Renesas HA16150T High-speed current mode push-pull pwm control ic Datasheet

HA16150T/P
High-Speed Current Mode
Push-Pull PWM Control IC
REJ03F0146-0300
Rev.3.00
Jan 30, 2007
Description
The HA16150 is a high-speed current mode PWM control IC with push-pull dual outputs, suitable for high-reliability,
high-efficiency, high-mounting-density isolated DC-DC converter and high-output AC-DC converter control.
The HA16150 can be used in various applications, including push-pull converters and half-bridge, double-forward, and
single-forward applications.
The HA16150 incorporates 180-degree phase-inverted push-pull dual outputs, and directly drives a power MOS FET.
Operation at a maximum of 1 MHz is possible on an oscillator reference frequency.
The package lineup comprises an ultra-thin surface-mount TSSOP-16 suitable for slim communication system modules,
and a general-purpose insertion DILP-6 suitable for characteristics evaluation.
Features
<Maximum Ratings>
 Supply voltage Vcc: 20 V
 Peak output current Ipk-out: ±1.0 A
 Operating junction temperature Tjopr: –40°C to +125°C
<Electrical Characteristics>
 VREF output voltage VREF: 5.0 V ± 1%
 UVLO start threshold VH: 9.3 V ± 0.7 V
 UVLO shutdown threshold VL: 8.3 V ± 0.7 V
 Operating current Icc: 4 mA typ.
 Standby current Is: 150 µA typ.
<Functions>
 Soft start (one external timing capacitance)
 Remote on/off control
 Independent dead band time adjustment
 Current limiter adjustment (set drooping characteristic adjustment)
 Push-pull/single-end output switching
 Package lineup: TSSOP-16/DILP-16
Rev.3.00 Jan 30, 2007 page 1 of 24
HA16150T/P
Pin Arrangement
INP
1
16
VREF
INM
2
15
REMOTE
EOUT
3
14
VCC
CSLIM
4
13
OUT2
CS
5
12
PGND
RT
6
11
OUT1
CT
7
10
TDB
SS
8
9
SGND
(Top view)
Pin Functions
Pin No.
Pin Name
Pin Functions
1
2
INP
INM
Error amplifier non-inverted (+) input
Error amplifier inverted (–) input
3
4
EOUT
CSLIM
Error amplifier output
Current limiter level adjustment
5
6
CS
RT
Current sense signal input
Operating frequency setting resistance connection
7
8
CT
SS
Operating frequency setting capacitance connection
Soft start time setting timing capacitance connection
9
10
SGND
TDB
Small signal system ground
Dead band time setting timing capacitance connection
11
12
OUT1
PGND
Power MOS FET driver output 1
Power system ground
13
14
OUT2
VCC
Power MOS FET driver output 2
Supply voltage
15
16
REMOTE
VREF
Remote on/off control
Reference voltage
Rev.3.00 Jan 30, 2007 page 2 of 24
HA16150T/P
Block Diagram
VREF
16
VCC
14
VREF
22.2V
300µA
Vref
Generator
UVL
REMOTE 15
REMOTE
Comp.
VREF
1.1V
Vref good
Vref
Good
Vref good
R
Q
S
Q
UVL
TDB
Comp.
0.5V
Single End
Comp.
5µA
10 TDB
SS 8
SS Comp.
S
Q
R
Q
4V
TDB
Latch
Vcc
SS Ramp
Vref good
SS
Ramp
11 OUT1
CT
PGND
VREF
VREF
RT 6
D
Driver
Vcc
Q
CK Q
CT 7
13 OUT2
1/2 Divider
Vref good
12 PGND
Oscillator
R
Q
S
Q
Blanking
Pulse
IN
CS
Latch
Vcc
OUT
5 CS
VREF
CS Comp.
400µA
2R
INM 2
R
(VCOMP-2VF)/3
9 SGND
E-Amp.
INP 1
1.4V
3
4
EOUT
CSLIM
Rev.3.00 Jan 30, 2007 page 3 of 24
65ns
Blanking Enable
Comp.
