V
t
Two switching cycles
VDS
t
5.11
Layout recommendations
A proper printed circuit board layout is essential for correct operation of any switch-mode
converter and this is true for the ALTAIR05T-800 as well. Careful component placing, correct
traces routing, appropriate traces widths and compliance with isolation distances are the
major issues. In particular:
●
The compensation network should be connected as close as possible to the COMP
pin, maintaining the trace for the GND as short as possible
●
Signal Ground should be routed separately from power ground, as well from the sense
resistor trace.
Doc ID 17957 Rev 1
21/28
Application information
ALTAIR05T-800
Figure 20. Suggested routing for converter
OUT
AC IN
AC IN
GND
CDC
FB/ZCD
COMP
22/28
DRAIN
VDD
ALTAIR05T-800
GND
Doc ID 17957 Rev 1
IREF
SOURCE
ALTAIR05T-800
6
Typical application
Typical application
Figure 21. Test board schematic: 5 W wide range mains CC/CV battery charger
L1
AC IN
BR
MB6S- RC
R1
T1
470uH
5V - 1A
STPS3L40U F
C1
4.7uF
400V
22
1W
D7
C3
1nF
C2
4. 7uF
400V
R2
120K
C9
680uF
Low ESR
R9
2. 2k
AC IN
D7
STTH1L06
R3
GN D
4 7K
D2
R4
BAT46
10
C4
10uF
R5
U1
ALTAIR 05
TBD
VDD
CD C
2. 5V
F B/ ZC D
+
2 .2nF - Y Cap
C UR R ENT
C ON TR OL
IR EF
C O MP
R6
10 K
GN D
T1 SPECIFICATION
Supplier: MAGNETICA
SOU R CE
C5
470nF
C7
4. 7nF
C6
1nF
Table 5.
C 10
D RAI N
R7
10k
R8
1.2
Core E16/8/5, f er rite N67
Gap: 0.18mm for 2.2mH primary inductance
Lleakage max= 88uH
Pr imar y: 125T, AWG34
Auxiliar y: 25T, AWG34
Secondary: 9T, 0.50 Tex-E
Efficiency at 115 VAC
Load [%]
IOUT[A]
VOUT[V]
POUT[W]
PIN[W]
Efficiency [%]
25
0.25
4.97
1.243
1.643
75.62
50
0.5
4.97
2.485
3.156
78.64
75
0.75
4.97
3.728
4.72
78.97
100
1
4.98
4.980
6.4
77.81
Average efficiency
Table 6.
77.79
Efficiency at 230 VAC
Load [%]
IOUT[A]
VOUT[V]
POUT[W]
PIN[W]
Efficiency [%]
25
0.25
4.98
1.245
1.88
66.22
50
0.5
4.97
2.485
3.349
74.18
75
0.75
4.98
3.735
4.838
77.22
100
1
4.99
4.990
6.326
78.88
Average efficiency
Doc ID 17957 Rev 1
74.12
23/28
Package mechanical data
7
ALTAIR05T-800
Package mechanical data
In order to meet environmental requirements, ST offers these devices in different grades of
ECOPACK® packages, depending on their level of environmental compliance. ECOPACK®
specifications, grade definitions and product status are available at: www.st.com.
ECOPACK® is an ST trademark.
Table 7.
SO16N mechanical data
Mm
inch
Dim.
Min
Typ
A
a1
Min
Typ
1.75
0.1
Max
0.069
0.25
a2
0.004
0.009
1.6
0.063
b
0.35
0.46
0.014
0.018
b1
0.19
0.25
0.007
0.010
C
0.5
c1
0.020
45°
(typ.)
D (1)
9.8
10
0.386
0.394
E
5.8
6.2
0.228
0.244
e
1.27
0.050
e3
8.89
0.350
F(1)
3.8
4.0
0.150
0.157
G
4.60
5.30
0.181
0.208
L
0.4
1.27
0.150
0.050
M
S
24/28
Max
0.62
0.024
8 °(max.)
Doc ID 17957 Rev 1
ALTAIR05T-800
Package mechanical data
Figure 22. Package dimensions
Doc ID 17957 Rev 1
25/28
Order codes
8
ALTAIR05T-800
Order codes
Table 8.
Ordering information
Order code
Package
ALTAIR05T-800
ALTAIR05T-800TR
26/28
Packaging
Tube
SO16N
Tape and reel
Doc ID 17957 Rev 1
ALTAIR05T-800
9
Revision history
Revision history
Table 9.
Document revision history
Date
Revision
25-Oct-2010
1
Changes
Initial release.
Doc ID 17957 Rev 1
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ALTAIR05T-800
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