BD6300KU-E2 [ROHM]
Disk Drive Motor Controller, 0.8A, PQFP64, ROHS COMPLIANT, UQFP-64;型号: | BD6300KU-E2 |
厂家: | ROHM |
描述: | Disk Drive Motor Controller, 0.8A, PQFP64, ROHS COMPLIANT, UQFP-64 电动机控制 |
文件: | 总17页 (文件大小:763K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
TECHNICAL NOTE
Motor Driver IC Series for Tape Record System
3 in 1 Motor Driver
for Digital Video Camera
BD6637KV/KS, BD6300KU
ʀDescription
The low power consumption, 3 in 1 motor driver, utilizes a DMOS linear output driver. It integrates the capstan, cylinder,
loading motor driver, and amplifier of each sensor signal that is required for digital video camera systems.
ʀFeatures
3-phase motor driver for capstan
1) 3-phase full wave drive system (pseudo-linear)
2) Output stage DMOS drive system
3) Built-in torque ripple canceling circuit
4) Built-in output Tr saturation preventing circuit (lower)
5) Equipped with a VM power supply control terminal
6) Built-in normal, reverse, and short brake function
7) Built-in FG sensor amplifier
3-phase sensor-less motor driver for cylinder
1) Soft switching drive system
2) Output stage DMOS drive system
3) Built-in output Tr saturation preventing circuit (lower)
4) Equipped with a VM power supply control terminal
5) Built-in startup circuit
6) Built-in FG/PG sensor amplifier
Reversible motor driver for loading
1) Output stage DMOS drive system
2) Normal/Reverse rotation and braking 3 mode output
3) Any setting of output voltage with L_REF terminal available
Built-in TSD
Built-in voltage rise circuit
Power saving function
ʀApplications
Portable video equipment, such as digital video cameras, VTR, and 8-mm video cameras.
Ver.B Oct. 2005
ʀProduct lineup
ꢀ
Item
BD6637KV/KS
BD6300KU
3-phase pseudo-linear drive
(DMOS linear drive)
3-phase pseudo-linear drive
(DMOS linear drive)
Capstan
Cylinder
Loading
3-phase sensor-less soft switching drive
(DMOS linear drive)
3-phase sensor-less soft switching drive
(DMOS linear drive)
DMOS H bridge drive
DMOS H bridge drive
Capstan FG signal, Cylinder PG signal
(coil sense), Cylinder FG signal waveform
coordinate
Capstan FG signal, Cylinder PG signal
(hall sense), Cylinder FG signal, Reel
sensor signal waveform coordinate
Sensor
Amplifier
Package
VQFP64/SQFP56
UQFP64
ꢀ ꢀ ꢀ ꢀ ꢀ
ʀAbsolute maximum ratings (Ta=25@)
Unit
Symbol
Limit
Parameter
VCC
UNREG
C_VM
D_VM
L_VM
7
15
V
V
Supply voltage
10
V
10
V
7
V
BD6637KV/KS
1250
1750
ዉ25ጚ+75
ዉ40ጚ+150
150
mW
mW
@
Pd
Power dissipation
BD6300KU
Operate temperature
Storage temperature
Junction temperature
Topr
Tstg
@
Tjmax
@
BD6637KV/KS
BD6300KU
1000
800
mA
mA
Output max current
Iomax
70mm470mm41.6mm glass epoxy board. Reduced by 14mW/@ when Ta=25@
However, do not exceed Pd, ASO and Tj=150@(Common to 3 drivers)
ʀOperating conditions
VCC
UNREG
C_VM
D_VM
L_VM
V
V
V
V
V
2.7 ጚ 4.5
5 ጚ 12
Supply voltage
0 ጚ 8
0 ጚ 8
4.5 ጚ 5.5
UNREG C_VM
UNREG D_VM
L_VM VCC
2/16
ʀElectrical characteristics
BD6637KV/KS (Unless otherwise specified Ta=25@,VCC=3V, C_VMዙD_VMዙL_VM=5VወUNREG=7.2V)
Limit
Parameter
Symbol
Unit
Conditions
Fig No.