HA16150T/P
Absolute Maximum Ratings
(Ta = 25°C)
Item
Power supply voltage
Symbol
Ratings
20
Unit
V
Vcc
OUT1 output current (peak)
OUT2 output current (peak)
Ipk-out1
Ipk-out2
±1.0
±1.0
A
A
OUT1 output current (DC)
OUT2 output current (DC)
Idc-out1
Idc-out2
±0.1
±0.1
A
A
OUT1 output voltage
OUT2 output voltage
Vout1
Vout2
–0.3 to Vcc
–0.3 to Vcc
V
V
INM pin voltage
REMOTE pin voltage
Vinm
Vremote
–0.3 to Vcc
–0.3 to Vcc
V
V
REMOTE pin current
INP pin voltage
Iremote
Vinp
+0.2
–0.3 to Vcc
mA
V
SS pin voltage
RT pin voltage
Vss
Vrt
–0.3 to Vref
–0.3 to Vref
V
V
RT pin current
CT pin voltage
Irt
Vct
–0.2
–0.3 to Vref
mA
V
CSLIM pin voltage
EOUT pin voltage
Vcslim
Veout
–0.3 to Vref
–0.3 to Vref
V
V
VREF pin voltage
TDB pin voltage
Vref
Vtdb
–0.3 to Vref
–0.3 to Vref
V
V
CS pin voltage
Operating junction temperature
Vcs
Tj-opr
–0.3 to Vref
–40 to +125
V
°C
Storage temperature
Tstg
–55 to +150
Notes: 1. Rated voltages are with reference to the GND (SGND, PGND) pin.
2. For rated currents, inflow to the IC is indicated by (+), and outflow by (–).
3. Shows the transient current when driving a capacitive load.
4. HA16150T (TSSOP):
θja = 250°C/W
This value is based on actual measurements on a 110% wiring density
glass epoxy circuit board (55 mm × 45 mm × 1.6 mm).
HA16150P (DILP):
θja = 124°C/W
Rev.3.00 Jan 30, 2007 page 4 of 24
°C
Note
3
3
4
HA16150T/P
Electrical Characteristics
(Ta = 25°C, Vcc = 12 V, Fosc = 100 kHz)
Supply
VREF
Oscillator
PWM
Comparator
Error
amplifier
Current
sense
Remote
Item
Start threshold
Symbol
VH
Min
8.6
Typ
9.3
Max
10.0
Unit
V
Shutdown threshold
UVLO hysteresis
VL
dVUVL
7.6
0.7
8.3
1.0
9.0
1.3
V
V
Start-up current
Operating current
Is
Icc
100
–
150
4
250
6
µA
mA
Vcc zenner shunt
voltage
Vz temperature
stability
Vz
21.2
22.2
23.2
V
dVz/dTa
–
4.5
–
mV/°C
Output voltage
Line regulation
Vref
Vref-line
4.95
–
5.0
5
5.05
20
V
mV
Load regulation
Temperature
stability
Vref-load
dVref/dTa
–
–
5
80
20
–
mV
ppm/°C
Oscillator frequency
fosc
88
100
112
kHz
Temperature
stability
dfosc/dTa
–
±0.1
–
%/°C
High voltage
Low voltage
Vth
Vtl
–
–
3.0
2.0
–
–
V
V
DC *
1
DC *
Differential voltage
Input bias current
dVt
Ifb
–
–1
1.0
–
–
+1
V
µA
DC *
Open loop gain
EOUT sink current
Av
Isnk-eout
–
–
70
3.0
–
–
dB
mA
f = 1.0kHz *
1
Veout = 1.1V *
EOUT source
current
Low voltage
Isrc-eout
–
–0.4
–
mA
Veout = 3.0V *
Vol-eout
–
0.8
1.1
V
EOUT : Open
High voltage
Voltage gain
Voh-eout
Avcs
4.7
2.85
5.0
3.00
–
3.15
V
V/V
EOUT : Open
Delay to output
Leading edge
blanking
time
td-cs
tbl
–
–
150
65
230
–
ns
ns
*
Leading edge
blanking
disable voltage
On threshold
voltage
Vbl-off
1.3
1.4
1.5
V
Measured pin : EOUT
Von
1.40
–
–
V
*
Voff
–
–
3.00
V
*
Iremote
60
90
120
µA
Vremote = 4V
–7.0
–5.0
–3.0
µA
Vss = 1V
Off threshold
voltage
Sink current
Soft start
Source current
Iss
Note: 1. Reference values for design.
