RENESAS R2A20121SP

R2A20121SP
Synchronous Phase Shift Full-Bridge Control IC
REJ03D0914-0100
Rev.1.00
Sep 29, 2008
Features
•
•
•
•
•
High frequency operation; oscillator frequency = 2 MHz Max
Full-bridge phase-shift switching circuit with adjustable delay times
Integrated secondary synchronous rectification control with adjustable delay times
Pulse by pulse current limit
Package: TSSOP-20
Illustrative Circuit
VIN
Vout
+
−
DC 5 V
DC 5 V
DC 5 V
DC 5 V
DC 5 V
Vbias
(DC 12 V)
VCC OUT OUT CS RAMP
-A -B
OUT
-C
OUT OUT OUT
-D
-E -F
COMP
R2A20121
VREF
GND RT SYNC SS FB (+)
FB (−)
DELAY DELAY DELAY
-3
-1
-2
HAT3043C
HAT3042C
HAT3004R
Note: The above circuit is reference example. Please confirm the operation when designing the system.
REJ03D0914-0100 Rev.1.00 Sep 29, 2008
Page 1 of 27
R2A20121SP
Pin Arrangement
SYNC
1
20
RT
RAMP
2
19
GND
CS
3
18
OUT-A
COMP
4
17
OUT-B
FB (+)
5
16
OUT-C
FB (−)
6
15
OUT-D
SS
7
14
OUT-E
DELAY-1
8
13
OUT-F
DELAY-2
9
12
VCC
DELAY-3
10
11
VREF
(Top view)
Pin Functions
Pin No.
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
Pin Name
SYNC
Function
Synchronization I/O for the oscillator
RAMP
CS
COMP
FB (+)
FB (–)
SS
DELAY-1
DELAY-2
DELAY-3
VREF
VCC
OUT-F
OUT-E
OUT-D
OUT-C
OUT-B
OUT-A
GND
RT
Current sense signal input for the full-bridge control loop
Current sense signal input for OCP
Error amplifier output
Error amplifier plus input
Error amplifier minus input
Timing capacitor for soft-start
Delay time adjustor for the full-bridge control signal (OUT-A and B)
Delay time adjustor for the full-bridge control signal (OUT-C and D)
Delay time adjustor for the secondary control signal (OUT-E and F)
5 V/20 mA Output
IC power supply input
Secondary control signal
Secondary control signal
Full-bridge control signal
Full-bridge control signal
Full-bridge control signal
Full-bridge control signal
Ground level for the IC
Timing resistor for the oscillator
REJ03D0914-0100 Rev.1.00 Sep 29, 2008
Page 2 of 27
R2A20121SP
Block Diagram
VCC
H
UVLO
L
VCC > 8.4 V→High
UVL
5V
GENERATOR
VREF
VREF H
GOOD L
VREF > 4.6 V→High
VREF
RT
START-UP
COUNTER
32 CLOCK
Current Ref.
Generator
OSCILLATOR
FB (−)
OUT-A
VREF
DELAY
ERROR AMP
VREF
−
VREF
Q
SYNC. I/O
CIRCUIT
BIAS
DELAY
RES
SYNC
VREF GOOD
DELAY-1
OUT-B
VREF
500 µ
R
SQ
+
DELAY
OUT-C
FB (+)
COMPARATOR
DELAY-2
VREF
−
+
COMP
DELAY
OUT-D
1.135 V
RAMP
+
−
CLAMP CIRCUIT
1.55 V
1.46 V
VREF GOOD
VREF
R
Q
S
Zero Delay
4V
10 µ
SS
VREF GOOD
VREF
DELAY
CS
+
1.4 V
PULSE BY PULSE
−
Zero Delay
DELAY
GND
Note: Note that all switches in the block diagram are turned on when control signal is high.
REJ03D0914-0100 Rev.1.00 Sep 29, 2008
Page 3 of 27
OUT-E
DELAY-3
VREF
OUT-F
R2A20121SP
Absolute Maximum Ratings
(Ta = 25°C)
Item
Power supply voltage
Peak output current
DC output current
VREF output current
COMP sink current
DELAY set current
RT set current
VREF terminal voltage
Terminal group 1 voltage
Operating junction temperature
Storage temperature
Symbol
Vcc
Ipk-out
Idc-out
Iref-out
Isink-comp
Iset-delay
Iset-rt
Vter-ref
Vter-1
Tj-opr
Tstg
Notes: 1.
