TECHNICAL NOTE
Large Current External FET Controller Type Switching Regulator
Step-down,
High-efficiency
Switching Regulators
(Controller type)
BD9011EKN , BD9011KV , BD9775FV
BD9011EKN, BD9011KV
Overview
The BD9011EKN/KV is a 2-ch synchronous controller with rectification switching for enhanced power management efficiency.
It supports a wide input range, enabling low power consumption ecodesign for an array of electronics.
Features
1) Wide input voltage range: 3.9V to 30V
2) Precision voltage references: 0.8V±1%
3) FET direct drive
4) Rectification switching for increased efficiency
5) Variable frequency: 250k to 550kHz (external synchronization to 550kHz)
6) Built-in selected OFF latch and auto remove over current protection
7) Built-in independent power up/power down sequencing control
8) Make various application , step-down , step-up and step-up-down
9) Small footprint packages: HQFN36V, VQFP48C
Applications
Car audio and navigation systems, CRTTVLCDTVPDPTVSTBDVDand PC systemsportable CD and DVD players,
etc.
Absolute Maximum Ratings (Ta=25)
Parameter Symbol Rating Unit Parameter Symbol Rating Unit
EXTVCC Voltage EXTVCC 34
*1
V COMP1,2 Voltage COMP1,2
VCCCL1,2 Voltage VCCCL1,2 34
*1
V DET1,2 Voltage DET1,2
CL1,2 Voltage CL1,2 34 V RTSYNC Voltage RTSYNC
VREG5 V
SW1,2 Voltage SW1,2 34
*1
V
BOOT1,2 Voltage BOOT1,2 40
*1
V
0.875
*2
HQFN36VW
BOOT1,2-SW1,2
Voltage BOOT1,2-SW1,2 7
*1
V
STB, EN1,2 Voltage STB, EN1,2 VCC V
Power Dissipation Pd
1.1
*2
VQFP48CW
VREG5,5A VREG5,5A 7 V Operating
temperature Topr -40 to +105
VREG33 VREG33 VREG5 V Storage temperature Tstg -55 to +150
SS1,2FB1,2 SS1,2FB1,2 VREG5 V Junction temperature Tj +150
*1 Regardless of the listed rating, do not exceed Pd in any circumstances.
*2 Mounted on a 70mm x 70mm x 0.8mm glass-epoxy board. De-rated at 7.44mW/℃(HQFN36V or 8.8mW/℃(VQFP48C
above 25.
Sep. 2008
2/29
Operating conditions (Ta=25)
Parameter Symbol Min. Typ. Max. Unit
Input voltage 1 EXTVCC 3.9
*1
*2
12 30 V
Input voltage 2 VCC 3.9
*1
*2
12 30 V
BOOTSW voltage BOOTSW 4.5 5 VREG5 V
Carrier frequency OSC 250 300 550 kHz
Synchronous frequency SYNC OSC - 550 kHz
Synchronous pulse duty Duty 40 50 60
Min OFF pulse TMIN - 100 - nsec
This product is not designed to provide resistance against radiation.
*1 After more than 4.5V, voltage range.
*2 In case of using less than 6V, Short to VCC, EXTVCC and VREG5.
Electrical characteristics (Unless otherwise specified, Ta=25 VCC=12V STB=5V EN1,2=5V)
Limit
Parameter Symbol
Min. Typ. Max. Unit Conditions
VIN bias current IIN - 5 10 mA
Shutdown mode current IST - 0 10 μA VSTB=0V
Error Amp Block
Feedback reference voltage VOB 0.792 0.800 0.808 V
Feedback reference voltage
(Ta=-40 to 105) VOB+ 0.784 0.800 0.816 V Ta=-40 to 105
Open circuit voltage gain Averr - 46 - dB
VO input bias current IVo+ - - 1 μA
FET Driver Block
HG high side ON resistance HGhon - 1.5 - Ω
HG low side ON resistance HGlon - 1.0 - Ω
LG high side ON resistance LGhon - 1.5 - Ω
LG low side ON resistance LGlon - 0.5 - Ω
Oscillator
Carrier frequency FOSC 270 300 330 kHz RT=100 kΩ
Synchronous frequency Fsync - 500 - kHz RT=100 kΩ,SYNC=500kHz
Over Current Protection Block
CL threshold voltage Vswth 70 90 110 V
CL threshold voltage
Ta=-40 to 105℃) Vswth+ 67 90 113 V Ta=-40 to 105
VREG Block
VREG5 output voltage VREG5 4.8 5 5.2 V IREF=6mA
VREG33 reference voltage VREG33 3.0 3.3 3.6 V IREG=6mA
VREG5 threshold voltage VREG_UVLO 2.6 2.8 3.0 V VREG:Sweep down
VREG5 hysteresis voltage DVREG_UVLO 50 100 200 mV VREG:Sweep up
Soft start block
Charge current ISS 6.5 10 13.5 μA VSS=1V
Charge current
(Ta=-40 to 105) ISS+ 6 10 14 μA VSS=1V,Ta=-40 to 105
Note: Not all shipped products are subject to outgoing inspection.
3/29
Reference data (Unless otherwise specified, Ta=25)
Fig.1 Efficiency 1
Fig.4 Reference voltage vs.
temperature characteristics
Fig.5 Over current detection vs.
temperature characteristics
Fig.6 Frequency vs.
tem
p
erature characteristics
0
10
20
30
40
50
60
70
80
90
100
0123
OUTPUT CURRENTIo[A]
EFFICIENCY[%]
1.2V
1.8V 2.6V 3.3V
5.0V
VIN=12V
0.784
0.788
0.792
0.796
0.800
0.804
0.808
0.812
0.816
-40 -15 10 35 60 85 110
AMBIENT TEMPERATURE Ta[℃]
RE FE RENC E VOL TAG E VO B[V]
60
70
80
90
100
110
-40 -15 10 35 60 85 110
AMBIENT TEMPERATURE Ta[]
過電流検出電圧 Vswth[mV]
270
280
290
300
310
320
330
-40 -15 10 35 60 85 110
AMBIENT TEMPERATURE : Ta[℃]
OSILATING FREQUENCY : F
OSC
[kHz]
RT=100kΩ
3.00
3.25
3.50
3.75
4.00
4.25
4.50
4.75
5.00
5.25
-40 -15 10 35 60 85 110
AMBIENT TEMPERATURE : Ta[℃]
OUT PUT VOLTAGE : Vo[V]
VREG5
VREG33
Fig.7 Internal Reg vs.
tem
p
erature characteristics
0
10
20
30
40
50
60
70
80
90
100
6 9 12 15 18 21 24
INPUT VOLTAGEV
IN
[V]
EFFICIENCY[%]
3.3V 5.0V
Io=2A
Fig.2 Efficiency 2
0
1
2
3
4
5
6
0 5 10 15 20 25
INPUT VOL TAG E V
IN
[V]
OUT PUT VOLTAGE : Vo[V]
3.3V
5.0V
0.0
0.5
1.0
1.5
2.0
2.5
3.0
0123456
OUTPUT C URRENT: I o [A]
OUT PUT VOLTAGE Vo[V
]
LOFF=
L
LOFF=H
RCL=15mΩ
Fig.8 Line regulation Fig.9 Load regulation
0
1
2
3
4
5
6
0246
INPUT VOLTAGEV
EN
[V]
OUTPUT VOLTAGE Vo[V]
105℃
25℃
-40℃
Fig.10 EN threshold voltage Fig.11 Load transient response 1 Fig.12 Load transient response 2
0
1
2
3
4
5
6
0102030
INPUT VOLTAGE:V
IN
[V]
CIRC UIT CURRE NT[ mA]
105℃ 25℃ -40℃
Fig.3 Circuit current
V
OUT
V
OUT
I
OUT
I
OUT
1A/div
50mV/div
1A/div
50mV/div
4/29
Block diagram (Parentheses indicate VQFP48C pin numbers)