Rev.3.00 Jan 30, 2007 page 5 of 24
Test Conditions
Vcc = 8V
Vinm = 1.0V, Vinp = 1.25V,
Vcs = 0V
Icc = 10mA
1
Icc = 10mA *
Iref = –1mA
Vcc = 11V to 18V
Iref = –1mA to –20mA
Ta = –40 to 125°C
Measured at OUT1 and OUT2
RT = 27kΩ, CT = 1000pF
1
Ta = –40 to 125°C *
1
1
1
1
1
1
1
HA16150T/P
Electrical Characteristics (cont.)
(Ta = 25°C, Vcc = 12 V, Fosc = 100 kHz)
OUT1
OUT2
Dead-band
time
Note:
Item
Minimum duty cycle
Symbol
Dmin-out1
Min
–
Typ
–
Max
0
Unit
%
Test Conditions
Veout = 0V
Maximum duty
cycle
Rise time
Dmax-out1
48
49
–
%
TDB : OPEN
tr-out1
–
30
65
ns
CL = 1000pF
Fall time
Low voltage
tf-out1
Vol1-out1
–
–
30
0.05
65
0.2
ns
V
CL = 1000pF
Iout = 20mA
High voltage
Vol2-out1
Voh1-out1
–
11.5
0.5
11.9
2.0
–
V
V
Iout = 200mA (pulse)
Iout = –20mA
Minimum duty cycle
Voh2-out1
Dmin-out2
10.0
–
11.0
–
–
0
V
%
Iout = –200mA (pulse)
Veout = 0V
Maximum duty
cycle
Rise time
Dmax-out2
48
49
–
%
TDB : OPEN
tr-out2
–
30
65
ns
CL = 1000pF
Fall time
Low voltage
tf-out2
Vol1-out2
–
–
30
0.05
65
0.2
ns
V
CL = 1000pF
Iout = 20mA
High voltage
Vol2-out2
Voh1-out2
–
11.5
0.5
11.9
2.0
–
V
V
Iout = 200mA (pulse)
Iout = –20mA
Dead-band time
Voh2-out2
tdb0
10.0
–
11.0
60
–
–
V
ns
Iout = –200mA (pulse)
1
TDB : OPEN *
–
140
–
ns
Ctdb = 47pF *
tdb
1. Reference values for design.
Rev.3.00 Jan 30, 2007 page 6 of 24
1
HA16150T/P
Timing Diagram
1. Start-up Timing
9.3V
8.3V
VCC
VREF
3V
V_CT
2V
RESET
(internal signal)
Q
(internal signal)
Q
(internal signal)
V_TDB term.
V_TDB comp. out
(internal signal)
tdb
tdb
Dead-band pulse
(internal signal)
OUT1
OFF
ON
OFF
ON
OFF
ON
OFF
ON
OFF
ON
OUT2
ON
OFF
ON
OFF
ON
OFF
ON
OFF
ON
OFF
Rev.3.00 Jan 30, 2007 page 7 of 24
ON
HA16150T/P
2. Current Sense
VREF
3V
V_CT
2V
RESET
(internal signal)
Dead-band pulse
(internal signal)
Q
(internal signal)
Q
(internal signal)
V_EOUT
V_CS
V_CS comp.(−)
OUT1
OUT2
Rev.3.00 Jan 30, 2007 page 8 of 24
V_CS comp.(−) = (V_EOUT − 2VF) / 3
HA16150T/P
3. Soft Start
VREF
3V
V_CT
2V
RESET
(internal signal)
V_TDB term.
Dead-band pulse
(internal signal)
V_SS
SS comp. IN+
(internal signal)
SS comp. out
(internal signal)
OUT1
OUT2
Rev.3.00 Jan 30, 2007 page 9 of 24
HA16150T/P
4. Leading Edge Blanking
3V
V_CT
2V
RESET
(internal signal)
Dead-band pulse
(internal signal)
Q
(internal signal)
Q
(internal signal)
V_EOUT
1.4V
V_CS
V_CS comp.(−)
(internal signal)
Blanking pulse
(internal signal)
V_CS comp.(+)
(internal signal)
OUT1
OUT2
Rev.3.00 Jan 30, 2007 page 10 of 24
Blanking Time reset
HA16150T/P
5. Push-Pull/Single-End Switching
(1) Push-pull operation: Leave the TDB pin open or connect a capacitance to GND
3V
V_CT
2V
RESET
(internal signal)
V_TDB term.