2.
3.
4.
5.
Ratings
20
±50
±5
–20
2
0.3
0.3
–0.3 to 6
–0.3 to (Vref + 0.3)
–40 to +125
–55 to +150
Rated voltages are with reference to the GND pin.
Shows the transient current when driving a capacitive load.
For rated currents, inflow to the IC is indicated by (+), and outflow by (–).
VREF pin voltage must not exceed VCC pin voltage.
Terminal group 1 is defined the pins;
CS, RAMP, COMP, FB (+), FB (–), SS, RT, SYNC, DELAY-1 to 3, OUT-A to F
6. θja; 228°C/W
Board condition; Glass epoxy 55 mm × 45 mm × 1.6 mm, 10% wiring density.
REJ03D0914-0100 Rev.1.00 Sep 29, 2008
Page 4 of 27
Unit
V
mA
mA
mA
mA
mA
mA
V
V
°C
°C
Notes
1
2, 3
3
3
3
3
3
1, 4
1, 5
6
R2A20121SP
Electrical Characteristics
(Ta = 25°C, Vcc = 12 V, RT = 33 kΩ, Rdelay = 51 kΩ, unless otherwise specified.)
Item
SUPPLY
VREF
OSCILLATOR
SYNC
Note:
Symbol
Min
Typ
Max
Unit
Test Conditions
Start threshold
VH
7.7
8.4
9.1
V
Shutdown threshold
VL
7.4
8.0
8.6
V
UVLO hysteresis
dVUVL
0.3
0.4
0.5
V
Start-up current
Is
—
90
150
µA
Vcc = 7.5 V
Operating current
Icc
—
7
10
mA
No load on VREF pin
Output voltage
Vref
4.9
5.0
5.1
V
Line regulation
Vref-line
—
0
10
mV
Vcc = 10 V to 16 V
Load regulation
Vref-load
—
6
20
mV
Iref = –1 mA to –20 mA
Temperature stability
dVref/dTa
—
±80 *
1
—
ppm/°C
Oscillator frequency
fosc
—
960 *
1
—
kHz
Switching frequency
fsw
412
480
547
kHz
Line stability
fsw-line
–1.5
0
1.5
%
Vcc = 10 V to 16 V
Temperature stability
dfsw/dTa
—
±0.1 *
—
%/°C
Ta = –40 to 105°C
RT voltage
VRT
2.5
2.7
2.9
V
Input threshold
VTH-SYNC
2.5
2.85
3.2
V
Output high
VOH-SYNC
3.5
4.0
—
V
RSYNC = 33 kΩ to GND
RSYNC = 33kΩ to VREF
1
Output low
VOL-SYNC
—
0.05
0.15
V
Minimum input pulse
TI-MIN
50
—
—
ns
Output pulse width
TO-SYNC
—
500
—
ns
1. Reference values for design. Not 100% tested in production.
REJ03D0914-0100 Rev.1.00 Sep 29, 2008
Page 5 of 27
Ta = –40 to 105°C
Measured on OUT-A, -B
R2A20121SP
Electrical Characteristics (cont.)
(Ta = 25°C, Vcc = 12 V, RT = 33 k, Rdelay = 51 k, unless otherwise specified.)
ERROR
AMPLIFIER
Item
Input offset voltage
Symbol
Vos
Min
–2
Typ
3
Max
8
Unit
mV
FB (+) input current
FB (–) input current
Open-loop DC gain
Unity gain bandwidth
Output source current
IFB (+)
IFB (–)
Av
BW
ISOURCE
–2.0
–2.0
—
—
–650
0
0
1
80 *
1
2*
–500
2.0
2.0
—
—
–390
µA
µA
dB
MHz
µA
Output sink current
ISINK
2.0
6.5
—
mA
FB (+) = 1.25 V,
FB (–) = 1.75 V, COMP = 2 V
Output high voltage
VOH-EO
3.7
3.9
—
V
FB (+) = 1.25 V,
FB (–) = 0.75 V, COMP; Open
Output low voltage
VOL-EO
—
0.1
0.4
V
FB (+) = 1.25 V,
FB (–) = 1.75 V, COMP; Open
VCLAMP-EO
–0.16
–0.07
0.0
V
FB (+) = 1.25 V, FB (–) = 0.75 V,
COMP; Open, SS = 1 V
VRAMP
IRAMP
ISINK-RAMP
Dmin
Dmax
Tpd
Tdis
TD1, 2, 3
TD2_1, _2, _3
VD1, 2, 3
1.035
–5
8
—
—
—
40
22
70
1.9
1.135
–0.8
26
1 5
0**
1 5
97.0 * *
30
80
33.5
100
2.0
1.235
5
—
—
—
60
120
45
130
2.1
V
µA
mA
%
%
ns
ns
ns
ns
V
Output clamp voltage *
PHASE
MODULATOR
4
RAMP offset voltage
RAMP bias current
1
RAMP sink current *
Minimum phase shift
Maximum phase shift
2
Delay to OUT-C, -D *
1
RAMP discharge time *
3
DELAY-1, -2, -3 *
1 3
DELAY2-1, -2, -3 * *
Terminal voltage
DELAY
Notes: 1. Reference values for design. Not 100% tested in production.