Fig-13
Pin configuration PIN function table
BD9011EKNHQFN36V
Fig-14
Pin
No. Pin name Function
1 SW1 High side FET source pin 1
2 DGND1 Low side FET source pin 1
3 OUTL1 Low side FET gate drive pin 1
4 VREG5A FET drive REG input
5 VREG33 Reference input REG output
6 FB1 Error amp input 1
7 COMP1 Error amp output 1
8 SS1 Soft start setting pin 1
9 DET1 FB detector output 1
10 STB Standby ON/OFF pin
11 EN1 Output 1ON/OFF pin
12 EN2 Output 2ON/OFFpin
13 GND Ground
14 LOFF Over current protection OFF latch
function ON/OFF pin
15 RT Switching frequency setting pin
16 SYNC External synchronous pulse input pin
17 LLM Built-in pull-down resistor pin
18 DET2 FB detector output 2
19 SS2 Soft start setting pin 2
20 COMP2 Error amp output 2
21 FB2 Error amp input 2
22 EXTVCC External power input pin
23 N.C.
24 VREG5 FET drive REG output
25 OUTL2 Low side FET gate drive pin 2
26 DGND2 Low side FET source pin 2
27 SW2 High side FET source pin 2
28 OUTH2 Hi side FET gate drive pin 2
29 BOOT2 OUTH2 driver power pin
30 CL2 Over current detector setting pin 2
31 VCCCL2 Over current detection VCC2
32 VCC Input power pin
33 VCCCL1 Over current detection VCC1
34 CL1 Over current detector setting pin 1
35 BOOT1 OUTH1 driver power pin
36 OUTH1 High side FET gate drive pin 1
OUTH2
28
29
30
31
32
33
34
35
36
BOOT2
CL2
VCCCL2
VCC
VCCCL1
CL1
BOOT1
OUTH1
DET2
18
17
16
15
14
13
12
11
10
LMM
SYNC
RT
LOFF
GND
EN2
EN1
STB
1 2 3
4 5 6 7
8 9
SW1
DGND1
OUTL1
VREG5
A
VREG33
FB1
COMP1
SS1
DET1
27 26 25
24 23 22 21
20 19
SW2
DGND2
OUTL2
VREG5
EXTVCC
FB2
COMP2
SS2
TSD
5V Reg
2.7V
3.3V Reg
TSD
UVLO
PWM
COMP
Err Amp
0.8V
Sequence DET
UVLO
0.56V 0.56V
VREG5
VCCCL2
CL2
BOOT2
OUTH2
SW2
OUTL2
DGND2
FB2
SS2
COMP2
DET2 LOFF EN2 EN1
VREG5A
EXTVCC STB VCC RT
SYNC
Set
Q
Reset
Q
Reset Set
DRV
Set
Reset
VREG5
OCP
UVLO TSD
B.G SYNC
OSC
Slope
PWM
COMP
TSD
UVLO
Q
Set Reset
DRV
Set
Reset
SW
LOGIC
Set
Q
Reset
Sequence DET
Err Amp
0.8V
OCP
Slope
GND DET1
SW
LOGIC
OUTH1
SW1
OUTL1
DGND1
SS1
COMP1
BOOT1
CL1
VCCCL1
VREG33
FB1
5(19)
17(35)
16
(34)
32
(7)
9
(24)
21(39)
24(44)
19(37)
26(47)
33(8)
1(13)
34(10)
36(12)
4(17)
3(15)
2(14)
8(23)
6(21)
7(22)
35(11)
30(3)
31(5)
29(2)
28(1)
27(48)
20(38)
25(46)
22
(41)
10
(25)
15
(33)
13
(29)
11
(26)
12
(27)
14
(31)
18
(36) (30)
(GNDS)
LLM
5/29
40
41
42
43
44
45
46
47
48
36 35 34
33 32 31 30
29 28
1 2 3
4 5 6 7
8 9
10 11 12
OUTH2
BOOT2
CL2
N.C
VCCCL2
N.C
VCC
VCCCL1
N.C
CL1
BOOT1
OUTH1
21
20
19
18
17
16
15
14
13
24
23
22
FB1
N.C
VREG33
N.C
VREG5A
N.C
OUTL1
DGND1
SW1
DET1
SS1
COMP1
27 26 25
37
38
39
N.C
EXTVCC
N.C
N.C
VREG5
N.C
OUTL2
DGND2
SW2
SS2
COMP2
FB2
DET2
LLM
SYNC
RT
LOFF
GNDS
GND
N.C
EN2
EN1
STB
N.C
Pin configuration Pin function table
BD9011KVVQFP48C
Fig-15
Block functional descriptions
Error amp
The error amp compares output feedback voltage to the 0.8V reference voltage and provides the comparison result as COMP voltage, which is
used to determine the switching Duty. COMP voltage is limited to the SS voltage, since soft start at power up is based on SS pin voltage.
Oscillator (OSC)
Oscillation frequency is determined by the switching frequency pin (RT) in this block. The frequency can be set between 250kHz and 550kHz.
SLOPE
The SLOPE block uses the clock produced by the oscillator to generate a triangular wave, and sends the wave to the PWM comparator.
PWM COMP
The PWM comparator determines switching Duty by comparing the COMP voltage, output from the error amp, with the triangular wave from the
SLOPE block. Switching duty is limited to a percentage of the internal maximum duty, and thus cannot be 100% of the maximum.
Reference voltage (5Vreg33Vreg)
This block generates the internal reference voltages: 5V and 3.3V.
External synchronization (SYNC)
Determines the switching frequency, based on the external pulse applied.
Over current protection (OCP)
Over current protection is activated when the VCCCL-CL voltage reaches or exceeds 90mV. When over current protection is active, Duty is low,
and output voltage also decreases. When LOFF=L, the output voltage has fallen to 70% or below and output is latched OFF. The OFF latch
mode ends when the latch is set to STB, EN.
Sequence control (Sequence DET)
Compares FB voltage with reference voltage (0.56V) and outputs the result as DET.
Protection circuits (UVLO/TSD)
The UVLO lock out function is activated when VREG falls to about 2.8V, while TSD turns outputs OFF when the chip temperature reaches or
exceeds 150. Output is restored when temperature falls back below the threshold value.
Pin
No. Pin name Function
1 OUTH2 High side FET gate drive pin 2
2 BOOT2 OUTH2 driver power pin
3 CL2 Over current detection pin 2
4 N.C Non-connect (unused) pin
5 VCCCL2 Over current detection VCC2
6 N.C Non-connect (unused) pin
7 VCC Input power pin
8 VCCCL1 Over current detection CC1
9 N.C Non-connect (unused) pin
10 CL1 Over current detection setting pin 1
11 BOOT1 OUTH1 driver power pin
12 OUTH1 High side FET gate drive pin 1
13 SW1 High side FET source pin 1
14 DGND1 Low side FET source pin 1
15 OUTL1 Low side FET gate drive pin 1
16 N.C Non-connect (unused) pin
17 VREG5A FET drive REG input
18 N.C Non-connect (unused) pin
19 VREG33 Reference input REG output
20 N.C Non-connect (unused) pin
21 FB1 Error amp input 1
22 COMP1 Error amp output 1
23 SS1 Soft start setting pin 1
24 DET1 FB detector output 1
25 STB Standby ON/OFF pin
26 EN1 Output 1 ON/OFF pin
27 EN2 Output 2 ON/OFF pin
28 N.C Non-connect (unused) pin
29 GND Ground
30 GNDS Sense ground
31 LOFF Over current protection OFF latch
function ON/OFF pin
32 N.C Non-connect (unused) pin
33 RT Switching frequency setting pin
34 SYNC External synchronous pulse input pin
35 LLM Built-in pull-down resistor pin
36 DET2 FB detector output 2
37 SS2 Soft start setting pin 2
38 COMP2 Error amp output 2
39 FB2 Error amp input 2
40 N.C Non-connect (unused) pin
41 EXTVCC External power input pin
42 N.C Non-connect (unused) pin
43 N.C Non-connect (unused) pin
44 VREG5 FET drive REG output
45 N.C Non-connect (unused) pin
46 OUTL2 Low side FET gate drive pin 2
47 DGND2 Low side FET source pin 2
48 SW2 High side FET source pin 2
6/29
Application circuit example (Parentheses indicate VQFP48C pin numbers)
Fig-16AStep-DownCout=OS Capacitor
There are many factors(The PCB board layout, Output Current, etc.)that can affect the DCDC characteristics.
Please verify and confirm using practical applications.
Fig-16BStep-DownCout=Ceramic Capacitor
There are many factors(The PCB board layout, Output Current, etc.)that can affect the DCDC characteristics.
Please verify and confirm using practical applications.