Min.
Typ.
Max.
<TOTAL>
VCC Circuit current 1
VCC Circuit current 2
UNREG stand by current
PS input switching level
VG voltage
Icc1
Icc2
6
13
ዉ
20
5
mA
ꢁA
Power save OFF
Power save ON
Power save ON
Fig.1
Fig.2
Fig.3
ዉ
IUNREG
PS
ꢁA
ዉ
ዉ
5
0.6
9.5
1.4
11
2
V
V
ዉ
VG
12.5
Fig.4,5
<CAPSTAN OUTPUT>
Output H voltage
C_VOH
C_VOL
ዉ
ዉ
0.35
0.4
0.55
0.65
V
V
IOUT=-400mA
Fig.6
Fig.7
Output L voltage
IOUT=400mA,C_RNF=0.33Q
<CAPSTAN HALL AMP>
In-phase input voltage range
Hall input offset range
<CAPSTAN F/B/R>
C_VCM
1.2
-15
ዉ
ዉ
VCC-1.1
15
V
ዉ
ዉ
C_VHOF
mV
Forward rotation control
Brake voltage range
Reverse rotation control
<CAPSTAN TORQUE CONTROL>
EC input bias current
Torque control input/output gain
Torque control start voltage
Current limit voltage
Ripple cancel ratio
C_VFWD
C_VBRK
ዉ
ዉ
1.5
ዉ
0.7
1.7
ዉ
V
V
V
ዉ
ዉ
ዉ
1.3
2.3
C_VREV
C_IEC
C_GIO
ꢁA
ዉ
ዉ
0.35
1.05
0.2
8
3
7.5
0.65
1.35
0.28
32
C_EC=VCC
0.5
1.2
0.24
20
A/V
V
C_RNF=0.33Q,C_RCC=3.3kQ
Fig.8
Fig.8
Fig.8
ዉ
C_VECOFS
C_Climit
V
C_RNF=0.33Q,C_RCC=3.3kQ
IOUT=400mA,C_RCC=3.3kQ
C_VRCC
%
<CAPSTAN VS>
Voltage gain
C_GVS
7
8
9
TIMES
V
ዉ
ዉ
Output H voltage
IOVS=1mA,
C_VVSOH
ዉ
0.5
0.8
Output L voltage
C_VVSOL
ዉ
0.13
0.25
0.2
0.38
V
V
IOVS=50ꢁA
DC/DC43 in use
ዉ
ዉ
VS offset voltage
<CAPSTAN FGAMP>
Input offset voltage
DC bias voltage
C_VVSOFS
0.12
C_VFGOFS
C_VFG
ዉ
ዉ
-12
1.3
50
ዉ
1.5
59
12
1.7
mV
V
Voltage gain 1
C_AV1
Fig.20
Fig.20
ዉ
ዉ
dB
dB
V
f=3kHz
Voltage gain 2
C_AV2
30
0.35
36
ዉ
f=50kHz
In-phase input voltage range
Output H voltage
C_VFGCM
ዉ
VCC-1.1
0.5
IOH=0.2mA,
IOL=1mA
C_VFGAOH
C_VFGAOL
ዉ
ዉ
0.3
0.1
V
ዉ
ዉ
Output L voltage
0.3
V
<CAPSTAN FGHYS>
C_FG hysteresis width
DC bias voltage
C_VFGHYS
C_VFG+
30
1.3
ዉ
46
1.5
0.1
62
1.7
mV
V
Fig.22
ዉ
Output L voltage
C_VFGSOL
0.3
ዲ
IOL=1mA
Fig.21
<CYLINDER OUTPUT>
Output H voltage
D_VOH
D_VOL
ዉ
ዉ
0.3
0.4
0.5
V
V
IOUT=-400mA
IOUT=400mA,C_RNF=0.33Q
Fig.9
Output L voltage
0.65
Fig.10
<CYLINDER TORQUE CONTROL>
EC input bias current
D_IEC
ꢁA
ዉ
ዉ
2
5
D_EC=VCC
Torque control input/output gain
D_GIO
0.45
1.05
0.217
0.66
1.2
0.87
1.35
0.332
A/V
V
D_RNF=0.33ꢀ
Fig.11
Fig.11
Fig.11
Torque control start voltage
Current limit voltage
D_VECOFS
D_Climit
0.274
V
D_RNF=0.33ꢀ
3/16
BD6637KV/KS (Unless otherwise specified Ta=25@,VCC=3V, C_VMዙD_VMዙL_VM=5VወUNREG=7.2V)
Limit
Typ.