2. Tpd is defined as;
1V
RAMP
50%
0V
5V
50%
OUT-C/D
0V
Tpd
3. TD1, 2, 3 are defined as;
TD1
TD1
OUT-A
50%
OUT-B
For primary
control
OUT-C
TD2
TD2
OUT-D
OUT-E
For secondary
control
TD3
OUT-F
TD3
4. VCLAMP-EO = VCOMP – SS voltage (1 V)
5. Maximum/Minimum phase shift is defined as;
D=
T2
× 2 × 100 (%)
T1
OUT-A
OUT-B
T2
T2
OUT-D
OUT-C
T1
REJ03D0914-0100 Rev.1.00 Sep 29, 2008
Page 6 of 27
T1
Test Conditions
FB (–) and COMP are shorted.
VFB (+) = 1.25 V
FB (+) = FB (–) = 1.25 V
FB (+) = FB (–) = 1.25 V
FB (+) = 1.25 V,
FB (–) = 0.75 V, COMP = 2 V
RAMP = 0.3 V
RAMP = 1 V, COMP = 0 V
RAMP = 1 V, COMP = 0 V
RAMP = 0 V, COMP = 2.1 V
COMP = 1.6 V
Delay set R = 51 k
Delay set R = 180 k
Delay set R = 51 k
R2A20121SP
Electrical Characteristics (cont.)
(Ta = 25°C, Vcc = 12 V, RT = 33 k, Rdelay = 51 k, unless otherwise specified.)
Item
SOFT START
OVER
Symbol
Min
Typ
Max
Unit
Source current
ISS
–14
–10
–6
µA
SS high voltage
VOH-SS
3.9
4.0
4.1
V
Pulse-by-pulse current
limit threshold
VCS-PP
1.26
1.4
1.54
V
CURRENT
PROTECTION
Delay to OUT pins *
OUTPUT
High voltage
2
Test Conditions
SS = 1 V
Tpd-cs
—
40
80
ns
CS = 0 V to 1.57 V
VOH-OUT
4.3
4.8
—
V
IOUT = –5 mA
Low voltage
VOL-OUT
—
0.1
0.4
V
IOUT = 5 mA
Rise time
tr
—
5
15
ns
COUT = 33 pF
tf
—
5
15
ns
COUT = 33 pF
TD4
—
3
20
ns
Fall time
Timing offset *
3
Notes: 1. Reference values for design. Not 100% tested in production.
2. Tpd-cs is defined as;
1.57 V
50%
CS
0
50%
OUT-C/D
Tpd-cs
3. TD4 is defined as;
OUT-D
OUT-C
50%
OUT-E
50%
TD4
REJ03D0914-0100 Rev.1.00 Sep 29, 2008
Page 7 of 27
50%
OUT-F
50%
TD4
R2A20121SP
Timing Diagram
Note: All voltage, current, time shown in the diagram is typical value.