SW1
DGND1
OUTL1
VREG5A
VREG33
FB1
COMP1
SS1
DET1
STB
EN1
EN2
GND
LOFF
RT
SYNC
LLM
SW2
DET2
DGND2
OUTL2
VREG5
EXTVCC
FB2
COMP2
SS2
OUTH1
BOOT1
CL1
VCCCL1
VCC
VCCCL2
CL2
BOOT2
OUTH2
100kΩ
0.1uF
1uF
1uF
39kΩ 15000pF
0.1uF
0.33
uF
10
Ω
15mΩ
15mΩ
0.33uF
1uF
39kΩ 15000pF
15kΩ
47kΩ
220uF
(
OS コン
)
220uF
(OS コン)
13kΩ
68kΩ
10uH Vo(5V/3A)
RB051
L-40
RB051
L-40
10uH Vo(3.3V/3A)
SP8K2 SP8K2
VIN(12V)
31
(5)
27
(48)
0.1
uF 0.1
uF
36
(12)
35
(11
)
32
(7)
30
(3)
29
(2)
28
(1)
26
(47)
24
(44)
22
(41)
21
(39)
20
(38)
19
(37)
18
(36)
17
(35)
16
(34)
15
(33)
14
(31)
13
(29)
12
(27)
11
(26)
10
(25)
1
(13)
3
(15)
4
(17)
5
(19)
6
(21)
7
(22)
9
(24)
2
(14)
25
(46)
8
(23)
23
100Ω
1nF1nF
100Ω
RB160
VA- 4 0
RB160
VA- 4 0
33
(8)
34
(10)
100uF
(SLF12565TDK)
(SLF12565TDK)
SW1
DGND1
OUTL1
VREG5A
VREG33
FB1
COMP1
SS1
DET1
STB
EN1
EN2
GND
LOFF
RT
SYNC
LLM
SW2
DET2
DGND2
OUTL2
VREG5
EXTVCC
FB2
COMP2
SS2
OUTH1
BOOT1
CL1
VCCCL1
VCC
VCCCL2
CL2
BOOT2
OUTH2
0.1uF
1uF
1uF
1kΩ 10000pF
0.1uF
0.33
uF
10
Ω
23mΩ
23mΩ
0.33uF
1uF
3.3kΩ 3300pF
20kΩ
43
kΩ
12kΩ
Vo(1.8V/2A)
RB051
L-40
RB051
L-40
10uH Vo(2.5V/2A)
SP8K2 SP8K2
VIN(12V)
31
(5)
27
(48)
0.1
uF 0.1
uF
36
(12)
35
(11
)
33
(8)
32
(7)
30
(3)
29
(2)
28
(1)
26
(47)
24
(44)
22
(41)
21
(39)
20
(38)
19
(37)
18
(36)
17
(35)
15
(33)
14
(31)
13
(29)
1
(13)
3
(15)
4
(17)
5
(19)
6
(21)
7
(22)
9
(24)
2
(14)
25
(46)
8
(23)
23
100Ω
1nF1nF
100Ω
330pF
15kΩ
150Ω
3300pF
330pF
1000pF
510Ω
10uH
RB160
VA-40
RB160
VA-4 0
34
(10)
100uF
100kΩ
16
(34)
12
(27)
11
(26)
10
(25)
30uF
(C2012JB
0J106K
TDK)
30uF
(C2012JB
0J106K
TDK)
(SLF10145TDK)
(SLF10145TDK)
7/29
Fig-16CStep-DownLow Input Voltage
There are many factors(The PCB board layout, Output Current, etc.)that can affect the DCDC characteristics.
Please verify and confirm using practical applications.
Fig-16DStep-Upand Step-Up-Down
There are many factors(The PCB board layout, Output Current, etc.)that can affect the DCDC characteristics.
Please verify and confirm using practical applications.
Vo(12V/1A)
18
(36)
17
(35)
15
(33)
14
(31)
13
(29)
3300pF
10kΩ
SW1
DGND1
OUTL1
VREG5A
VREG33
FB1
COMP1
SS1
DET1
STB
EN1
EN2
GND
LOFF
RT
SYNC
LLM
SW2
DET2
DGND2
OUTL2
VREG5
EXTVCC
FB2
COMP2
SS2
OUTH1
BOOT1
CL1
VCCCL1
VCC
VCCCL2
CL2
BOOT2
OUTH2
0.1uF
1uF
1uF
10kΩ 22000pF
0.1uF
0.33
uF
10
Ω
10mΩ
10mΩ
0.33uF
1uF
4.7kΩ22000pF
6.2kΩ
91
kΩ
220uF
23.5kΩ
Vo(24V/1A)
27uH
SP8K2
VIN(12V)
27
(48)
1uF 0.1
uF
36
(12)
35
(11
)
32
(7)
29
(2)
28
(1)
26
(47)
24
(44)
22
(41)
21
(39)
20
(38)
19
(37)
1
(13)
3
(15)
4
(17)
5
(19)
6
(21)
7
(22)
9
(24)
2
(14)
25
(46)
8
(23)
23
100Ω
1nF1nF
100Ω
1000pF
680
kΩ
5.1kΩ
1000pF
1000pF
220
uF
REGSPIC
TM
27uH
RSS
065N03
Co1
RB051L-40
L1
100uF
34
(10)
33
(8)
30
(3)
31
(5)
RB160
VA-40
RB051
L-40
Co2
L2
Do3
100kΩ
16
(34)
12
(27)
11
(26)
10
(25)
(SLF12565TDK)
(SLF12565TDK)
REGSPIC
TM
is
Trade Mark of RHOM
SW1
DGND1
OUTL1
VREG5A
VREG33
FB1
COMP1
SS1
DET1
STB
EN1
EN2
GND
LOFF
RT
SYNC
LLM
SW2
DET2
DGND2
OUTL2
VREG5
EXTVCC
FB2
COMP2
SS2
OUTH1
BOOT1
CL1
VCCCL1
VCC
VCCCL2
CL2
BOOT2
OUTH2
0.1uF
1uF
1uF
3.3kΩ 4700pF
0.1uF
0.33
uF
10
Ω
23mΩ
23mΩ
0.33uF
1uF
10kΩ 2200pF
20kΩ
12kΩ
VIN(5V)
31
(5)
27
(48)
36
(12)
35
(11
)
33
(8)
32
(7)
30
(3)
29
(2)
28
(1)
26
(47)
24
(44)
22
(41)
21
(39)
20
(38)
19
(37)
18
(36)
17
(35)
15
(33)
14
(31)
13
(29)
1
(13)
3
(15)
4
(17)
5
(19)
6
(21)
7
(22)
9
(24)
2
(14)
25
(46)
8
(23)
23
100Ω
1nF1nF
100Ω
100pF
33pF
43
kΩ
30uF
(セラコン)
RB051
L-40
6.8uH Vo(2.5V/2A)
SP8K2
1000pF
300Ω
34
(10)
100uF
100kΩ
16
(34)
12
(27)
11
(26)
10
(25)
RB160
V
-40
30uF
(セラコン)
Vo(1.8V/2A)
RB051
L-40
SP8K2
15kΩ
100Ω
3300pF
6.8uH 0.1uF
RB160
VA-40 0.1uF
(SLF10145TDK) (SLF10145TDK)
8/29
VCC-VOUT)×VOUT
L×VCC×f
ΔIL = [A]・・・5
VCC-VOUT)×VOUT
ΔIL×VCC×f
L = [H]・・・7
Fig-17
VOUTVCC - VOUT
VCC
IRMS = IOUT × [A]・・・10
Application component selection
(1) Setting the output L value
The coil value significantly influences the output ripple current.
Thus, as seen in equation (5), the larger the coil, and the higher
the switching frequency, the lower the drop in ripple current.
The optimal output ripple current setting is 30% of maximum current.
ΔIL = 0.3×IOUTmax.[A]・・・6
(ΔILoutput ripple current fswitching frequency
Outputting a current in excess of the coil current rating will cause magnetic saturation of the coil and decrease
efficiency.
Please establish sufficient margin to ensure that peak current does not exceed the coil current rating.
Use low resistance (DCR, ACR) coils to minimize coil loss and increase efficiency.
(2) Setting the output capacitor Co value
Select the output capacitor with the highest value for ripple voltage (V
PP
) tolerance and maximum drop voltage
(at rapid load change). The following equation is used to determine the output ripple voltage.
ΔI
L
Vo 1
Step down ΔV
PP
= ΔI
L
× R
ESR
+ × × [V] Note: fswitching frequency
Co Vcc f
Be sure to keep the output Co setting within the allowable ripple voltage range.
Please allow sufficient output voltage margin in establishing the capacitor rating. Note that low-ESR capacitors enable
lower output ripple voltage.
Also, to meet the requirement for setting the output startup time parameter within the soft start time range, please factor
in the conditions described in the capacitance equation (9) for output capacitors, below.
TSS × (Limit IOUT) Tss soft start time
Co ・・・ 9
VOUT ILimitover current detection value2/16reference
Note: less than optimal capacitance values may cause problems at startup.
(3) Input capacitor selection
The input capacitor serves to lower the output impedance of the power
source connected to the input pin (VCC). Increased power supply output
impedance can cause input voltage (VCC) instability, and may negatively
impact oscillation and ripple rejection characteristics. Therefore, be
certain to establish an input capacitor in close proximity to the VCC and
GND pins. Select a low-ESR capacitor with the required ripple current
capacity and the capability to withstand temperature changes without
wide tolerance fluctuations. The ripple current IRMSS is determined
using equation (10).
Also, be certain to ascertain the operating temperature, load range and
MOSFET conditions for the application in which the capacitor will be used,
since capacitor performance is heavily dependent on the application’s
input power characteristics, substrate wiring and MOSFET gate drain
capacity.
