ROHM BD9354MWV

1/4
STRUCTURE
PRODUCT SERIES
Silicon Monolithic Integrated Circuit
7-Channel Switching Regulator Controller for Digital Camera
TYPE
ＢＤ９３５４ＭＷＶ
PIN ASSIGNMENT
BLOCK DIAGRAM
PACKAGE
Functions
●
Fig.1
Fig.1
Fig.2
Power supply voltage 2.2～5.5V(at start-up), 2.05～5.5V(after start-up)
● CH1step-down converter, CH2cross converter, CH3 step-down converter, CH4 step- down converter
CH5 inverting converter for CCD, CH6 boost converter for CCD, CH7 boost converter for LED
● All Internal Power MOSFETs
● Built-In MOSFETs for synchronous rectifying action mode on CH1～4
● Built-In feedback resistors on CH2
● All channels contain internal compensation between inputs outputs of error amps
● Contains sequence control circuit for CH1～4
● Operating frequency 1.5MHz(CH1,3,4)､750KHz（CH2,5,6,7）
● Built-In Short-circuit Protection (SCP)
● CH6 have high side switches with soft start function
● Built-In Over voltage Protection (OVP)
● Thermally enhanced UQFN036V5050 package（5mm×5mm, 0.4mm pitch）
○Absolute maximum ratings（Ta＝25℃）
Parameter
P o w e r
I n p u t
O u t p u t
P
O
S
J
Symbol
V o l t a g e
c u r r e n t
o w e r
D i s s i p a t i o
p e r a t i n g T e m p e r a t u r
t o r a g e
T e m p e r a t u r
u n c t i o n T e m p e r a t u r
n
e
e
e
VCC,Hx13,Hx2,
Hx4,Hx567,VO2,HS6L
STB1234,56
PWM7
Hx5 - Lx5
Lx6
Lx7,VO7
IomaxLx1
IomaxHx2
IomaxHx3
IomaxHx4,Lx4
IomaxHx5
IomaxHS6L
IomaxLx6～7
Pd
Topr
Tstg
Tjmax
Limit
Unit
－0.3～7
V
－0.3～7
－0.3～7
-0.3～15
－0.3～20
-0.3～21
±0.8
±1.5
±0.8
±1.0
±1.5
±1.2
±1.2
0.88 *1
－25～+85
－55～+150
+150
V
V
V
V
V
A
A
A
A
A
A
A
W
℃
℃
℃
*1 Should be derated by 7.04mW/℃ at Ta=25℃ or more. When mounted on a glass epoxy PCB of 74.2mm×74.2 mm×1.6 mm
○Recommended operating conditions
Parameter
Power Supply Voltage (at start-up)
Power Supply Voltage (after start-up)
VREF Pin Connecting Catacitor
VREGA Pin Connecting Capacitor
PWM7 freqency
【Oscillator】
Oscillator (CH1,3,4)
OSC Timing Resistor
MIN
Limit
TYP
MAX
VCC1
VCC2
CVREF
CVREGA
fpwm
2.2
2.05
0.047
0.47
20
0.1
1.0
-
5.5
5.5
0.47
4.7
100
V
V
μF
μF
kHz
fosc
RT
0.8
47
1.5
62
1.8
120
MHz
kΩ
Symbol
REV. A
Unit
2/4
○Electrical characteristics（Ta=25℃, VCC=3V, RT=62kΩ, STB1～6=3V,PWM7=2.5V）
Standard Value
Parameter
Symbol
MIN
TYP
MAX
2.2
2.275
Unit
Parameter
Condition
Output Voltage
2.125
V
CH1,2,4 Soft Start time
Io=5mA
【Under Voltage Lockout】
VCC startup voltage
Threshold
VCC minimum
operating voltage
Vuv1
Vuv2
after Turn-On
VREGA startup
voltage
Vuv3