Full Bridge and Secondary Control
COMP
RAMP + 1.135 V
(Internal signal)
1.135 V
RAMP
CS
TD1
TD1
OUT-A
OUT-B
OUT-C
TD2
TD2
OUT-D
TD3
OUT-E
TD3
OUT-F
VIN
OUT-A
DRIVE
MA
MC
DRIVE
OUT-C
OUT-B
DRIVE
MB
MD
DRIVE
OUT-D
RAMP
DRIVE
OUT-E
External Power Stage
REJ03D0914-0100 Rev.1.00 Sep 29, 2008
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ME MF
DRIVE
OUT-F
R2A20121SP
Start-up and Shutdown
8.4 V
8V
VCC
5V
VREF
0V
RES
(Internal signal)
VREF GOOD
(Internal signal)
32 counts
High
Low
4.0 V
SS
0V
DISCHARGE
(Internal signal)
High
Low
From Error Amp
COMP
COMPARATOR
−
+
FOR PHASE MODULATION
1.135 V
RAMP
Current information
CLAMP
VREF
4.0 V
SS
Iss
10 µA
SS IN
Css
DISCHARGE
Soft-start Block
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Page 9 of 27
R2A20121SP
Functional Description
Note: All voltage, current, time shown in the diagram is typical value unless otherwise noted.
UVLO
UVLO (Under Voltage Lockout Operation) is a function that halts operation of the IC in the event of a low IC power
supply voltage. When IC operation is halted, the 5 V internal voltage generation circuit (VREF) halts, and therefore
operation of circuitry using VREF as the operating power supply halts.
Circuit blocks other than UVLO use VREF as their operating power supply. Therefore, the power supply current of the
IC becomes equal to the current dissipated by the UVLO circuit. The following graphs show the relationship between
the VCC input current and VCC input voltage, and between VREF and the VCC input voltage.
ICC
ICC
Is
VCC
0
7.5 V 8.0 V 8.4 V
0
8.0 V 8.4 V
12 V
20 V
VREF
5V
VCC
20 V
Figure 1
Start-up Counter
When the VREFGOOD signal (internal signal) goes to the logic low level, the R2A20121 starts operating as a
controller. The VREFGOOD signal is created from VREFGOOD circuit output via a 32-clock startup counter.
VCC
H
L
VREF
5V
Generator
UVLO
From Oscillator
VREF
GOOD
H
L
VREF GOOD
Start-up
Counter
32 clock
Circuit Bias
Figure 2
Therefore, the start of IC operation is a 32-count later than UVLO release. When the oscillator frequency is set to 1
MHz, this represents a delay of 32 µs. This delay enables operation to be halted until VREF (5 V) stabilizes when
UVLO is released. Note that the start-up counter operates when VREF rises is performed, but does not operate when
VREF falls is performed (there is no logic delay due to the start-up counter).
8.4 V
8.0 V
VCC
4.6 V
VREF
4.4 V
32 counts
RES
(Internal signal)
VREF GOOD
(Internal signal)
Start of operation
Figure 3
REJ03D0914-0100 Rev.1.00 Sep 29, 2008
Page 10 of 27
Operation halted
R2A20121SP
Oscillator
The oscillation frequency of the oscillator is set by means of a resistance connected between the RT pin and GND. The
following graph shows the relationship between the external resistance and the oscillation frequency. The typical value
of the oscillation frequency is given by the following equation.
1
25 [pF] × RT [Ω] + 150 [ns]
fosc =
[Hz]
fosc vs. RT
10000
R2A20121
fosc (kHz)
SYNC
1000
(2.7 V)
RT
GND
100
RT
10
10
100
RT (kΩ)
1000
Figure 4
Place the resistor for connection to the RT pin as close to the pin as is possible. Please design the pattern so that the
level of cross-talk from other signals is minimized.
Synchronized Operation
Parallel synchronized operation is possible by connecting the SYNC pins of R2A20121s. In this case, up to four slave
ICs can be connected to one master IC. A value of at least twice the master RT value should be set for the slave IC RT
values.
R2A20121
SLAVE
R2A20121
MASTER
(2.7 V)
RT
RT
SYNC
SYNC
RT
(2.7 V)
2 × RT
GND
GND
R2A20121
SLAVE
SYNC
RT
GND
Max 4 slaves
Figure 5 Parallel Synchronized Operation
REJ03D0914-0100 Rev.1.00 Sep 29, 2008
Page 11 of 27
(2.7 V)
2 × RT
R2A20121SP
External synchronized operation is possible by supplying a synchronization signal to the SYNC pins of R2A20121s. In
this case, a frequency not exceeding 1/2 that of the master clock should be set for the R2A20121s.
A maximum master clock frequency of 2 MHz should be used. See the figure below for the input waveform conditions.