L
VIN
VOUT
Co
Cin
ΔI
L
Output ripple current
I
L
VCC
Co
L
VOUT
Fig-18
Input capacitor
Fig-19
9/29
Vo
R8
R9
Internal ref. 0.8V
FB
(4) Feedback resistor design
Please refer to the following equation in determining the proper feedback resistance. The recommended setting is in a range
between 10kΩ and 330kΩ. Resistance less than 10kΩ risks decreased power efficiency, while setting the resistance value
higher than 330kΩ will result in an internal error amp input bias current of 0.2uA increasing the offset voltage.
R8 +R9
Vo = × 0.8 [V] ・・・11
R9
Fig-20
(5) Setting switching frequency
The triangular wave switching frequency can be set by connecting a resistor to the RT 15(33) pin. The RT sets the frequency
by adjusting the charge/discharge current in relation to the internal capacitor. Refer to the figure below in determining proper
RT resistance, noting that the recommended resistance setting is between 50kΩ and 130kΩ. Settings outside this range
may render the switching function inoperable, and proper operation of the controller overall cannot be guaranteed when
unsupported resistance values are used.
250
300
350
400
450
500
550
50 60 70 80 90 100 110 120 130
RT [ kΩ]
周波数 [ kHz ]
Fig-21 RT vs. switching frequency
(6) Setting the soft start delay
The soft start function is necessary to prevent an inrush of coil current and output voltage overshoot at startup. The figure
below shows the relation between soft start delay time and capacitance, which can be calculated using equation (12) at right.
0.8V(typ.)×CSS
TSS = [sec]・・・(12)
ISS(10μA Typ.)
Fig-22 SS capacitance vs. delay time
Recommended capacitance values are between 0.01uF and 0.1uF. Capacitance lower than 0.01uF may generate output
overshoots. Please use high accuracy components (such as X5R) when implementing sequential startups involving other
power sources. Be sure to test the actual devices and applications to be used, since the soft start time varies, depending on
input voltage, output voltage and capacitance, coils and other characteristics.
0.01
0.1
1
10
0.001 0.01 0.1
SS CAPACITANCE[uF]
DELAY TIME[ms]
10/29
Over current detection point
I
L
A
COMP
FB
C
R
Feedback
L
VIN
I
L
Vo
VCCCL
CL
RCL
-18 0
-9 0
0
90
18 0
A
0
0
-90
-180
(a)
GBW(b)
-180°
Phase margin
-90°
-20dB/decade
Gain
[dB]
Phase
[deg]
1
2πRCA
point (a) fa = 1.25[Hz]
1
2πRC
point (b) fa = GBW [Hz]
(7) Setting over current detection values
The current limit valueILimitis determined by the resistance of the RCL established between CL and VCCCL.
90m
ILimit = [A]・・・(13)
RCL
Fig-23 Fig-24
There are 2 current limit function (ON/OFF control type and OFF latch type) toggled by LOFF pin.
LOFF=L (0<LOFF<1V): Off Latch Type Current Limit
The output becomes OFF and latched when SS=H and, current limit operation, and the output voltage is less than or equal
to 70% of Vo. The OFF latch is deactivated by re-inputting EN signal or VCC control input (switch OFF and ON once more).
LOFF=H (1<LOFF<VREG5): ON/OFF Control Type Current Limit
When the current goes beyond the threshold value, the current can be limited by reducing the ON Duty Cycle. When the load
goes back to the normal operation, the output voltage also becomes back on to the specific level.
(8) Method for determining phase compensation
Conditions for application stability
Feedback stability conditions are as follows:
When gain is 1 (0dB) and phase shift is 150° or less (i.e., phase margin is at least 30°):
a dual-output high-frequency step-down switching regulator is required
Additionally, in DC/DC applications, sampling is based on the switching frequency; therefore, overall GBW may be set at no
more than 1/10 the switching frequency. In summary, target characteristics for application stability are:
Phase shift of 150° or less (i.e., phase margin of 30° or more) with gain of 1 (0dB)
GBW (i.e., gain 0dB frequency) no more than 1/10 the switching frequency.
Stability conditions mandate a relatively higher switching frequency, in order to limit GBW enough to increase response.
The key to achieving successful stabilization using phase compensation is to cancel the secondary phase margin/delay
(-180°) generated by LC resonance, by employing a dual phase lead. In short, adding two phase leads stabilizes the
application.
GBW (the frequency at gain 1) is determined by the phase compensation capacitor connected to the error amp. Thus, a larger
capacitor will serve to lower GBW if desired.
General use integrator (low-pass filter) Integrator open loop characteristics
Fig-26 Fig-27
The error amp is provided with phase compensation similar to that depicted in figures and above and thus serves
as the system’s low-pass filter.
In DC/DC converter applications, R is established parallel to the feedback resistance.
LOFF=L
OFF Latch
Vo×70%
LOFF=H
The current limit value
Io
V
o
Fig-25
11/29
FB
R2
A
COMP
Vo
C2
C1
R1
FB
R2
A
COMP
Vo
C2
R1
R3
1
2π√LC
fr = [Hz]
Resonance point phase margin -180°
resonance point1
2π√LC
fr = [Hz]Resonance Point
f
ESR
= [Hz] :Zero
1
2πR
ESR
C
-90°:Pole
Fig-28 Fig-29
Fig-32
1
2π√LC
When electrolytic or other high-ESR output capacitors are used:
Phase compensation is relatively simple for applications employing high-ESR output capacitors (on the order of several
Ω). In DC/DC converter applications, where LC resonance circuits are always incorporated, the phase margin at these
locations is -180°. However, wherever ESR is present, a 90° phase lead is generated, limiting the net phase margin to -90°
in the presence of ESR. Since the desired phase margin is in a range less than 150°, this is a highly advantageous
approach in terms of the phase margin. However, it also has the drawback of increasing output voltage ripple components.
LC resonance circuit ESR connected
Since ESR changes the phase characteristics, only one phase lead need be provided for high-ESR applications. Please choose
one of the following methods to add the phase lead.
Add C to feedback resistor Add R3 to aggregator
Fig-30 Fig-31
Phase lead fz = [Hz] Phase lead fz = [Hz]
Set the phase lead frequency close to the LC resonance frequency in order to cancel the LC resonance.
When using ceramic, OS-CON, or other low-ESR capacitors for the output capacitor:
Where low-ESR (on the order of tens of mΩ) output capacitors are employed, a two phase-lead insertion scheme is
required, but this is different from the approach described in figure ~, since in this case the LC resonance gives rise
to a 180° phase margin/delay. Here, a phase compensation method such as that shown in figure below can be
implemented.
Phase compensation provided by secondary (dual) phase lead
Phase lead fz1 = [Hz]
Phase lead fz2 = [Hz]
LC resonance frequency fr = [Hz]
Once the phase-lead frequency is determined, it should be set close to the LC resonance frequency.
This technique simplifies the phase topology of the DCDC Converter. Therefore, it might need a certain amount
of trial-and-error process. There are many factors(The PCB board layout, Output Current, etc.)that can affect
the DCDC characteristics. Please verify and confirm using practical applications.
1
2πC1R1
1
2πC2R3
Vcc
Vo
L C
Vcc
Vo
L
C
R
ESR
1
2πR1C1
1
2πR3C2
FB
R2
A
COMP
Vo
C2
R1
R3
C1
12/29
Vo1
VCC VREG5 VREG5
OUTH1 BOOT1 VCC BOOT2
SW1
OUTL1
DGND1
FB1
Vo2
COMP1
SS1
DET2
OUTH2
OUTL2
SW2
DGND2
FB2
COMP2
SS2
DET1
STB EN1 EN2 GND
9MOSFET selection
FET uses Nch MOS
V
DS
Vcc
V
GSM1
BOOT-SW interval voltage
V
GSM2
VREG5
Allowable currentvoltage current + ripple current
Should be at least the over current protection value
Select a low ON-resistance MOSFET for highest efficiency
Fig-33
10Schottky barrier diode selection
Reverse voltage V
R
Vcc
Allowable currentvoltage current + ripple current
Should be at least the over current protection value
Select a low forward voltage, fast recovery diode for highest
efficiency
The shoot-through may happen when the input parasitic
capacitance of FET is extremely big or the Duty ratio is less
than or equal to 10%. Less than or equal to 1000pF input
parasitic capacitance is recommended. Please confirm
operation on the actual application since this character is
affected by PCB layout and components.
11Sequence function
Circuit diagram Timing chart
Fig-35 Fig-36
V
CC
I
L
Vo
V
DS
V
GSM1
V
GSM2
V
DS
V
CC
Vo
V
R
With EN1, 2 at ”H” level, when EN1 goes ”L”,
Vo1 turns OFF, but Vo2 output continues.