Threshold
VREGA minimum
operating voltage
Vuv4
after Turn-On
【Short Circuit Protection】
Timer Startup
Threshold
Delay time for SCP 1
Vtcinv
Tscp
-
1.95
2.05
V
-
2.05
2.15
V
-
-
2.025
V
VCC=2.2V
-
-
2.15
V
VCC=2.2V
0.42
50
0.48
70
0.54
90
V
msec
1.5
1.7
MHz
RT=62kΩ
Rrequency
CH2,5,6,7
fosc2
0.65
0.75
0.85
MHz
RT=62kΩ
-
-
100
%
Vscp=0V
-
-
100
%
86
92
96
%
Dmax2
INV Threshold
INV7 Threshold 1
INV7 Threshold 2
INV7 Threshold 3
INV7 Threshold 4
VO2S Input Current
3.5
msec
RT=62kΩ
1.5
2.5
msec
RT=62kΩ
CH5 Soft Start time
Tss5
1.8
2.8
3.8
msec
RT=62kΩ
CH6 Soft Start time
Tss6
2.5
3.5
4.5
msec
RT=62kΩ
SW
ON
CH2 Lx21 Highside SW ON
resistance
CH2 Lx21 Lowside SW
ON resisitance
CH2 Lx22 Highside SW ON
resistance
CH2 Lx22 Lowside SW
ON resistance
(※1)
1.3
2.6
5.2
msec
Td1
9
15
21
msec
RT=62kΩ
Td56
0.23
0.42
0.61
msec
RT=62kΩ,
STB1234=H
RON1P
-
300
450
mΩ
Hx1=3.6V
RON1N
-
230
350
mΩ
Hx1=3.6V
RON21P
-
120
180
mΩ
Hx2=3.6V
RON21N
-
120
180
mΩ
Hx2=3.6V,
RON22P
-
150
230
mΩ
VO2=3.4V
RON22N
-
120
180
mΩ
Hx2=3.6V
CH3 Highside SW ON resistance
RON3P
-
300
450
mΩ
Hx3=3.6V
CH3 Lowside SW ON resistace
RON3N
-
230
350
mΩ
Hx3=3.6V
CH4 Highside SW ON resistace
RON4P
-
190
290
mΩ
Hx4=3.6V
CH4 Lowside SW ON resistance
RON4N
-
110
170
mΩ
Hx4=5V
CH5 PMOS SW ON resistace
RON5P
-
600
900
mΩ
Hx56=3.6V
-
-
100
%
Dmax4
86
92
96
%
CH6,7 NMOS SW ON resistance
RON6N
-
500
800
mΩ
IINV
-
0
50
nA
INV1,3～6=3.0V
CH6 Load SW ON resistace
RON67P
-
200
300
mΩ
VINV
0.79
0.80
0.81
V
CH1,3～6
【STB1～6】
mV
PWM7
Duty=100%
VINV7
1
VINV7
2
VINV7
3
VINV7
4
598
630
662
449
473
497
mV
PWM7
Duty=75%
234
252
270
mV
PWM7
Duty=40%
17
32
47
mV
PWM7
Duty=5%
STB
Control
Voltage
VO2
IVO2S
3.332
4.7
3.46
8
V
6.7
8.7
uA
VO2S= 3.4V
-6.00
-5.91
V
INV5 1M//200kΩ,
1MΩ(※2)
3.4
CH5 Output Voltage
VOUT
5
Line Regulation
DVLi
-
4.0
12.5
mV
VCC= 2.2～5V
Output Current
When shorted
Ios
0.2
1.0
-
mA
VREF5=0V
-6.09
VSTBH1
1.5
-
5.5
V
VSTBL1
-0.3
-
0.3
V
RSTB1
250
400
700
kΩ
H Level
VPWMH
2.05
-
4.00
V
L Level
VPWML
0
-
0.40
V
Pull Down Resistance
RPWM
250
400
700
kΩ
CH7 Delay time for shutdown
Toff7
200
300
-
μsec
RLED
-
2
3
Ω
VCC=3.6V
VOVP7
18
19
20
V
VO7 monitor
VCC terminal
ISTB1
-
-
5
μA
Hｘ terminal
ISTB2
-
-
5
μA
Lx terminal
ISTB3
-
-
5
μA
Icc
-
5.0
11.0
mA
STB1234,
STB56
【PWM7】
PWM7
Control
Voltage
RT=62kΩ
【LEDSW】
LED PIN SW ON resistance
【OVP】
OVP Threshold
【Circuit Current】
Circuit Current
（VCC PIN Current）
When circuit is operated by 100% duty at CH1,3 and CH4, SCP timer start.