R2A20121
SLAVE
TTL or CMOS
MASTER
MASTER CLOCK
SYNC
RT
(2.7 V)
GND
RT
R2A20121
SLAVE
SYNC
RT
(2.7 V)
GND
RT
Figure 6 External Synchronized Operation
TCYCLE
Item
TI-MIN
TIH-SYNC
TIL-SYNC
500 ns Min
TI-MIN
50 ns Min
TIL-MIN
100 ns Min
VIH-SYNC
3.2 V to VREF
VIL-SYNC
0 V to 2.5 V
TIL-MIN
Figure 7 SYNC Pin Input Conditions
REJ03D0914-0100 Rev.1.00 Sep 29, 2008
Page 12 of 27
Input Range
TCYCLE
R2A20121SP
Noise Margin
When a synchronization signal is given to an SYNC terminal of the R2A20121, the oscillation frequency of the IC may
occur abnormality by the slew rate of the synchronization signal and the noise level of the VREF terminal.
The following graph shows the relationship between the slew rate of the synchronization signal and the VREF noise
level.
In the case of synchronized operation, a VREF capacitor should be chosen with reference to the following graph.
R2A20121 Noise Margin
11
10
SYNC Slew Rate [V/µs]
9
8
Area of normal operation
7
6
5
4
3
2
1
0
100
150
200
250
300
VREF Noise Level [mVp-p]
350
Note: The upper graph is a measurement result by our evaluation jig.
Please confirm enough evaluation because the influence of the noise is different with each board.
REJ03D0914-0100 Rev.1.00 Sep 29, 2008
Page 13 of 27
400
R2A20121SP
RAMP Capacitance Setting Method
The following graph shows the relationship between the RAMP capacitance and discharge time.
A RAMP capacitance should be chosen with reference to the following graph.
R2A20121 Discharge Time vs. RAMP Capacitance
140
120
Discharge Time [ns]
100
80
60
40
20
RAMP Capacitance [pF]
REJ03D0914-0100 Rev.1.00 Sep 29, 2008
Page 14 of 27
1500
1400
1300
1200
1100
1000
900
800
700
600
500
400
300
200
100
0
0
R2A20121SP
Synchronous Phase Shift Full-Bridge Control
The R2A20121 is provided with full-bridge control outputs OUT-A through OUT-D, and secondary-side synchronous
rectification control outputs OUT-E and OUT-F. ZVS (Zero Voltage Switching) can be performed by adjusting timing
delays TD1 and TD2 between the OUT-A through OUT-D outputs by means of an external resistance. OUT-E and
OUT-F have an output timing suitable for secondary-side full-wave rectification, and so can be used in either current
doubler or center tap applications. The following figure shows full-bridge ZVS + current doubler operation using an
ideal model.
RES pulse
(Internal signal)
SA
Full-Bridge
control switch
(on when high)
TD1
SB
SC
TD2
SD
Synchronous
rectification
control switch
(on when high)
Transformer
primary
both-side
voltage
SE
TD3
SF
VIN
0
−VIN
Transformer VIN/N
secondary
0
−VIN/N
both-side
voltage
Subinterval :
Time :
1
t0
2
t1
3
t2
4
t3
5
t4
t5
Figure 8
• Subinterval: 1
In interval 1, SA and SD are turned on, and VIN is generated on the transformer primary side. On the transformer
secondary side, a value proportional to the winding ratio is generated, and the primary-side power is transmitted to
the load side.
At this time, secondary-side switch SE is off and SF is on.
L1
VIN
SA
SE
SC
V11
V12
VOUT
Lr
Cr1
SB
SD
Cr2
SF
L2
Subinterval: 1
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R2A20121SP
• Subinterval: 2
As SD is turned off at point t1, the primary-side current flows into resonant capacitance Cr2. At this time Cr2 is
charged, and therefore the potential of V12 rises. Considering that the exciting current and the L1 and L2 ripple
currents are considerable smaller than Io, the following is an approximate equation for the slope of V12.
dV12
dt
=
0.5 Io
N
•
1
Cr2
[ V/s ] …………………… (1)
Here, N is the ratio of the primary coil to the secondary coil (N = N1/N2), and Io is the output current.
As SE and SF are on, the transformer secondary side is in the shorted state, and the value of the current flowing up
to that time is retained.