When EN1 stays ”H” and EN2 returns to ”H”, DET1 is in
open state; thus SS2 is asserted, and Vo2 output starts.
If Vo2 is 76% of the voltage setting or higher, DET2 goes
open and SS1 is asserted, starting Vo1 output.
EN1
EN2
DET2
SS1
FB1
Vo1
DET1
SS2
FB2
Vo2
0.61V
over 76%
under 70%
0.56V 0.61V 0.56V
over 76%
over 70%
With EN1,2 at “H” level, i
f
Vo1 starts at 76% or more o
f
voltage setting, DET goes
open and SS1 is asserted,
starting Vo2 output.
Same as “A” at left
A
With EN2 set ”L”, if Vo2
goes below 70% the voltage
setting, DET2 shorts and SS1
is asserted, turning Vo1 OFF
A
Fig-34
13/29
Input/Output equivalent circuits (Items in parentheses apply to VQFP48C)
1(13)27(48)PINSW1SW2
29(2)35(11)PINBOOT2BOOT1
28(1)36(15)PINOUTH1OUTH2
2(14)26(47)PINDGND1DGND2
3(15)25(46)PINOUTL1OUTL2
24(44) VREG5 / 4(17)VREG5A
14(31)PINLOFF
16(34)PINSYNC 6(21)21(39)PINFB1FB2 8(23)19(37)PINSS1SS2
10(25)11(26)12(27)PIN
STBEN1EN2 9(24)18(36)PINDET1DET2 15(33)PINRT
17(35)PINLLM 30(3)34(10)PINCL2CL1
31(5)33(8)PINVCCCL2VCCCL17(22)20(38)PINCOMP1COMP2
22(41)PINEXTVCC
24(44)PINVREG5 5(19)PINVREG33 4(17)DINVREG5A
BOOT
OUTH
SW
300k
OUTL
DGND
LOFF
100k
135.8k
172.2k
VREG5
FB
VREG5
/
VREG5A
1k
2.5k
SS
VREG5
/ VREG5A
100k
50k
2k
VCC
STB
EN 172.2k
135.8k
100k DET
VREG5
/ VREG5A
10k
VREG5
RT
SYNC 5k
250k
VREG5
1P
VREG5A
LLM
308k
COMP
VREG5
/ VREG5A
20Ω
5kΩ
5kΩ
VCC
VREG5A
EXTVCC
VREG5
VCC
VCC
150k
746.32k
255k
VREG33
VREG5A
VCC
150k
746.32k
469.06k
VCCCL
VCC
CL
5k
5P
VCC
1k
14/29
N
P
+
(PINA)
Resistor
Parasitic element
P
P
+
GND
P
N
Operation notes
1Absolute maximum ratings
Exceeding the absolute maximum ratings for supply voltage, operating temperature or other parameters can damage or
destroy the IC. When this occurs, it is impossible to identify the source of the damage as a short circuit, open circuit, etc.
Therefore, if any special mode is being considered with values expected to exceed absolute maximum ratings, consider
taking physical safety measures to protect the circuits, such as adding fuses.
2GND electric potential
Keep the GND terminal potential at the lowest (minimum) potential under any operating condition.
3Thermal design
Be sure that the thermal design allows sufficient margin for power dissipation (Pd) under actual operating conditions.
4Inter-pin shorts and mounting errors
Use caution when positioning the IC for mounting on printed surface boards. Connection errors may result in damage or
destruction of the IC. The IC can also be damaged when foreign substances short output pins together, or cause shorts
between the power supply and GND.
5Operation in strong electromagnetic fields
Use caution when operating in the presence of strong electromagnetic fields, as this may cause the IC to malfunction.
6Testing on application boards
Connecting a capacitor to a low impedance pin for testing on an application board may subject the IC to stress. Be sure to
discharge the capacitors after every test process or step. Always turn the IC power supply off before connecting it to or
removing it from any of the apparatus used during the testing process. In addition, ground the IC during all steps in the
assembly process, and take similar antistatic precautions when transporting or storing the IC.
7) The output FET
The shoot-through may happen when the input parasitic capacitance of FET is extremely big or the Duty ratio is less than
or equal to 10%. Less than or equal to 1000pF input parasitic capacitance is recommended. Please confirm operation on
the actual application since this character is affected by PCB layout and components.
8This monolithic IC contains P+ isolation and P substrate layers between adjacent elements in order to keep them isolated.
P-N junctions are formed at the intersection of these P layers with the N layers of other elements, creating a parasitic diode
or transistor. Relations between each potential may form as shown in the example below, where a resistor and transistor
are connected to a pin:
With the resistor, when GND Pin A, and with the transistor (NPN), when GNDPin B:
The P-N junction operates as a parasitic diode
With the transistor (NPN), when GND Pin B:
The P-N junction operates as a parasitic transistor by interacting with the N layers of elements in proximity to the
parasitic diode described above.
Parasitic diodes inevitably occur in the structure of the IC. Their operation can result in mutual interference between circuits,
and can cause malfunctions, and, in turn, physical damage or destruction. Therefore, do not employ any of the methods
under which parasitic diodes can operate, such as applying a voltage to an input pin lower than the (P substrate) GND.
Fig-37 Fig-38 Fig-39 Fig-40
9GND wiring pattern
When both a small-signal GND and high current GND are present, single-point grounding (at the set standard point) is
recommended, in order to separate the small-signal and high current patterns, and to be sure voltage changes stemming
from the wiring resistance and high current do not cause any voltage change in the small-signal GND. In the same way, care
must be taken to avoid wiring pattern fluctuations in any connected external component GND.
(PINB)
TransistorNPN
P
+
P
+
N N
P substrate
GND
N
P
C E
B
Parasitic element or transistor
GND
C
B
Parasitic element or transisto
r
(PINB)
E
(PINA)
Parasitic element
15/29
10In some application and process testing, Vcc and pin potential may be reversed, possibly causing internal circuit or element
damage. For example, when the external capacitor is charged, the electric charge can cause a Vcc short circuit to the GND.
In order to avoid these problems, limiting output pin capacitance to 100μF or less and inserting a Vcc series countercurrent
prevention diode or bypass diode between the various pins and the Vcc is recommended.
Fig-41
11Thermal shutdown (TSD)
This IC is provided with a built-in thermal shutdown (TSD) circuit, which is designed to prevent thermal damage to or
destruction of the IC. Normal operation should be within the power dissipation parameter, but if the IC should run beyond
allowable Pd for a continued period, junction temperature (Tj) will rise, thus activating the TSD circuit, and turning all output
pins OFF. When Tj again falls below the TSD threshold, circuits are automatically restored to normal operation. Note that
the TSD circuit is only asserted beyond the absolute maximum rating. Therefore, under no circumstances should the TSD
be used in set design or for any purpose other than protecting the IC against overheating
12The SW pin
When the SW pin is connected in an application, its coil counter-electromotive force may give rise to a single electric
potential. When setting up the application, make sure that the SW pin never exceeds the absolute maximum value.
Connecting a resistor of several Ω will reduce the electric potential. (See Fig. 43)
Fig-42
13Dropout operation
When input voltage falls below approximately output voltage / 0.9 (varying depending on operating frequency) the ON
interval on the OUTL side MOS is lost, making boost applications and wrap operation impossible. If a small differential
between input and output voltage is envisioned for a prospective application, connect the load such that the SW voltage
drops to the GND level. Managing this load requires discharging the SW line capacitance (SW pin capacitance: approx.
500pF; OUTL side MOS D-S capacitance; Schottky capacitance). Supported loads can be calculated using the equation
below.
Output voltage × SW line capacitance
ILOAD =
25n
Note that SW line capacitance is lower with smaller loads, and more stable operation is attained when low voltage bias
circuits are configured as in the example below (Fig. 44). However, the degree to which line capacitance is reduced or
operational stability is attained will vary depending on the board layout and components. Therefore, be certain to confirm
the effectiveness of these design factors in actual operation before entering mass production.