So it is possible to use only for transition time shorter than Tscp.
Recommend resistor value over 20kΩ between VREF to INV5, because VREF current is under 100uA.
And, Please set resistor value considered phase compensation for coil and output capacitor.
(※3)
Hx56=3.6V
Active
Stand-by
Current
(※2)
Hx56=3.6V
Non Active
Pull Down Resistance
【Reference Voltage Vref for CH5】
(※1)
TDTC
L=6.4μH,
Co=4.7μF
LED 3pcs
(※3)
Dmax3
【CH2 Feedback】
CH2 Output Voltage
2.5
0.5
CH1 Lowside SW ON resistance
【Error AMP】
Input Bias Current
1.5
Tss3
CH1
Highside
resisitance
CH1～7
1.3
Max duty
5,6,7
Max duty
CH2 Lx21
Max duty
CH2 Lx22
Condition
Tss1,2,4
CH1～4 Delay time for
Soft Start
CH 5,6 Delay time for
Soft Start
INV pin monitor
CH4
fosc1
Max duty
4
Unit
【Output Driver】
Frequency CH1,3,4
Dmax1
d
Dmax1
u
Standard Value
TYP
MAX
CH3 Soft Start time
CH7 Soft Start time
【Oscillator】
Max duty
1,3
MIN
【Soft Start】
【Internal Regulator VREGA】
VREG
A
Symbol
Related to LED quantity , LED forward voltage and Input voltage.
◎ This product is not designed for normal operation with in a radioactive environment..
REV. A
INV1-7=1.2V
INV5=-0.2V
VCC= 3.0V
3/4
GND
RT
INV4
INV1
INV3
26
25
24
23
22
21
SCP
VREF5
27
VREGA
INV5
○PIN Assignment ・Block Diagram
20
19
2.5V
REG
18 VO2S
+
+
-
INV7 29
-
-
+
-
+
-
-
+
1.0V
VREF
+
OSC
INV6 28
17
VCC
+
-
30
16 VO2
VO7 31
PWM7 32
HS6L
33
HX567
34
15 LX22
OVP
PWM &
LOGIC BLOCK
FILTER
PRE DRIVER
LED
14 PGND2
13 LX21
12
HX2
PRE DRIVER
PRE
DRIVER
STB56
35
11 LX3
PRE
DRIVER
36
PRE DRIVER
LX5
PRE DRIVER
PRE
DRIVER
10 PGND13
1
2
3
4
5
6
7
8
9
LX6
PGND567
LX7
PGND4
LX4
HX4
STB1234
HX13
LX1
B.G CTL
○Package
Fig .1
○PIN Description
端 子 名
機
VCC
IC Power Supply Input
GND
Ground
能
PGND13,2,4,567 Ground for Internal FET
VREGA
BD9354
VREF5
Hx13,2,4,567
Lx1,3,4,5,6,7
Terminal for Connecting Inductor
Lx22
VO2
CH2 DC/DC Output
Output Terminal for Internal
Load Switch
VO2S
RT
SCP
STB1234,56
PWM7
REV. A
Terminal for Connecting Inductor
For CH2 Input
Terminal for Connecting Inductor
For CH2 Output
HS6L
INV1,3,4,5,6,7
図-2
CH5 Reference Output
CH1～3,5,6 Pch FET Source Terminal ,
FET Driver Power Supply
Lx21
LOT No.