Dead-band pulse
(internal signal)
OUT1
OUT2
(2) Single-end operation: Perform pull-up connection of the TDB pin to the VREF pin
3V
V_CT
2V
RESET
(internal signal)
5V
V_TDB term.
Dead-band pulse
(internal signal)
0V
OUT1
OUT2
0V
Rev.3.00 Jan 30, 2007 page 11 of 24
HA16150T/P
Functional Description
1. UVL Circuit
The UVL circuit monitors the Vcc voltage and halts operation of the IC in the event of a low voltage.
The voltage for detecting Vcc has a hysteresis characteristic, with 9.3 V as the start threshold and 8.3 V as the shutdown
threshold.
When the IC has been halted by the UVL circuit, control is performed to fix driver circuit output low, halt VREF output
and the oscillator, and reset the soft start circuit.
9.3V
VCC
8.3V
4.5V
VREF
4.5V
3V
V_CT
2V
V_SS
OUT1
OUT2
Figure 1
2. Remote ON/OFF Circuit
A remote on/off control function is incorporated, enabling the IC to be halted without cutting the supply voltage by
pulling the REMOTE pin up to 3.0 V or higher.
This function halts VREF output and driver output.
At this time the IC enters Remote-OFF mode and IC current dissipation can be decreased. This function can thus be
used for power management, etc.
When remote off control is performed, the soft start circuit is also reset, and therefore a soft start is effected when
restarting, preventing overshoot.
However, when restarting by the remote on control function before the SS pin is completely discharged, soft start
operation may not be performed normally. In such a case, add a circuit to pull the SS pin out in conjunction with a
remote off signal.
SS
REMOTE
100kΩ
Figure 2 Example of Circuit to Pull out SS Pin
Rev.3.00 Jan 30, 2007 page 12 of 24
HA16150T/P
If the remote on/off control function is not used, the REMOTE pin should be permanently pulled down to GND with a
resistance of about 100 kΩ.
The remote on/off control function halts only reference voltage. Other functions will be stopped when the reference
voltage is below 4.5 V (typ.). Large stabilizing capacitance of the VREF pin results in a difference between the timing
of remote off signal and the timing to stop the IC
(1) VREF is halted by REMOTE.
4.5V(Typ)
(2) When VREF is blow 4.5 V(Typ),
other functions are stopped.
CH3: REMOTE
CH4: VREF
CH1: SS
CH2: OUT1
Figure 3 Operation When Remote is Off (Reference Data)
3. Soft Start Circuit
This function gradually increases the pulse width of the OUT pin from 0% duty at start-up to prevent a sudden increase
in the pulse width that may cause problems such as transient stress on external parts or overshoot of the secondary-side
output voltage.
The soft start time can easily be set with a single external capacitance.
V_CT
V_SS
SS comp. IN+
(internal signal)
1.1V
SS comp. out
OUT1
OUT2
Figure 4
Rev.3.00 Jan 30, 2007 page 13 of 24
HA16150T/P
Soft start time tss is determined by SS pin connection capacitance Css and an internal constant, and can be estimated
using the equation shown below.
Soft start time tss is the time until the first pulse is output to the driver output OUT pin after VREF starts up following
UVLO release.
This is equivalent to the time until the SS pin voltage reaches IC-internal SS comparator reference voltage VTL (1.1 V),
and can be calculated using the approximate equation shown below.
Soft start time tss when Css is 1000pF is given by the following equation.
tss =
Css × VTL
=
Iss
1000 [pF] × 1.1 [V]
5 [µA]
≈ 220 [µs]
* Iss: SS pin source current, 5 µA typ.
Note: A soft start circuit operates only once at the start-up of the IC (after the VREF pin voltage is launched and the
VrefGOOD circuit is operated). If the SS pin is lowered to 1.1 V or less after the SS pin becomes once high,
the pulse of OUT1 and OUT2 is not halt. Each duty cycle of OUT1 and OUT2 is fixed to 25%.
4. Dead Band Generation Circuit
"Dead band" refers to the time when both push-pull dual outputs are off.