L1
VIN
SA
SE
SC
V11
V12
VOUT
Lr
Cr1
SB
SD
Cr2
SF
L2
Subinterval: 2
• Subinterval: 3
SC is turned on at point t2. ZVS operation can be attained by setting the SD off (t1) → SC on (t2) delay to the
optimal value. This delay time can be expressed by equation (2).
TD2 =
N
0.5 Io
• Cr2 • VIN
[s] …………………… (2)
After SC is turned on, the transformer primary side is in the shorted state, and therefore the current value
immediately after SC was turned on is retained.
L1
VIN
SA
SE
SC
V11
V12
VOUT
Lr
Cr1
SB
SD
Cr2
SF
L2
Subinterval: 3
• Subinterval: 4
As SA is turned off at point t3, the primary-side current discharges resonant capacitance Cr1, and the potential of
V11 falls. A negative potential is applied to resonant inductor Lr, and a flux reset starts. At this time, since the series
resonance circuit is composed of Cr1 and Lr, the V11 waveform changes to a sine wave. The resonance frequency is
given by equation (3).
fr =
1
[Hz] …………………… (3)
2 π √ (Cr1 • Lr)
L1
VIN
SA
SE
SC
V11
V12
VOUT
Lr
Cr1
SB
SD
Cr2
SF
L2
Subinterval: 4
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R2A20121SP
• Subinterval: 5
When synchronous switch SF is turned off at point t4, the current flowing in SF up to that time continues to flow
through the SF body diode. SF turn-off must be performed before completion of the resonant inductor Lr flux reset.
If SF is not off on completion of the Lr flux reset, power transmission will be performed with the transformer
secondary-side shorted, and therefore an excessive current will flow in the transformer primary and secondary sides,
and parts may be damaged.
Also, if the SF body diode is on for a long period, loss will be high. Therefore, optimal timing should be set by
means of the R2A20121's delay adjustment pin, DELAY-3.
Lr reset time tr is given by equation (4) when the resonance voltage peak value is within the input voltage.
Treset (Lr) | vpp ≤ VIN =
1
1
•
fr
4
= 0.5 π
√ (Lr • Cr1)
[s] ………… (4)
Here, vpp is the resonance voltage peak value.
vpp =
Io
2
•
1
•
N
√ (Lr / Cr1)
[V] …………………… (5)
L1
VIN
SA
SE
SC
V11
V12
VOUT
Lr
Cr1
SB
SD
Cr2
SF
L2
Subinterval: 5
• Time: t5
SB is turned on at point t5. The SB switching loss can be minimized by turning on SB when the SB both-side
voltages are at a minimum (when the resonance voltage is at a peak). The SB turn-on timing can be set with TD1 of
the R2A20121. The time when the resonance voltage is at a peak is given by equation (4).
From t5 onward, operation is on the same principle as in Subinterval 1 through Subinterval 5.
L1
VIN
SA
SE
SC
V11
V12
VOUT
Lr
Cr1
SB
SD
Cr2
SF
L2
Time: t5
REJ03D0914-0100 Rev.1.00 Sep 29, 2008
Page 17 of 27
R2A20121SP
Delay Setting
Inter-output delays (TD1, TD2, TD3) are set by means of a resistance connected between the DELAY-1 (-2, -3) pin and
GND. The following graph shows the relationship between the external resistance and delay. The typical value of the
delay set time is given by the following equation.
TD = 0.5 [pF] × RD [Ω] + 8 [ns]
[s]
When the RD value is small, the set time will be larger than the above calculated value due to the effect of internal
delay, etc., and therefore a constant setting should be made with reference to the following graph.
TD (ns)
R2A20121
TD vs. RD
1.00E+03
1.00E+02
(2.0 V)
1.00E+01
RD
1.00E+00
DELAY-1
(DELAY-2)
(DELAY-3)
GND
1
10
1000
100
RD (kΩ)
Figure 9
Place the resistor for connection to the DELAY-1,2,3 pin as close to the pin as is possible. Please design the pattern so
that the level of cross-talk from other signals is minimized.
DELAY-3 (TD3)
There is a condition that secondary-side control output OUT-E and OUT-F delay TD3 is 0 s (typical) in order to prevent
shorting of the transformer secondary side. The relationship between TD3 and the IC operating state is shown in the
following table.