VREGA Output
Error Amp Inverted Input
CH2 Output Feedback Terminal
Terminal for Connecting a Resister
To Set the OSC Frequency
SCP Timer Flag Terminal
CH1～CH6 ON/OFF Control Terminal
CH7 ON/OFF Control,
PWM Dimming Input
LED
Terminal for connecting LED Cathode
VO7
CH7 DC/DC Output
4/4
○Operation Notes
１.) Absolute maximum ratings
This product is produced with strict quality control. However, the IC may be destroyed if operated beyond its absolute
maximum ratings. If the device is destroyed by exceeding the recommended maximum ratings, the failure mode will be difficult
to determine. (E.g. short mode, open mode) Therefore, physical protection counter-measures (like fuse) should be implemented
when operating conditions beyond the absolute maximum ratings anticipated.
２.) GND potential
Make sure GND is connected at lowest potential. All pins except NON5, must not have voltage below GND. Also, NON5 pin must
not have voltage below - 0.3V on start up.
３.) Setting of heat
Make sure that power dissipation does not exceed maximum ratings.
４.) Pin short and mistake fitting
Avoid placing the IC near hot part of the PCB. This may cause damage to IC. Also make sure that the output-to-output and output
to GND condition will not happen because this may damage the IC.
５.) Actions in strong magnetic field
Exposing the IC within a strong magnetic field area may cause malfunction.
６.) Mutual impedance
Use short and wide wiring tracks for the main supply and ground to keep the mutual impedance as small as possible. Use inductor
and capacitor network to keep the ripple voltage minimum.
７.) Thermal shutdown circuit (TSD circuit)
The IC incorporates a built-in thermal shutdown circuit (TSD circuit). The thermal shutdown circuit (TSD circuit) is designed only
to shut the IC off to prevent runaway thermal operation. It is not designed to protect the IC or guarantee its operation. Do not
continue to use the IC after operating this circuit or use the IC in an environment where the operation of this circuit is assumed.
８.) Rush current at the time of power supply injection.
An IC which has plural power supplies, or CMOS IC could have momentary rush current at the time of power supply injection.
Please take care about power supply coupling capacity and width of power Supply and GND pattern wiring.
９.) IC Terminal Input
This IC is a monolithic IC that has a P- board and P+ isolation for the purpose of keeping distance between elements. A P-N junction
is formed between the P-layer and the N-layer of each element, and various types of parasitic elements are then formed.
For example, an application where a resistor and a transistor are connected to a terminal (shown in Fig.15):
○When GND > (terminal A) at the resistor and GND > (terminal B) at the transistor (NPN), the P-N junction operates as
a parasitic diode.
○When GND > (terminal B) at the transistor (NPN), a parasitic NPN transistor operates as a result of the NHayers of other
elements in the proximity of the aforementioned parasitic diode.
Parasitic elements are structurally inevitable in the IC due to electric potential relationships. The operation of parasitic elements
Induces the interference of circuit operations, causing malfunctions and possibly the destruction of the IC. Please be careful not to
use the IC in a way that would cause parasitic elements to operate. For example, by applying a voltage that is lower than the
GND (P-board) to the input terminal.
Transistor (NPN)
B
E
（Terminal B）
C
Resistor
（Terminal A）
GND
（TerminalＡ）
P
P＋
N
N
P-board
P
P＋
P＋
N
N
Ｎ
P＋
Parasitic element
N
P-board
Parasitic
element
～
～
N
GND
Parasitic
l
t
Fig - 3 Simplified structure of a Bipolar IC
REV. A
GND
Notice
Notes
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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 responsibility for such damage.
The technical information specified herein is intended only to show the typical functions of and
examples of application circuits for the Products. ROHM does not grant you, explicitly or
implicitly, any license to use or exercise intellectual property or other rights held by ROHM and
other parties. ROHM shall bear no responsibility whatsoever for any dispute arising from the
use of such technical information.
The Products specified in this document are intended to be used with general-use electronic
equipment or devices (such as audio visual equipment, office-automation equipment, communication devices, electronic appliances and amusement devices).
The Products specified in this document are not designed to be radiation tolerant.
While ROHM always makes efforts to enhance the quality and reliability of its Products, a
Product may fail or malfunction for a variety of reasons.
Please be sure to implement in your equipment using the Products safety measures to guard
against the possibility of physical injury, fire or any other damage caused in the event of the
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shall bear no responsibility whatsoever for your use of any Product outside of the prescribed
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R1120A