ROHM BH9992GU

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■ Structure
Silicon Monolithic Integrated Circuit
■ Product Name
For DSC handshake guard, signal processing and motor driving IC
■ Model Name
BH9992GU
■ Function
・
・
・
・
・
・
・
・
GYROAMP 2ch
HALLAMP 2ch
R-2R type 8bit D/A converter 5ch
R-2R type 10bit D/A converter 2ch
No dead zone system PWM Driver
SAW wave oscillator
Regulator
Rail to Rail AMP
■ Absolute maximum ratings
Item
Symbol
Standard value
Unit
Power supply voltage
VC, VDD, PVCC
7.0
V
Power dissipation （*1）
PD
1400
mW
Operation temperature
TOPR
-10～70
℃
range
Storage temperature
TSTG
-40～125
℃
range
H Bridge output current1
IOUT1
300
mA
H Bridge output current2
IOUT2
500
mA
（*2）
*1 Mounting board specification（Rohm standard board） Material：The glass fabric base epoxy
Dimensions：50[mm]×58[mm]×1.75[mm] (8 layers)
When using it at Ta=25℃ or more, 14 [mW] of 1[℃] decreases.
*2 Instantaneous current（1[us] or less）
■ Operating condition
Item
Symbol
Min.
Typ.
Max.
VC power supply voltage
VC
3.0 (*3)
3.3
5.5
VDD power supply voltage（≦VC）
VDD
2.5
3.0
5.5
PVCC power supply voltage
PVCC
3.0
5.0
5.5
Serial clock frequency
FSCLK
―
1.0
4.0
DACOUT limit load capacity 1
CLA1
―
―
0.1
(DAC0OUT,DAC3OUT,DAC4OUT)
Between VDDOUT and GND,
CLVDDOUT
1.0
―
30.0
load capacity
*3 When VDDOUT is used, the Min. operating condition of VC power supply voltage is 3.2[V].
・A radiation is not designed.
REV. D
Unit
V
V
V
MHz
μF
μF
2/8
■
Physical Dimension
Package type nama ： VCSP85H4
BH9992
Lot. No.
■ CHIP Backside PIN Arrangement
AMP4
AMP4
H
+IN
-IN
AMP2
AMP4
AMP9
G
OUT
OUT
+IN
AMP2
AMP7
F
GND1
-IN
OUT
AMP7
VDD
E
VC1
-IN
OUT
AMP9
AMP8
AMP9
D
OUT
-IN
-IN
AMP10
AMP10
C
OUT
-IN
AMP10
VC3
B
GND3
+IN
A
PGND1
OUT1F
1
2
3
AMP3
-IN
AMP3
OUT
AMP1
OUT
DAC4
OUT
AMP8
OUT
XSTBY
REV. D
VDD2
AMP1
-IN
DAC0
OUT
DAC3
OUT
DAC6
OUT
AGND
AMP11
OUT
AMP11
-IN
VREF1
IN
AMP12
-IN
DAC5
OUT
AMP11
+IN
AMP13
OUT
VDD1
AMP14
OUT
AMP12
OUT
VC2
LD
DATA
CLK
GND2
OUT1R
4
PVCC
5
OUT2R
6
OUT2F
7
Please keep open for the terminal, when you use.
Fig.1 Physical Dimension (Unit ： mm)
AMP3
+IN
AMP13
-IN
AMP13
+IN
AMP14
-IN
AMP14
+IN
AMP12
+IN
PGND2
8
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■ PIN Description
PIN No.
Pin Name
1-A
―
2-A
3-A
4-A
5-A
PGND1
OUT1F
OUT1R
PVCC
6-A
OUT2R
7-A
8-A
1-B
2-B
3-B
4-B
OUT2F
―
AMP10+IN
GND3
VC3
LD
5-B
6-B
7-B
8-B
1-C
2-C
3-C
4-C
5-C
6-C
7-C
8-C
1-D
2-D
3-D
4-D
5-D
6-D
7-D
8-D
DATA
CLK
GND2
PGND2
AMP10-IN
AMP10OUT
―
XSTBY
DAC6OUT
DAC5OUT
VC2
AMP12+IN
AMP9-IN
AMP9OUT
AMP8-IN
AMP8OUT
DAC3OUT
AMP12-IN
AMP12OUT
AMP14+IN
Pin explanation
―
PIN No.