Mode
Light load
Pulse by pulse OCL
Definition
COMP < 1.55 V
CS ≥ 1.4 V
Operation of OUT-E, OUT-F
TD3 = 0
TD3 = 0
Notes
1, 3
2, 3
Notes: 1. Light-load detection is performed by means of the error amplifier output voltage. Light-load detection
characteristics are as shown in the following diagram.
VREF
Error
Light Load
500 µ
Amp.
TD3
Detector
−
FB (−)
−
TD3
+
+
set value
FB (+)
COMP
−
Comparator
+
RAMP
1.135 V
0
1.46 V 1.55 V
COMP
voltage
Light Load Detector Characteristics
2. TD3 of the next OUT-E or OUT-F after the pulse-by-pulse current limiter (PBP OCL) operates is 0 s (typical).
When OUT-C and OUT-D are subsequently inverted by the Phase Shift Comparator, not the PBP OCL, TD3
is restored to the value set by means of the DELAY-3 pin.
3. If once the SS terminal is not exceed 3.9 V after an IC started, the IC continues maintaining a state in TD3 =
0. When an external part is attached to the SS terminal, please be careful.
REJ03D0914-0100 Rev.1.00 Sep 29, 2008
Page 18 of 27
R2A20121SP
Application
Note: All voltage, current, time shown in the diagram are typical value.
Sample application circuits are given here. Confirmatory experiments should be carried out when applying these
examples to products.
Slope Compensation
In order to improve the unstable operation characteristic of current mode, voltage slopes in a current sense signal can be
superimposed. The following is a possible slope compensation method.
R2A20121
5 V (VREF)
OUT-A
OUT-B
OUT-D
OUT-C
Comparator
−
+
1.135 V
Current sense signal
Compensated signal
RAMP
S
Q
R
RES
Figure 10
Driving a Pulse Transformer
OUT-A through OUT-F of this IC are CMOS outputs that use Vref as their power supply. When directly driving a pulse
transformer, the Vref voltage fluctuates according to the exciting current. As Vref fluctuation may make internal circuit
operation unstable, direct drive of a pulse transformer should be avoided.
• Case 1 (NG)
The figure below shows a case where a pulse transformer is driven directly. Vref voltage fluctuation occurs due to
the exciting current.
R2A20121
Vref value fluctuates due to
this exiting current
Vref
Cref
Internal
Circuitry
OUT-E
Case 1 (NG)
• Case 2
The figure below shows an example in which a current amplifier is added by means of transistors. A reverse current
due to the exciting current is prevented by a blocking diode, and therefore capacitance CB is charged. In this way,
fluctuation of the Cref potential is suppressed and stable operation can be achieved.
As well as a buffer implemented by means of a transistor, standard logic IC or buffer IC connection is also possible.
The buffer circuit power supply method should be implemented in the same way.
Blocking diode
R2A20121
CB
Vref
Cref
Internal
Circuitry
OUT-E
Case 2
REJ03D0914-0100 Rev.1.00 Sep 29, 2008
Page 19 of 27
R2A20121SP
• Case 3
The figure below shows an example of a drive power supply method using emitter following. For the same reason as
described above, fluctuation of the Cref potential is suppressed and stable operation can be achieved.
VCC
R2A20121
CB
VREF
Cref
Internal
Circuitry
OUT-E
Case 3
Supplying Power from an External Power Supply
It is also possible to use an external source as the power supply for the R2A20121 as shown in figure 11. The
VREFGOOD circuit controls whether the IC is operating or stopped. The threshold voltage of the VREFGOOD circuit
is 4.6 V (typ.) on the rising edge and 4.4 V on the falling edge. Since the IC’s characteristics vary with the value of the
external voltage, this voltage must be provided by a high-precision 5-V source.