Fig-43
Vcc
Pin
Bypass diode
Countercurrent prevention diode
OUT
SW
Vcc
Vcc
VREG
Vo
OUT
BOOT
DGND
OUTL
OUTH
SW R
Vcc
Vo
16/29
HQFN36V
0.0
0.2
0.4
0.6
0.8
1.0
0 25 50 75 100 125 150
AMBIENT TEMPERATORE:Ta [℃]
POWER DISSIPATION:Pd [W]
PD(W)
0.875W
0.56W
VQFP48C
0.0
0.2
0.4
0.6
0.8
1.0
1.2
0 25 50 75 100 125 150
AMBIENT TEMPERATORE:Ta [℃]
POWER DISSIPATION:Pd [W]
PD(W)
1.1W
0.75W
Power dissipation vs. temperature characteristics
①:Stand-alone IC ①:Stand-alone IC
②:Mounted on Rohm standard board ②:Mounted on Rohm standard board
70mm x 70mm x 1.6mm glass-epoxy board 70mm×70mm×1.6mm glass-epoxy board
Part order number
B D 9 0 1 1 K V E 2
ROHM part
code
Type/No. Package type
KV VQFP48C
EKN HQFN36V
Tape and Reel Information
E2 : Embossed carrier tape
HQFN36V
Unit:mm
<Dimension>
(The direction is the 1pin of product is at the upper left when you hold
reel on the left hand and you pull out the tape on the right hand)
Tape
Quantity
Direction
of feed
Embossed carrier tape(with dry pack)
2500pcs
E2
<Tape and Reel information>
When you order , please order in times the amount of package quantity.
Reel Direction of feed
1pin
1234
1234
1234
1234
1234
1234
Unit:mm)
<Dimension>
VQFP48C
< Packing information >
When you order , please order in times the amount of package quantity.
Ta
p
e
Quantit
y
Direction
of feed
Embossed carrier tape
1500pcs
(The direction is the 1pin of product is at the upper left when you hold
reel on the left hand and you pull out the tape on the right hand)
E2
Reel 1Pin Direction of feed
17/29
BD9775FV (1channel synchronous rectification configuration)
Description
BD9775FV is Switching Controller with synchronous rectification(BD9775FV is 1channel synchronous rectification) and wide
input range. It can contribute to ecological design(lower power consumption) for most of electronic equipments.
Features (BD9775FV)
1) 2channel Step-Down DC/DC FET driver
2) Synchronous rectification for channel 2
3) Able to synchronize to an external clock signal
4) Over Current Protection (OCP) by monitoring VDS of P channel FET
5) Short Circuit Protection (SCP) by delay time and latch method
6) Under Voltage Lock Out (UVLO)
7) Thermal Shut Down (TSD)
8) Package : SSOP-B28
Applications (BD9775FV)
Car navigation system, Car Audio, Display, Flat TV
Absolute maximum ratings (Ta=25)(BD9775FV)
Parameter Symbol Limits Units
Supply Voltage (VCC to GND) Vcc 36 V
VREF to GND Voltage Vref 7 V
VREGA to GND Voltage Vrega 7 V
VREGB to VCC Voltage Vregb 7 V
OUT1, OUT2H to VCC Voltage Vouth 7 V
OUT2L to GND Voltage Voutl 7 V
Power Dissipation Pd 640(*1) mW
Operating Temperature Range Topr -40 to +85
Storage Temperature Range Tstg -55 to +125
Junction Temperature Tjmax +125
(*1) Without heat sink, reduce to 6.4mW when Ta=25 or above
Pd is 850mW mounted on 70x70x1.6mm, and reduce to 8.5mW/ above 25.
18/29
Recommended operating conditionsTa=-25 to +75℃)(BD9775FV)
Electrical characteristics Ta = 25℃,VCC=13.2V, fosc=100kHz, CTL1=3V, CTL2=3V(BD9775FV)
Limits
Parameter Symbol
Min. Typ. Max.
Unit Condition
Whole Device
Stand-by Current Iccst 5 μA CTL1,CTL2=0V
Circuit Current Icc 2.5 4.2 7 mA FB1,FB2=0V
Reference Voltage
VREF Output Voltage Vref 2.97 3.00 3.03 V Io=-1mA
Line Regulation DVli 10 mV Vcc=7 to 18V,Io=-1mA
Load Regulation DVlo 10 mV Io=-0.1mA to -2mA
Short Output Current Ios -60 -22 -5 mA
Internal Voltage Regulator
VREGA Output Voltage Vrega 4.5 5.0 5.5 V Switching with COUT=5000pF
VREGB Output Voltage Vregb VCC-5.5 VCC-5.0 VCC-4.5 V Switching with COUT=5000pF
VREGB Dropout Voltage Vdregb 1.8 2.2 V VREGB to GND Voltage
Oscillator
Oscillating Frequency fosc 90 100 110 kHz RT=27kΩ,CT=470pF
Frequency Tolerance Dfosc 2 % Vcc=7 to 18V
Synchronized Frequency
Synchronized Frequency osc2 120 kHz FIN=120kHz
FIN Threshold Voltage Vthfin 1.2 1.4 1.6 V
FIN Input Current IFIN -1 1 μA VFIN=1.4V
Error Amplifier
Threshold Voltage Vthea 0.98 1.00 1.02 V
INV Input Bias Current Ibias -1 1 μA
Voltage Gain Av 70 dB DC
Band Width Bw 2.0 MHz Av=0dB
Maximum Output Voltage Vfbh 2.2 2.4 2.6 V INV=0.5V
Minimum Output Voltage Vfbl 0.1 V INV=1.5V
Output Sink Current Isink 0.5 2 5.2 mA FB1,2 Terminal
Isource1 -170 -110 -70 μA FB1 Terminal
Output Source Current
Isource2 -200 -130 -85 μA FB2 Terminal
Limits
Parameter Symbol
MIN TYP MAX
Units
Supply Voltage VCC 6.0 - 30.0 V
Oscillating Frequency osc 30 100 300 KHz
Timing Resistance RT 10 27 56 KΩ
Timing Capacitance CT 100 470 4700 pF
19/29
Limits
Parameter Symbol
Min. Typ. Max.
Unit Condition
PWM Comparator
Threshold Voltage at 0% Vth0 0.88 0.98 1.08 V FB Voltage
Threshold Voltage
at 100%
Vth100 1.88 1.98 2.08 V FB Voltage
DTC Input Bias Current Idtc -1 1 μA
FET Driver
Sink Current Isink 20 36 58 mA VDS=0.4V
Source Current Isource -510 -320 -180 mA VDS=0.4V
RonN 7.0 11.0 17.8 Ω OUT1,2H,2L : L
ON Resistance
RonP 0.7 1.4 2.2 Ω OUT1,2H,2L : H
Rise Time Tr 20 nsec Switching with COUT=5000pF
Fall Time Tf 100 nsec Switching with COUT=5000pF
Driver’s Duty Cycle of
Synchronous
Rectification
ΔDuty 42 45 48 %
RSYNC=30KΩ,
50% of main driver’s duty cycle
SYNC Terminal Voltage Vsync 1.45 1.55 1.65 V Rsync=30KΩ,FB=1.5V
Over Current Protection (OCP)
VS Threshold Voltage Vths VCC-0.24 VCC-0.21 VCC-0.18 V
RCL=21kΩ, the output tern off after
detected 8 cycle
IVSH -1 1 μA VS1,VS2=PBU
VS Input Current
IVSL -1 1 μA VS1,VS2=0V
CL Input Current Icl 9 10 11 μA
Stand-by
Threshold Voltage Vctl 1.0 1.5 2.0 V
CL Input Current Ictl 6 15 30 μA CTL1,CTL2=3V
Short Circuit Protection SCP
Timer Start Voltage Vtime 0.6 0.7 0.8 V INV Voltage
Threshold Voltage Vthscp 1.92 2.00 2.08 V SCP Voltage
Stand-by Voltage Vstscp 10 100 mV SCP Voltage
Source current Isoscp -4.0 -2.5 -1.5 μA SCP=1.0V
Under Voltage Lock Out UVLO
Threshold Voltage Vuvlo 5.6 5.7 5.8 V Vcc sweep down
Hysteresis
Voltage Range
DVuvlo 0.05 0.1 0.15 V
20/29
Pin Description PinNo/PinName (BD9775FV)
(BD9775FV)
Block Diagram (BD9775FV)
Fig.1
FUNCTION EXPLANATION (BD9775FV)
1.DC/DC Converter
Reference Voltage
Stable voltage of compensated temperature, is generated from the power supply voltage (VCC). The reference voltage is 3.0V,
the accuracy is ±1. Place a capacitor with low ESR (several decades mΩ) between VREF and GND.
Internal Regulator A VREGA
5V is generated the power supply voltage. The voltage is for the driver of the synchronous rectification’s MOSFET. Place a
capacitor with low ESR (several decades mΩ) between VREGA and PGND.
Pin
No.