1-E
Pin Name
VDDOUT
Power block ground
CH1 forward output
CH1 reverse output
Power block power
supply
CH2 reverse output
2-E
3-E
4-E
5-E
VC1
AMP7-IN
DAC4OUT
DAC0OUT
6-E
VREF1IN
CH2 forward output
―
AMP10+Input
GND
VC power supply
Serial data loading
input
Serial data input
Serial clock input
GND
Power block ground
AMP10-input
AMP10 output
―
Standby control input
DAC6 output
DAC5 output
VC power supply
AMP12+input
AMP9-input
AMP9 output
AMP8-input
AMP8 output
DAC3 output
AMP12-input
AMP12 output
AMP14+input
7-E
8-E
1-F
2-F
3-F
4-F
AMP14OUT
AMP14-IN
GND1
AMP2-IN
AMP7OUT
AMP1OUT
AMP reference
input
AMP14 output
AMP14-input
GND
AMP2-input
AMP7 output
AMP10 output
5-F
6-F
7-F
8-F
1-G
2-G
3-G
4-G
5-G
6-G
7-G
8-G
1-H
2-H
3-H
4-H
5-H
6-H
7-H
8-H
AMP1-IN
AMP11-IN
VDD1
AMP13+IN
AMP9+IN
AMP2OUT
AMP4OUT
AMP3OUT
VDD2
AMP11OUT
AMP13OUT
AMP13-IN
―
AMP4+IN
AMP4-IN
AMP3-IN
AMP3+IN
AGND
AMP11+IN
―
AMP1-input
AMP11-input
VDD power supply
AMP13+input
AMP9+input
AMP2 output
AMP4 output
AMP3 output
VDD power supply
AMP11 output
AMP13 output
AMP13-input
―
AMP4+input
AMP4- input
AMP3- input
AMP3+ input
Analog GND
AMP11+input
―
REV. D
Pin explanation
VDD regulator
output
VC power supply
AMP7-input
DAC4 output
DAC0 output
4/8
■ Whole Block Diagram
GYRO AMP1
(VDD)
AMP7OUT
AMP7-IN
HALL AMP2
(VDD)
HALL AMP1
(VDD)
AMP9+IN
GYRO AMP2
(VDD)
AMP2-IN
AMP8-IN
VDD (VC)
GND1
DAC7ch
(VC standard voltage is VDD)
VC1
VDDOUT
AMP9OUT
AMP9-IN
XSTBY
PWM1
(VC)
PWM2
(VC)
LOGIC
(VC)
AMP10OUT
AMP10-IN
VC3
AMP10+IN
GND3
Pre
Driver1
VC,
PVCC
Pre
Driver2
VC,
PVCC
POWER Driver1
(PVCC)
Fig.2
POWER Driver2
(PVCC)
Whole Block Diagram
REV. D
VREF1IN
AMP12-IN
AMP13-IN
VDD1
AMP14OUT
AMP13+IN
DAC6OUT
AMP12OUT
AMP14-IN
DAC5OUT
AMP14+IN
VC2
AMP12+IN
GND2
LD
DATA
PGND
CLK
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■ Electrical characteristic
◎Circuit current（VC=3.3[V], VDD=3.0[V], PVCC=5.0[V], DAC0OUT=VREF1IN, Ta=25[℃] except as otherwise noted.）
Standard value
Item
Symbol
Unit
Notes
Min. Typ. Max.
Current consumption 1 at standby
ISTBY
－
1.5
10
μA XSTBY, CLK, DI, LD=L
(VC+VDD+PVCC)
Current consumption1 when operating
DAC0=080H
ICC1
－
4.0
6.0
mA
(VC+VDD)
DAC1,2,3,4,5,6=000H
Current consumption2 when operating
DAC0=080H, DAC1,2,3,4,=0FFH
ICC2
－
11.0 16.5
mA
(VC+VDD)
DAC 5,6,=3FFH
Current consumption3 when operating
ICC3
－
25
50
μA XSTBY=H, POWSTBY_N=”0”
(PVCC)
◎HALL Sensor input _AMP
（VC=3.3[V], VDD=3.0[V], PVCC=5.0[V], DAC0=080H, DAC0OUT=VREF1IN, Ta=25[℃] except as otherwise noted）
Standard value
Item
Symbol
Unit
Notes
Min. Typ. Max.
<HALL_AMP (A1,A2)>
DAC1, 2=0FFH
Output voltage
H1VOUT
2.50
－
－
V
External 500[Ω], 270[Ω]
Output voltage range (Hi)
DAC1, 2=0FFH
H1VOH
2.40
－
－
V
(Open loop)
Outflow current 5.0[mA],
Output voltage range (Low)
DAC1, 2=000H
H1VOL
－
－
0.4
V
(Open loop)
Inflow current 5.0[mA], VIN=250[mV]
◎HALL Sensor output _AMP
（VC=3.3[V], VDD=3.0[V], PVCC=5.0[V], DAC0, DAC3, DAC4=080H, DAC0OUT=VREF1IN, Ta=25[℃] except as otherwise noted）
Standard value
Item
Symbol
Unit
Notes
Min. Typ. Max.