Vcc
Vext
5 V ± 2%
VREF
R2A20121
Figure 11
REJ03D0914-0100 Rev.1.00 Sep 29, 2008
Page 20 of 27
R2A20121SP
Characteristic Curves
UVL Voltage vs. Ambient Temperature Characteristics
9.0
8.8
VH
[V]
8.4
VH/VL
8.6
8.2
VL
8.0
7.8
7.6
7.4
−40
−25
0
25
50
Ta
75
100
125
[°C]
Standby Current vs. Ambient Temperature Characteristics
140
Vcc = 7.5 V
120
100
Is [µA]
80
60
40
20
0
−40
−25
0
25
50
Ta
REJ03D0914-0100 Rev.1.00 Sep 29, 2008
Page 21 of 27
[°C]
75
100
125
R2A20121SP
Operating Current vs. Ambient Temperature Characteristics
12
10
Icc [mA]
8
6
4
2
0
−40
−25
0
25
50
Ta
75
100
125
[°C]
VREF Output Voltage vs. Ambient Temperature Characteristics
5.20
5.15
5.10
VREF [V]
5.05
5.00
4.95
4.90
4.85
4.80
−40
−25
0
25
50
Ta
REJ03D0914-0100 Rev.1.00 Sep 29, 2008
Page 22 of 27
[°C]
75
100
125
R2A20121SP
Error Amplifier Offset Voltage vs. Ambient Temperature Characteristics
10.0
8.0
[mV]
6.0
4.0
Vos
2.0
0.0
−2.0
−4.0
−6.0
−40
−25
0
25
50
Ta
75
100
125
[°C]
Error Amplifier Source Current vs. Ambient Temperature Characteristics
−100
FB (+) = 1.25 V, FB (−) = 0.75 V, COMP = 2 V
[µA]
−300
ISOURCE
−200
−400
−500
−600
−700
−40
−25
0
25
50
Ta
REJ03D0914-0100 Rev.1.00 Sep 29, 2008
Page 23 of 27
[°C]
75
100
125
R2A20121SP
Error Amplifier Sink Current vs. Ambient Temperature Characteristics
20
FB (+) = 1.25 V, FB (−) = 1.75 V, COMP = 2 V
18
16
ISINK
[mA]
14
12
10
8
6
4
2
0
−40
−25
0
25
50
Ta
75
100
125
[°C]
Soft-start Pin Current vs. Ambient Temperature Characteristics
−5
SS = 1 V
−6
−7
[µA]
−8
−9
Iss
−10
−11
−12
−13
−14
−15
−40
−25
0
25
50
Ta
REJ03D0914-0100 Rev.1.00 Sep 29, 2008
Page 24 of 27
[°C]
75
100
125
R2A20121SP
Switching Frequency vs. Ambient Temperature Characteristics
580
560
540
fsw [kHz]
520
500
480
460
440
420
400
380
−40
−25
0
25
50
Ta
75
100
125
100
125
[°C]
TD1 Delay vs. Ambient Temperature Characteristics
50
45
40
TD1 [ns]
35
30
25
20
15
−40
−25
0
25
50
Ta
REJ03D0914-0100 Rev.1.00 Sep 29, 2008
Page 25 of 27
[°C]
75
R2A20121SP
Current Sense Delay Time vs. Ambient Temperature Characteristics
70
60
Tpd [ns]
50
40
30
20
10
0
−40
−25
0
25
Ta
50
[°C]
75
100
125
Overcurrent Protection Delay Time vs. Ambient Temperature Characteristics
100
Tpd_cs
[ns]
80
60
40
20
0
−40
−25
0
25
50
Ta
REJ03D0914-0100 Rev.1.00 Sep 29, 2008
Page 26 of 27
[°C]
75
100
125
R2A20121SP
Package Dimensions
JEITA Package Code
P-TSSOP20-4.4x6.5-0.65
RENESAS Code
PTSP0020JB-A
*1
Previous Code
TTP-20DAV
MASS[Typ.]
0.07g
D
F
20
NOTE)
1. DIMENSIONS"*1 (Nom)"AND"*2"
DO NOT INCLUDE MOLD FLASH.
2. DIMENSION"*3"DOES NOT
INCLUDE TRIM OFFSET.
11
c
HE
*2
E
bp
Terminal cross section
( Ni/Pd/Au plating )
Index mark
Reference Dimension in Millimeters
Symbol
1
e
bp
L1
x
M
A
Z
10
*3
A1
θ
L
y
Detail F
REJ03D0914-0100 Rev.1.00 Sep 29, 2008
Page 27 of 27
D
E
A2
A1
A
bp
b1
c
c1
θ
HE
e
x
y
Z
L
L1
Min Nom Max
6.50 6.80
4.40
0.03 0.07 0.10
1.10
0.15 0.20 0.25
0.10 0.15 0.20
0°
8°
6.20 6.40 6.60
0.65
0.13
0.10
0.65
0.4 0.5 0.6
1.0
Sales Strategic Planning Div.
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