Symbol
<CYLINDER STARTING/DETECTION/SLOPE>
Unit
Conditions
Parameter
Fig No.
Min.
Max.
DETECT terminal charge current
DETECT terminal discharge current
DETECT terminal H voltage
DETECT terminal L voltage
ISET voltage
SL1,2 charge current
SL1,2 discharge current
SL1,2 H voltage
D_IDETO
D_IDETI
D_VDETH
D_VDETL
D_VISET
D_ISLO
D_ISLI
D_VSLH
D_VSLL
2
2
1.1
0.5
0.32
16
17
2.5
0.85
5
5
10
10
1.5
0.8
0.48
28
ꢁA
ꢁA
V
V
V
ꢁA
ꢁA
V
Fig.12
Fig.12
Fig.13
Fig.13
Fig.14
Fig.15
Fig.15
Fig.16
Fig.16
1.3
0.65
0.4
22
24
2.8
1
RD_ISET=18kꢀ
RD_ISET=18kꢀ
RD_ISET=18kꢀ
31
ዉ
SL1,2 L voltage
1.15
V
SL1,2 charge and discharge
D_RSL
0.82
1.6
0.89
2
0.96
2.4
ዉ
ዉ
current ratio
SL switching EC level
< CYLINDER VS>
Voltage gain
D_VECSL
V
D_GVS
7
8
9
TIMES
V
ዉ
ዉ
IOVS=1mA,
between VCC and output
Output H voltage
0.5
0.8
D_VVSOH
ዉ
Output L voltage
VS offset voltage
<CYLINDER FGAMP>
Input offset voltage
DC bias voltage
Voltage gain 1
Voltage gain 2
In-phase input voltage range
D_VVSOL
D_VVSOFS
ዉ
0.13
0.25
0.2
0.38
V
V
IOVS=50ꢁA
DC/DC43 in use
ዉ
ዉ
0.12
D_VFGOFS
D_VFG+
D_FAV1
D_FAV2
D_VFGCM
-12
1.3
50
30
0.35
ዉ
1.5
59
36
ዉ
12
1.7
mV
V
dB
dB
V
ዉ
ዉ
ዉ
f=3kHz
f=50kHz
Fig.20
Fig.20
ዉ
ዉ
VCC-1.1
IOH=-0.2mA,
Output H voltage
D_VFGAOH
ዉ
ዉ
0.3
0.5
V
V
ዉ
ዉ
between VCC and output
Output L voltage
D_VFGAOL
0.15
0.35
IOL=1mA
<CYLINDER FGHYS>
Measure D_FGAMP at 1K
feed back resistance
D_FG hysteresis width
D_VFGHYS
ꢂ84
ꢂ110
ꢂ136
mV
Fig.24
Measure D_FGAMP at 1K
DC bias voltage
D_VFG+
1.3
1.5
0.1
1.7
0.3
V
V
ዉ
feed back resistance
Output L voltage
<CYLINDER PGAMP>
Input offset voltage
DC bias voltage
Voltage gain 1
Voltage gain 2
D_VFGSOL
IOL=1mA
Fig.21
ዉ
D_VPGOFS
D_VPG+
D_PAV1
D_PAV2
D_VPGCM
17
1.7
-12
1.3
50
30
0.35
ዉ
1.5
59
36
ዉ
mV
V
dB
dB
V
ዉ
ዉ
ዉ
f=3kHz
f=50kHz
Fig.20
Fig.20
ዉ
ዉ
In-phase input voltage range
VCC-1.1
IOH=-0.2mA,
Output H voltage
D_VPGAOH
ዉ
ዉ
0.3
0.5
V
V
ዉ
ዉ
between VCC and output
Output L voltage
<CYLINDER PGHYS>
D_PG hysteresis width
DC bias voltage
Output L voltage
<LOADING>
D_VPGAOL
0.15
0.35
IOL=1mA
D_VPGHYS
D_VPG+
D_VPGSOL
ꢂ118 ꢂ144
1.3
ዉ
ꢂ170
1.7
0.3
mV
V
V
Fig.23
ዉ
ꢀ
1.5
0.1
IOL=1mA
Fig.21
IOUT=200mA,L_REF=L_VM
Total saturation voltage of low and
high side output transistor
Fig.