By setting the dead band time arbitrarily, it is possible to configure a system in which the dual outputs are never on
simultaneously with respect to input and load variations.
V_CT
0.5V
V_TDB
SS comp. out
(internal signal)
OUT1
OUT2
Figure 5
Dead band time tdb is determined by TDB pin connection capacitance Cdb and an internal constant, and can be
estimated using the equation shown below.
Even when the TDB pin is open, the dead band time does not become zero due to floating capacitance of the IC package,
etc. This dead band time is designated tdb0.
Dead band time tdb when Cdb is 47 pF is given by the following equation.
tdb = tdb0 +
47 [pF] × 0.5 [V]
Cdb × Vth
= tdb0 +
300 [µA]
Idb
= 60 [ns] + 78 [ns]
= 138 [ns]
* Idb: TDB pin source current, 300 µA typ.
* Vth: IC-internal TDB comparator reference voltage
Rev.3.00 Jan 30, 2007 page 14 of 24
HA16150T/P
5. Operating Frequency
The operating frequency is adjusted by means of CT and RT.
Adjustment examples are shown in the graph below. This graph shows driver output operating frequencies. The
reference operating frequency generated at the CT pin is twice the driver output frequency.
The driver output operating frequency can be estimated using the approximate equation shown below.
This is only an approximate equation, and the higher the frequency, the greater will be the degree of error of the
approximate equation due to the effects of CT pin voltage overshoot, undershoot and so forth.
When the operating frequency is adjusted, it is essential to confirm operation using the actual system.
8
8
=
3 × CT × RT
3 × C6 × R7
8
=
3 × 470 [pF] × 27 [kΩ]
fosc =
= 210 [kHz]
10000
fosc (RT = 5.1kΩ)
fosc (RT = 10kΩ)
fosc (RT = 27kΩ)
fosc (RT = 75kΩ)
fosc (kHz)
1000
100
0
100
1000
CT (pF)
Figure 6
Rev.3.00 Jan 30, 2007 page 15 of 24
10000
HA16150T/P
6. Current Limiter Level
The drooping characteristic of the power supply output can be adjusted by adjusting the CSLIM pin voltage.
For example, the drooping characteristic can easily be adjusted, as shown in the figure below, by setting VREF to a
divided value with resistances R1 and R2 and connecting adjustment resistance Rx in parallel to R2.
Rx
R2
12k
Vref
16
Vcc
−
+
VREF
R1
15k
5 CS
CS
Comp.
−
+
E-amp.
2R
R
3
EOUT
4
CSLIM
Figure 7 CSLIM Peripheral Circuit
The graph below shows examples of power supply output drooping characteristic adjustment in a push-pull converter.
As shown in this graph, the point at which the power supply output current limit begins to be applied can be adjusted by
adjustment of the CSLIM pin voltage.
3.60
Rx: 24k
(VCSLIM = 1.75V)
3.40
Rx: 33k
(VCSLIM = 1.85V)
Rx: open
(VCSLIM = 2.22V)
Vout (V)
3.20
3.00
2.80
Rx: 47k
(VCSLIM = 1.95V)
Rx: 15k
(VCSLIM = 1.55V)
2.60
2.40
2.20
2.00
0.0
2.0
4.0
6.0
8.0
10.0
Iout (A)
Figure 8 Adjustment of Power Supply Output Drooping Characteristic
Rev.3.00 Jan 30, 2007 page 16 of 24
HA16150T/P
7. VREF Circuit
(1) For the VREF pin, make sure to connect stabilizing capacitance to GND.
(2) When the value of stabilizing capacitance is small or the load of VREF pin is heavy, either OUT1 or OUT2 may be
halted at high level if the IC is stopped by a remote off function. In such a case, increase the capacitance value. The
minimum value of capacitance to be connected is approximated by the following equation.
Cref >
10µs × (Iref + 6mA)
4.95V
(3) Depending on the value of capacitance to be connected, overshoot may result at the rising of the VREF pin (see the
figure below). Take extra care when the VREF pin voltage is used as the power supply and reference voltage of
external circuit.