<HALL_AMP (A3,A4,A9,A10)>
Output voltage 1
H2VOUT1
2.9
－
－
V
VINP=1.2[V], VINN=1.1[V]
(Open loop)
Output voltage 2
H2VOUT2
－
－
0.2
V
VINP=1.1[V], VINN=1.2[V]
(Open loop)
VIN=10[mVpp] (Differential voltage input)
Voltage gain
H2GVD
38.5 40.0 41.5
dB
f=100[Hz]
Cutoff frequency
H2fc
4.1
8.1
12.1
kHz -3[dB], Capa 10[pF]
<HALL_AMP (A5-A7, A6-A8)>
VINP Input=1.125, VINN Input=0.375
Output voltage 1
H3VOUT1
2.8
－
－
V
HALLSW1,3=ON, HALLSW2=OFF
DAC0=0BFH, DAC3,4=040H
VINP Input=0.375, VINN Input=1.125
Output voltage 2
H3VOUT2
－
－
0.2
V
HALLSW1,3=ON, HALLSW2=OFF
DAC0=040H, DAC3,4=0BFH
VINP Input=0.0[V], VINN Input=3.0[V]
Output voltage 3
H3VOUT3
2.8
－
－
V
HALLSW2=ON, HALLSW1,3=OFF
DAC3,4=0AAH
VINP Input=0.0[V], VINN Input=0.0[V]
Output voltage 4
H3VOUT4
－
－
0.2
V
HALLSW2=ON, HALLSW1,3=OFF
DAC3,4=055H
VIN=10[mVpp] (Differential voltage input)
Voltage gain
H3GVD
-1.5
0
1.5
dB
f=100[Hz]
Cutoff frequency
H3fc
23.0 46.0 69.0
kHz -3[dB], Capa 33[pF]
REV. D
6/8
◎GYRO_AMP
（VC=3.3[V], VDD=3.0[V], PVCC=5.0[V], DAC0=080H, DAC0OUT=VREF1IN, Ta=25[℃] except as otherwise noted）
Standard value
Item
Symbol
Unit
Notes
Min. Typ. Max.
<GYRO_AMP (A11,A12)>
Output voltage 1
G1VOUT1
2.9
－
－
V
VINP =1.2[V], VINN =1.1[V]
(Open loop)
Output voltage 2
G1VOUT2
－
－
0.2
V
VINP =1.1[V], VINN =1.2[V]
(Open loop)
VIN=10[mVpp] (Differential voltage input)
Voltage gain
G1GVD
38.5 40.0 41.5
dB
f=100[Hz]
Cutoff frequency
G1fc
4.1
8.1
12.1 kHz -3[dB], Capa 33[pF]
<GYRO_AMP (A13,A14)>
GYROSW2=ON,
Output voltage 1
G2VOUT1 1.30 1.50 1.70
V
GYROSW1, At GYROSW3=OFF,
VINP=open
GYROSW1, GYROSW2=ON,
Output voltage 2
G2VOUT2
1.1
1.50 1.90
V
At GYROSW3=OFF,
VINP=open
GYROSW2=ON, At GYROSW3=OFF
Voltage gain
G2GVD
36.3 37.8 39.3
dB
VIN=10[mVpp] (Differential voltage input)
f=100[Hz]
GYROSW2=ON, At GYROSW3=OFF
Cutoff frequency
G2fc
1.1
2.1
3.1
kHz
-3[dB], Capa 100[pF]
GYROSW2=ON, At GYROSW3=ON
Voltage gain
G2GVD2
32.5 34.0 35.5
dB
VIN=10[mVpp] (Differential voltage input)
f=100[Hz]
GYROSW2=ON, At GYROSW3=ON
Cutoff frequency
G2fc2
1.7
3.3
4.9
kHz
-3[dB], Capa 100[pF]
REV. D
7/8
■ Directions
1．Absolute maximum ratings
This IC might be destroyed when the absolute maximum ratings, such as impressed voltages
(VC,PVCC,VDD) or the operating temperature range (TOPR) is exceeded, and whether the destruction is
short circuit mode or open circuit mode cannot be specified. Please take into consideration the physical
countermeasures for safety, such as fusing, if a particular mode that exceeds the absolute maximum rating
is assumed.