Pin
Name Description
1 FB1
Error amplifier output pinChannel 1
2 INV1
Error amplifier negative input pinChannel 1
3 RT
Oscillator frequency adjustment pin
connected resistor
4 CT
Oscillator frequency adjustment pin
connected capacitor
5 FIN Oscillator synchronization pulse signal input pin
6 GND Low-noise ground
7 VREF Reference voltage output pin
8 DTC1
Maximum duty and soft start adjustment
pinChannel 1
9 DTC2
Maximum duty and soft start adjustment
pinChannel 2
10 INV2 Error amplifier negative input pinChannel 2
11 FB2
Error amplifier output pinChannel 2
12 CTL1 Enable/stand-by control inputChannel 1
13 CTL2 Enable/stand-by control inputChannel 2
14 VCC Main power supply pin
15 SYNC Synchronous rectification timing adjustable pin
16 PGND Power ground (connected low-side gate driver
and digital ground)
17 OUT2L Low-side ( synchronous rectifier ) gate driver
output pinChannel 2
18 VREGA Connected capacitor for internal regulator
19 SCP Delay time of short circuit protection adjustment
pin connected capacitor
20 VS2 Over current detection voltage monitor pin
connected FET drain, Channel 2
21 CL2 Over current detection voltage adjustment pin
connected capacitor and resistorChannel 2
22 PVCC2 High-side gate driver power supply
inputChannel 2
23 OUT2H High-side gate driver output pinChannel 2
24 VREGB Connected capacitor for internal regulator
25 OUT1 High-side gate driver output pinChannel 1
26 PVCC1 High-side gate driver power supply
inputChannel 1
27 CL1 Over current detection voltage adjustment pin
connected capacitor and resistorChannel 1
28 VS1 Over current detection voltage monitor pin
connected FET drain, Channel 1
28
27
26
25
24
23
22
21
20
19
18
1
2
3
4
5
6
7
8
9
10
11
FB1
INV1
RT
CT
Fin
GND
VREF
DTC1
DTC2
INV2
FB2
VS1
CL1
PVCC1
OUT1
VREGB
OUT2H
PVCC2
CL2
VS2
SCP
VREGA
17
16
15
12
13
14
CTL1
CTL2
VCC
OUT2L
PGND
SYNC
21/29
Internal regulator B VREGB
(VCC-5V) is generated from the power supply voltage. The voltage is for the driver of the main MOSFET switch.
Place a capacitor with low ESR (several decades mΩ) between VREGB and PVCC.
Oscillator
Placing a resistor and a capacitor to RT and CT, respectively, generates two triangle waves for both cannels, and each wave
is opposite phase. The waves are input to the PWM comparators for CH1 and CH2. Also, the oscillating frequency can be
slightly adjusted (less than 20%) by putting external clock pulse into Fin pin, which is higher frequency than the fixed one.
Error Amplifier
It amplifies the difference, between the establish output voltage and the actual output one detected at INV. And amplified
voltage comes out from FB. The comparing voltage is 1.0V and the accuracy is ±2%. The phase can be compensated
externally by placing a resistor and a capacitor between INV and FB.
PWM Comparator
It converts the output voltage from error amplifier into PWM waveform, then output to MOSFET driver.
MOSFET Driver
The main drivers (OUT1, OUT2H) are for P-channel MOSFETs, and the driver (OUT2L) for synchronous rectification is for
N-channel MOSFET. The values of output voltage are clamp to VREGB, VREGA, respectively. All drivers’ output
configurations are push-pull type. In addition, the output current capability is 36mA for the sink current and 320mA
(Vds=0.4V) for the source current.
2.Channel Control
Each output can be individually turned on or off with CTL1 and CTL2. When the CTL is “H” (more than 1.5V), it becomes
turned on.
3.Protection
Over Current ProtectionOCP
When detected over current (detecting drop voltage of the main MOSFET’s ON resistance), the MOSFET switch becomes
turned off, and the energy on DTC pin is discharged. After discharged, the output restarts automatically. The level of the
OCP detection threshold can be set by the resistance, which is connected between VCC and CL.
Short Circuit ProtectionSCP
When either output goes down and the voltage on INV pin gets lower than 0.7V, a capacitor placed on SCP is started to
charge.
When the SCP pin becomes more than 2.0V, the main MOSFET switches of both outputs are turned off; then, the outputs are
latched. While they are latched, the IC can be reset by restarting VCC or CTL, or discharging SCP.
Under Voltage Lock OutUVLO
Due to avoiding malfunctions when the IC is started up or the power supply voltage is rapidly disconnected, the main
MOSFET switches become off and DTC is discharged when the supply voltage is less than 5.7V. Also, when the output is
latched because of SCP function, the latch becomes reset. Due to preventing malfunctions in the case the power supply
voltage fluctuate at near UVLO threshold, there is 0.1V hysteresis between the detection and reset voltage of UVLO
threshold.
Thermal Shut DownTSD
Due to preventing breakdown of the IC by heating up, the main MOSFET switches become off and DTC pin is discharged by
detecting over temperature of the chip. Due to preventing malfunctions in the case temperature fluctuate at near TSD
threshold, there is hysteresis between TSD on and off.
22/29
SETTING UP INFOMATION (BD9775FV)
1)Simultaneously OFF Duty of MOSFETs for Synchronous Rectification
The simultaneously OFF duty of both main MOSFET switch and synchronous rectification MOSFET is determined by
resistance (Rsync) between SYNC and GND. See Fig. 4.
In Synchronous Rectification, insert RFB2-GND (RFB2-GND3×Rsync) between FB2 and GND, because it is possible to
reduce overshoot(sea fig.2). RFB2-GND decide following formula.
Fig.2
Resistance at FB2-GND setup condition
Rsync(MAX)MAX dispersion range at Rsync Rsync(MIN)MIN dispersion range at Rsync
Short SYNC to VREF if the synchronous rectification function is not needed.
Without Synchronous RectificationDon’t insert R
FB2-GND
0
5
10
15
20
25
30
35
40
0 20406080100
Rsync (kΩ)
ΔDuty (%)
T=-40℃
T= 25
T=105℃
SYNC
VREF
fosc=100kHz
Δduty=(t1+t2)/t×100 (%)
OUT2H
OUT2L
t1 t2
t
Threshold Voltage at100%
-Out
p
ut Source Current at FB2
Vsync
3×Rsync(MAX)
<R
FB2-GND
< 3xRsync(MIN)
2.08
0.4908
Rsync(MAX) +80.7x10
-6
R
FB2-GND
< < 3xRsync(MIN)
Rsync
SYNC FB2 R
FB2-GND
23/29
2) Oscillator Synchronization by External Pulse Signal
At the operation the oscillator is externally synchronized, input the synchronization signal into Fin in addition to connect a
resistor and a capacitor at RT and CT, respectively.
Input the external clock pulse on Fin, which is higher frequency than the fixed one. However, the frequency variation
should be less than 20%.
Also, the duty cycle of the pulse should be set from 10% to 90%.
CT Waveform during Synchronized with External Pulse
Short Fin to GND if the function of external synchronization is not needed.
Without Synchronization Signal
3)Setting the Over Current Threshold Level
The OCP detection levelIocpis determined by the ON resistance (R
ON
) of the main MOSFET switch and the resistance
(Rcl) which is placed between CL and VCC.
Iocp ×10
-5
[A]typ.
To prevent a malfunction caused by noise, place a capacitorCcl parallel to Rcl.
If OCP function is not needed, short VS to VCC, and short CL to GND.
With OCP Without OCP
CL, VS Pin Connection
Rcl
R
ON
Fin
Fin
CT
Fixed with RT and CT
Synchronized
CL
VS
VCC
CL
VS
Rcl
VCC
Ccl
To Main MOSFET Drain
24/29
4)Setting the Time for Short Circuit Protection
The time (tscp) from output short to latch activation is determined by the capacitor, Cscp, connected SCP pin.
tscp
7.96
×
10
5
×
Cscp
[sec]
typ.
Short SCP to GND if SCP function is not being used.
Without SCP
5)Single Channel Operation
This device can be used as a single output. The connection is as follows;
DTC,FB,CTL,CL Short to GND
VS,PVCC Short to VCC
INV Short to VREF
Single Channel Operation
6)Setting the Oscillating Frequency
The oscillating frequency can be set by selecting the timing resistor (RRT)and the timing capacitor (CCT).