Overshoot voltage (V)
1.0
0.8
0.6
0.4
0.2
0
1E–9
10E–9
100E–9
1E–6
10E–6
Vref pin capacitance (F)
Figure 9 Overshoot Voltage of Vref Pin (Reference Data)
8. CS Pin
RC filter is generally inserted into the CS pin to prevent the pin from malfunction due to noise. The CS pin has an
internal circuit to pull out electric charge while both of the OUT1 and OUT2 are at the low level (dead band time).
However, please be aware that the electric charge may not be pulled out when the duration of dead band time is short
and the filter constant is not appropriate.
Rev.3.00 Jan 30, 2007 page 17 of 24
HA16150T/P
9. Usage on Half-bridge Power Supply
The HA16150 is operated in the current mode. However, the half-bridge power supply becomes unstable in principle
by using current mode control. The HA16150, therefore, cannot be used basically. In order to use the HA16150 with
the half-bridge power supply, add a circuit as shown below and operate the HA16150 in the voltage mode.
VREF
R1
R2
OUT1
Q1
Q2
OUT2
C2
C1
CS input filter
Vslope
R3
Dead Band Time
1/fosc
OUT1
OUT2
(CSLIM – 2VF)
3
CS
Figure 10 Example of Circuit for Voltage Mode Operation
Design the charging circuits for R1 (R2), C1 (C2), Q1 (Q2) and R3 so that the peak voltage of CS is lower than
(CSLIM-2VF)/3 at the maximum ON pulse width of OUT1 and OUT2.
Furthermore, set the input filter values between R3 and CS pin so that the CS voltage is discharged assuredly while both
of the OUT1 and OUT2 are at low level.
Rev.3.00 Jan 30, 2007 page 18 of 24
HA16150T/P
Characteristic Curves
Power Supply Current vs. Power Supply Voltage Characteristics
6.0
Ta = 25°C
fosc = 100kHz
5.0
Icc (mA)
4.0
3.0
2.0
1.0
0.0
7.0
7.5
8.0
8.5
9.0
9.5
10.0
Vcc (V)
Standby Current vs. Power Supply Voltage Characteristics
1.0
Ta = 25°C
fosc = 100kHz
Is (mA)
0.8
0.6
0.4
0.2
0.0
0
1
2
3
4
5
Vcc (V)
Rev.3.00 Jan 30, 2007 page 19 of 24
6
7
8
9
10
HA16150T/P
Power Supply Current vs. Power Supply Voltage (Clamp Zener Voltage) Characteristics
18.0
Ta = 25°C
16.0 fosc = 100kHz
Icc (mA)
14.0
12.0
10.0
8.0
6.0
4.0
20.0
20.5
21.0
21.5
22.0
22.5
23.0
Vcc (V)
VREF Output Voltage vs. REMOTE Pin Voltage Characteristics
6.0
Ta = 25°C
5.0
VREF (V)
4.0
3.0
2.0
1.0
0.0
0.0
0.5
1.0
1.5
2.0
VREMOTE (V)
Rev.3.00 Jan 30, 2007 page 20 of 24
2.5
3.0
3.5
4.0
HA16150T/P
VREF Output Voltage vs. Ambient Temperature Characteristics
5.20
Iref = 1mA
5.15
VREF (V)
5.10
5.05
5.00
4.95
4.90
4.85
4.80
−50
−25
0
25
50
75
100
125
Ta (°C)
Operating Frequency vs. Ambient Temperature Characteristics
120
RT = 27kΩ
CT = 1000pF
fosc (kHz)
110
100
90
80
−50
−25
0
25
50
Ta (°C)
Rev.3.00 Jan 30, 2007 page 21 of 24
75
100
125
HA16150T/P
UVL Start-up Voltage vs. Ambient Temperature Characteristics
10.0
9.8
9.6
VH (V)
9.4
9.2
9.0
8.8
8.6
8.4
8.2
8.0
−50
−25
0
25
50
75
100
125
Ta (°C)
UVL Shutdown Voltage vs. Ambient Temperature Characteristics
9.0
8.8
8.6
8.4
VL (V)
8.2
8.0
7.8
7.6
7.4
7.2
7.0
−50
−25
0
25
50
Ta (°C)
Rev.3.00 Jan 30, 2007 page 22 of 24
75
100
125
HA16150T/P
Application Circuit Example
The following diagram shows a sample application circuit for a push-pull converter with a 48 V input voltage, 3.3 V
output voltage, and 10 A output current.