17,18
Output saturation voltage
L_VSAT
ዉ
0.3
0.5
V
L_REF pin input current
Vout-L_REF offset
L_IIREF
L_VOFS
ዉ
0.3
100
2
200
ꢁA
mV
ዉ
0
Fig.19
Forward rotation control
L_VFWD
L_VBRK
L_VREV
L_VREF
ዉ
1.3
2.3
ዉ
ዉ
1.5
ዉ
0.7
1.7
ዉ
V
V
ዉ
ዉ
ዉ
ዉ
voltage range
Brake voltage range
Reverse rotation control
voltage range
V
L_REF output open voltage
ዉ
1.3
ዲ
4/16
ʀElectrical characteristics
BD6300KU (Unless otherwise specified Ta=25@,VCC=3V, C_VMዙD_VMዙL_VM=5VወUNREG=7.2V)
Limit
Typ.
Symbol
Unit
Conditions
Parameter
Fig No.
Min.
Max.
<TOTAL>
VCC Circuit current 1
5
1
mA
mA
Icc1
Icc2
Power save OFF
Power save ON
11
4
17
7
Fig.25
Fig.26
VCC Circuit current 2
Fig.
28,29
VG
9.5
11
12.5
V
VG voltage
<CAPSTAN OUTPUT>
Output H voltage 1
C_VOH1
C_VOH2
C_VOL
ዉ
ዉ
ዉ
0.1
0.2
0.2
0.16
0.32
0.32
V
V
V
IOUT=-200mA
Fig.31
Fig.31
Fig.32
Output H voltage 2
IOUT=-400mA
IOUT=200mA,C_RNF=0.33Q
Output L voltageꢀ
<CAPSTAN HALL AMP>
In-phase input voltage range
C_VCM
1.2
-15
ዉ
ዉ
VCC-1.1
V
ዉ
ዉ
Hall input offset range
<CAPSTAN PS, F/B/R>
C_VHOF
15
mV
C_PS
ዉ
ዉ
ዉ
ዉ
0.7
ዉ
1.4
ዉ
2
V
V
V
V
C_PS input threshold levelꢀ
Forward rotation control
voltage range
Brake voltage range
Reverse rotation control
voltage range
0.7
1.7
ዉ
C_VFWD
C_VBRK
1.3
2.3
1.5
ዉ
C_VREV
<CAPSTAN TORQUE CONTROL>
EC input bias current
C_IEC
C_GIO
C.EC=VCC
ዉ
3
7.5
ꢁA
A/V
V
ዉ
Torque control input/output gain
Torque control start voltage
Current limit voltage
C_RNF=0.33Q,C_RCC=3.3kQ
0.42
1.05
0.25
0.6
1.2
0.33
0.78
1.35
0.41
Fig.30
Fig.30
Fig.30
C_VECOFS
C_Climit
C_RNF=0.33Q,C_RCC=3.3kQ
V
IOUT=100mA,C_RCC=3.3kQ
C_RNF=0.33Q
Ripple cancel ratio
C_VRCC
C_GVS
22
45
68
%
ዉ
<CAPSTAN VS>
Voltage gain
ዉ
TIMES
7
8
9
IOVS=1mA,
between VCC and output
V
V
Output H voltage
Output L voltage
C_VVSOH
C_VVSOL
ዉ
ዉ
0.5
0.8
0.2
ዉ
ዉ
IOVS=50ꢁA
0.13
<CAPSTAN FGAMP>
In-phase input voltage range