Fig.3
Fig.4
Ocsillating Frequency vs. Timing Capacitance (CCT)
10
100
1000
10 100 1000
Timing Resistance (kΩ)
Oscillating Frequency (kHz)
C
CT
=470pF
C
CT
=1000pF
C
CT
=100pF
SCP
Ocsillating Frequency vs. Timing Capacitance (RRT)
10
100
1000
100 1000 10000
Timing Capacitan ce(pF)
Oscillating Frequency (kHz)
R
RT
=100kΩ
R
RT
=27kΩ
R
RT
=5.1kΩ
DTC
FB
CTL
CL
VS
PVCC
INV
VREF
VCC
25/29
Timing Chart (BD9775FV)
Output ON/OFF, Minimum Input
UVLO
Fig.5
Over Current Protection, Short Circuit Protection, Thermal Shut Down
Fig.6
I/O EQUIVALENT CIRCUIT (BD9775FV)
FB1(1) FB2(11) RT(3)
VREF VREGA VCC
FB1
VREF VREGA VCC
VREF
RT
VCC
INV1(2),INV2(10) CT(4) FIN(5)
VCC
VREF
INV1,2
VREF VCC
VREG VCC
FIN
Fig.8
Fi
g
.7
VCC
CTL1
CTL2
DTC1
DTC2
Vout1
Vout2
6.0V UVLO is inactivated
at 5.8V
Stand-by Soft start
1.0V
1.0V
UVLO is activated at 5.7V
CTL1,2
SCP
DTC1,2
Vout1,2
Iout1,2
OCP is activated by detecting 8 consecutive cycles
OCP detection level
1.0V
2.0V
Half short of output
A
ctivate SCP
Inactivate half-short
Reset the latch by restarting CTL
A
ctivate TSD Inactivate TSD
0.7×fixed output voltage
VCC
FB1
VREGA
VREF
VCC
VREGA
VREF
VCC
VREF
INV12
VCC
VREF
VCC
VREF
RT
VCC
VREF
FIN
26/29
DTC1(8),DTC2(9) CTL1(12),CTL2(13) SYNC(15)
VREGA VREF
DTC1,2
VCC
VCCVREGA
CTL1,2
VREF VCC
SYNC
SCP(19) OUT2L(17),VREGA(18) VREF(7)
VCC
SCP
VREF
VCC
VREGA
OUT2L
VREF
VC
PVCC1(26),PVCC2(22)
OUT1(25),OUT2H(23),VREGB(24) VS1(28),VS2(20),CL1(27),CL2(21)
VCC
PVCC1,2
OUT1,2H
VREGB
CL1,2
V
S1,2
V
CC
Operation Notes (BD9775FV)
1) Absolute maximum ratings
Use of the IC in excess of absolute maximum ratings such as the applied voltage or operating temperature range may result in IC deterioration
or damage. Assumptions should not be made regarding the state of the IC (short mode or open mode) when such damage is suffered.
A physical safety measure such as a fuse should be implemented when use of the IC in a special mode where the absolute maximum ratings
may be exceeded is anticipated.
2) GND potential
Ensure a minimum GND pin potential in all operating conditions. In addition, ensure that no pins other than the GND pin carry a voltage lower
than or equal to the GND pin, including during actual transient phenomena.
3) Thermal design
Use a thermal design that allows for a sufficient margin in light of the power dissipation (Pd) in actual operating conditions.
4) Inter-pin shorts and mounting errors
Use caution when orienting and positioning the IC for mounting on printed circuit boards. Improper mounting may result in damage to the IC.
Shorts between output pins or between output pins and the power supply and GND pin caused by the presence of a foreign object may result in
damage to the IC.
5) Operation in a strong electromagnetic field
Use caution when using the IC in the presence of a strong electromagnetic field as doing so may cause the IC to malfunction.
6) Thermal shutdown circuit (TSD circuit)
This IC incorporates a built-in thermal shutdown circuit (TSD circuit). The TSD circuit is designed only to shut the IC off to prevent runaway
thermal operation. Do not continue to use the IC after operating this circuit or use the IC in an environment where the operation of the thermal
shutdown circuit is assumed.
7) Testing on application boards
When testing the IC on an application board, connecting a capacitor to a pin with low impedance subjects the IC to stress. Always discharge
capacitors after each process or step. Ground the IC during assembly steps as an antistatic measure, and use similar caution when transporting
or storing the IC. Always turn the IC's power supply off before connecting it to or removing it from a jig or fixture during the inspection process.
8) Common impedance
Power supply and ground wiring should reflect consideration of the need to lower common impedance and minimize ripple as much as possible
(by making wiring as short and thick as possible or rejecting ripple by incorporating inductance and capacitance).
Fi
g
.8
VCC
VREGA VREF
DTC1,2
VCC
VREF
SCP
VCC
PVCC12
OUTH12H
VREGB
VCC
VS12
CL12
VCC
VREF
VCC
VREGA
OUT2L
VCC
VREGA
CTL12
VREF VCC
SYNC
27/29
Vcc
Pin
Bypass diode
Countercurrent
prevention diode
9) Applications with modes that reverse VCC and pin potentials may cause
damage to internal IC circuits.
For example, such damage might occur when VCC is shorted with the
GND pin while an external capacitor is charged.
It is recommended to insert a diode for preventing back current flow
in series with VCC or bypass diodes between VCC and each pin.
Fig.9
10) Timing resistor and capacitor
Timing resistor(capacitor) connected between RT(CT) and GND, has to be placed near RT(CT) terminal 3pin(4pin). And pattern has to be short
enough.
11) The Dead time input voltage has to be set more than 1.1V.
Also, the resistance between DTC and VREF is used more than 30k to work OCP function reliably.
12) The energy on DTC18pinand DTC29pinis discharged when CTL112pinand CTL213pinare OFF, respectively, or VCC14pin
is OFF (UVLO activation). However, it is considerable to occur overshoot when CTL and VCC are turned on with remaining more than 1V on
the DTC.
13) If Gate capacitance of P-channel MOSFET or resistance placed on
Gate is large, and the time from beginning of Gate switching to the end of Drain’s (tsw),
is long, it may not start up due to the OCP malfunction.
To avoid it, select MOSFET or adjust resistance as tsw becomes less than 270nsec.
Fig.10
14) IC pin input
This monolithic IC contains P+ isolation and PCB layers between adjacent elements in order to keep them isolated.
P/N junctions are formed at the intersection of these P layers with the N layers of other elements to create a variety
of parasitic elements. For example, when a resistor and transistor are connected to pins as shown in following chart,
the P/N junction functions as a parasitic diode when GND > (Pin A) for the resistor or GND > (Pin B) for the transistor (NPN).
Similarly, when GND > (Pin B) for the transistor (NPN), the parasitic diode described above combines with the N layer of other adjacent
elements to operate as a parasitic NPN transistor.
The formation of parasitic elements as a result of the relationships of the potentials of different pins is an
inevitable result of the IC's architecture. The operation of parasitic elements can cause interference with circuit
operation as well as IC malfunction and damage. For these reasons, it is necessary to use caution so that the IC is
not used in a way that will trigger the operation of parasitic elements, such as by the application of voltages lower
than the GND (PCB) voltage to input and output pins.
Fig.11
Fig.12
VCC
VREF
tsw
GATE
DRAIN
Copper laminate area 70 mm×70mm
With no heat sink
0.4
0.6
0.2
050 75 100 125025
AMBIENT TEMPERATURE Ta(℃)
pd(W)
0.8
0.587W
0.64W
POWER DISSIPATION pd(W)
1.0
0.85W
150
N
P
+
(PINA)
Resistor
Parasitic element
P
P
+
GND
P
N
(PINB)
TransistorNPN
P
+
P
+
N N
P substrate
GND
N
P
C E
B
Parasitic element or transistor
GND
C
B
Parasitic element or transisto
r
(PINB)
E
(PINA)
Parasitic element
28/29
Part order number
B D 9 7 7 5 F V - E 2
ROHM Part
Code
Type/No. Package type
FV : SSOP-B28
Tape and Reel Information
E2 : Embossed carrier tape
(
Unit:mm
)
SSOP-B28
<Dimension> <Ta
p
e and Reel information>
Ta
p
e
Q
uantit
y
Direction
of feed
Embossed carrier ta
p
e
2000
p
cs
E2
(The direction is the 1pin of product is at the upper left when you hold
reel on the left hand and you pull out the tape on the right hand)
Reel
Direction of feed
1
p
in
1234
123
123
1234
123
1234
1234
1234
When you order , please order in times the amount of package quantity.
Catalog No.08T67 2A '08.9 ROHM ©
Appendix-Rev4.0
Thank you for your accessing to ROHM product informations.
More detail product informations and catalogs are available, please contact your nearest sales office.
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FAX : +81-75-315-0172
Appendix
Notes
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The content specified herein is subject to change for improvement without notice.
The content specified herein is for the purpose of introducing ROHM's products (hereinafter "Products"). If you
wish to use any such Product, please be sure to refer to the specifications, which can be obtained from ROHM
upon request.
Examples of application circuits, circuit constants and any other information contained herein illustrate the
standard usage and operations of the Products. The peripheral conditions must be taken into account
when designing circuits for mass production.
Great care was taken in ensuring the accuracy of the information specified in this document. However, should
you incur any damage arising from any inaccuracy or misprint of such information, ROHM shall bear no re-
sponsibility for such damage.
The technical information specified herein is intended only to show the typical functions of and examples
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sponsibility whatsoever for any dispute arising from the use of such technical information.
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While ROHM always makes efforts to enhance the quality and reliability of its Products, a Product may fail or
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Please be sure to implement in your equipment using the Products safety measures to guard against the
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