L2
1.5µH
R14 R18
680 390
Core : PQ20/16
Bobin : BPQ20/16-1114CP
+
Vin
48V
2T
10T
2T
R15 R19
2k
1k
C12 R17
0.033µ 3.3k
R10
15k
C3
0.1µ
C2
47µ/100V
10T
OUT(+)
+
C13
470µ/10V
R16
5.1k
HA17431VP
OUT(–)
D3
20V
L1
100µ
D2
IS2076A
C9+
4.7µ
C10+
0.1µ
D1
IS2076A
VREF
16
7T
VCC
14
VREF
22.2V
R8
120k
300µA
Vref
Generator
REMOTE
UVL
15
R9
120k
REMOTE
Comp.
Vref good
1.1V
VREF
Vref good
Vref
Good
R
Q
S
Q
UVL
TDB
Comp.
0.5V
Single End
Comp.
5µA
10
TDB
SS
8
C7
1000p
SS Comp.
S
Q
R
Q
4V
TDB
Latch
Vcc
SS Ramp
Vref good
SS
Ramp
11
R12
OUT1 10
H5N2001LS
CT
PGND
VREF
RT
R7
27k
VREF
6
D
CT
Driver
Vcc
Q
CK Q
7
C7
1000p
13
1/2 Divider
Vref good
12
Oscillator
R
Q
S
Q
R11
OUT2 10
PGND
Blanking
Pulse
IN
CS
Latch
Vcc
OUT
CS Comp.
400µA
2R
VREF
INM
R6
5.1k
2
INP
9
E-Amp.
1
1.4V
3
VREF
4
EOUT
CSLIM
R5
5.1k
C4
0.01µ
R1
15k
VREF
R2
12k
C14
6800p
Photo Coupler
Rev.3.00 Jan 30, 2007 page 23 of 24
Blanking Enable
Comp.
R4
1k
CS
C5
680p
R
(VCOMP-2VF)/3
R3
5.1k
65ns
5
VREF
SGND
R13
0.15/2W
HA16150T/P
Package Dimensions
As of January, 2003
19.20
20.00 Max
Unit: mm
1
7.40 Max
9
6.30
16
8
1.3
0.48 ± 0.10
7.62
2.54 Min 5.06 Max
2.54 ± 0.25
0.51 Min
1.11 Max
+ 0.13
0.25 – 0.05
0° − 15°
Package Code
JEDEC
JEITA
Mass (reference value)
JEITA Package Code
P-TSSOP16-4.4x5-0.65
RENESAS Code
PTSP0016JB-B
*1
Previous Code
TTP-16DA
DP-16
Conforms
Conforms
1.07 g
MASS[Typ.]
0.05g
D
F
16
9
NOTE)
1. DIMENSIONS"*1 (Nom)"AND"*2"
DO NOT INCLUDE MOLD FLASH.
2. DIMENSION"*3"DOES NOT
INCLUDE TRIM OFFSET.
bp
c
c1
*2
E
HE
b1
Index mark
Terminal cross section
1
Reference
Symbol
8
*3
Z
bp
x
M
L1
A
e
A1
θ
y
Rev.3.00 Jan 30, 2007 page 24 of 24
L
Detail F
D
E
A2
A1
A
bp
b1
c
c1
θ
HE
e
x
y
Z
L
L1
Dimension in Millimeters
Min Nom Max
5.00 5.30
4.40
0.03 0.07 0.10
1.10
0.15 0.22 0.30
0.20
0.12 0.17 0.22
0.15
0°
8°
6.20 6.40 6.60
0.65
0.13
0.10
0.65
0.40 0.50 0.60
1.0
Sales Strategic Planning Div.
Nippon Bldg., 2-6-2, Ohte-machi, Chiyoda-ku, Tokyo 100-0004, Japan
Notes:
1. This document is provided for reference purposes only so that Renesas customers may select the appropriate Renesas products for their use. Renesas neither makes
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but not limited to, product data, diagrams, charts, programs, algorithms, and application circuit examples.
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destruction or for the purpose of any other military use. When exporting the products or technology described herein, you should follow the applicable export control laws
and regulations, and procedures required by such laws and regulations.
4. All information included in this document such as product data, diagrams, charts, programs, algorithms, and application circuit examples, is current as of the date this
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Colophon .7.0
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