2．Reverse polarity connection
Connecting the power line to the IC in reverse polarity (from that recommended) will damage the part.
Please utilize the direction protection device as a diode in the supply line.
3．Power supply line
Due to switching and EMI noise generated by magnetic components (inductors and motors), using
electrolytic and ceramic suppress filter capacitors close to the IC power input terminals (Vcc and GND) is
recommended. Please note: the electrolytic capacitor value decreases at lower temperatures.
4．GND line
The ground line is where the lowest potential and transient voltages are connected to the IC.
5．Thermal design
Do not exceed the power dissipation (Pd) of the package specification rating under actual operation, and
please design enough temperature margins. (Refer to page 10.)
6．Short circuit mode between terminals and wrong mounting
Do not mount the IC in the wrong direction and be careful about the reverse-connection of the power
connector. Moreover, this IC might be destroyed when the dust short the terminals between them or GND.
7．Radiation
Strong electromagnetic radiation can cause operation failures.
8．ASO(Area of Safety Operation.)
Do not exceed the maximum ASO and the absolute maximum ratings of the output driver.
9．TSD(Thermal shut-down)
The TSD is activated when the junction temperature (Tj) reaches 1750C(with +/-250C hysteresis), and the
output terminal is switched to Hi-z. The TSD circuit aims to intercept IC from high temperature. The
guarantee and protection of IC are not purpose. Therefore, please do not use this IC after TSD circuit
operates, nor use it for assumption that operates the TSD circuit.
10．Capacitor between output and GND
If a large capacitor is connected between the output and GND, this IC might be destroyed when Vcc
becomes 0V or GND, because the electric charge accumulated in the capacitor flows to the output. Please
set said capacitor to smaller than 0.1μF.
REV. D
8/8
11．Inspection by the set circuit board
The stress might hang to IC by connecting the capacitor to the terminal with low impedance. Then, please
discharge electricity in each and all process. Moreover, in the inspection process, please turn off the power
before mounting the IC, and turn on after mounting the IC. In addition, please take into consideration the
countermeasures for electrostatic damage, such as giving the earth in assembly process, transportation or
preservation.
12．Each input terminal
This IC is a monolithic IC, and has P+ isolation and P substrate for the element separation. Therefore, a
parasitic PN junction is firmed in this P-layer and N-layer of each element. For instance, the resistor or the
transistor is connected to the terminal as shown in the figure below. When the GND voltage potential is
greater than the voltage potential at Terminals A or B, the PN junction operates as a parasitic diode. In
addition, the parasitic NPN transistor is formed in said parasitic diode and the N layer of surrounding
elements close to said parasitic diode. These parasitic elements are formed in the IC because of the voltage
relation. The parasitic element operating causes the wrong operation and destruction. Therefore, please be
careful so as not to operate the parasitic elements by impressing to input terminals lower voltage than
GND(P substrate). Please do not apply the voltage to the input terminal when the power-supply voltage is
not impressed. Moreover, please impress each input terminal lower than the power-supply voltage or equal
to the specified range in the guaranteed voltage when the power-supply voltage is impressing.
Resister
Transistor(NPN)
Terminal　B
Terminal　A
C
Terminal　B
B
E
Terminal　A
B
P+
P
P+
Parasitic
element
C
E
P+
P
P-Substrate
P+
P-Substrate
Surrounding
elements
Parasitic
element
GND
Parasitic
element
Parasitic
element
GND
GND
GND
Simplified structure of IC
13．Earth wiring pattern
Use separate ground lines for control signals and high current power driver outputs. Because these high
current outputs that flows to the wire impedance changes the GND voltage for control signal. Therefore,
each ground terminal of IC must be connected at the one point on the set circuit board. As for GND of
external parts, it is similar to the above-mentioned.
14．Reverse brake
When you do the reversal brake from the high-velocity revolution note the counter electromotive force.
Moreover, confirm the output current enough and examine the rotational speed which uses the reversal
brake.
15．About the capacitor between PVCC-PGND
The PVCC-PGND capacitor absorbs the change in a steep voltage and the current because of the PWM drive. As a result,
there is a role to suppress the disorder of the PVCC voltage. However, the effect decreases by the influence of the wiring
impedance etc. if the capacitor becomes far from IC. Arrange the PVCC-PGND capacitor near IC.
16．Bypass capacitor
Between the supply power supplies connect the bypass capacitor(0.1μF) near the pin of this IC.
REV. D
Notice
Notes
No copying or reproduction of this document, in part or in whole, is permitted without the
consent of ROHM Co.,Ltd.
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 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
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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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