C_VFGCM
C_IFG
ዉ
0.35
ዉ
ዉ
ዉ
VCC-1.1
1
V
ꢁA
V
Input bias current
Output H voltage
Output L voltage
ዉ
ዉ
C_VFGSOH
C_VFGSOL
2.8
ዉ
ዉ
ዉ
0.1
0.3
V
IOL=1mA
Fig.44
<CYLINDER OUTPUT>
Output H voltage
D_VOH
D_VOL
IOUT=-400mA
IOUT=100mA,C_RNF=0.33Q
ዉ
ዉ
0.3
0.28
0.48
0.4
V
V
Fig.34
Fig.35
Output L voltage
<CYLINDER OUTPUT>
D_PS
ዉ
0.7
1.4
2
V
D_PSꢀinput threshold levelꢀ
<CYLINDER TORQUE CONTROL>
EC input bias current
D_IEC
D_GIO
ዉ
ዉ
2
5
ꢁA
A/V
V
D_EC=VCC
Torque control input/output gain
Torque control start voltage
Current limit voltage
0.45
1.05
0.217
0.66
1.2
0.87
1.35
0.332
D_RNF=0.33Q
Fig.33
Fig.33
Fig.33
D_VECOFS
D_Climit
0.274
V
D_RNF=0.33Q
<CYLINDER STARTING/DETECTION>
DETECT terminal charge current
D_IDETO
D_IDETI
2
5
5
10
10
ꢁA
ꢁA
V
Fig.36
Fig.36
Fig.37
Fig.37
DETECT terminal discharge current
DETECT terminal H voltage
DETECT terminal L voltage
2
D_VDETH
D_VDETL
1.1
0.5
1.3
0.65
1.5
0.8
V
5/16
BD6300KU ELECTRICAL CHARACTERISTICS (Unless otherwise specified Ta=25@,VCC=3V, C_VMዙD_VMዙL_VM=5VወUNREG=7.2V)
Limit
Typ.
Symbol
Unit
Conditions
Parameter
Fig No.
Min.
Max.
<CYLINDER SLOPE>
ISET voltage
D_VISET
D_ISLO
D_ISLI
0.4
22
24
2.8
1
V
RD_ISET=18kꢀ
0.32
16
0.48
28
Fig.38
Fig.39
Fig.39
Fig.40
Fig.40
SL1,2 charge current
SL1,2 discharge current
SL1,2 H voltage
ꢁA
ꢁA
V
RD_ISET=18kꢀ
RD_ISET=18kꢀ
17
31
D_VSLH
D_VSLL
2.5
ዉ
SL1,2 L voltage
0.85
V
1.15
SL1,2 charge and discharge
current ratio
< CYLINDER VS>
Voltage gain
D_RSL
D_GVS
0.82
0.89
0.96
ዉ
TIME
7
8
9
ዉ
ዉ
ዉ
IOVS=-1mA,
between VCC and output
Output H voltage
Output L voltage
D_VVSOH
ዉ
ዉ
0.5
0.8
0.2
V
V
D_VVSOL
0.13
IOVS=50A
<CYLINDER FGAMP/SMT>
DC bias voltage
V
1.3
0.35
1.5
ዉ
1.7
VCC-1.1
1
ዉ
ዉ
D_VFG+
D_VFGCM
In-phase input voltage range
DC bias current
V
ꢁA
D_IFG
ዉ
2.8
ዉ
ዉ
ዉ
Output H voltage
D_VFGSO
D_VFGSO
ዉ
ዉ
V
V
ዉ
Output L voltage
0.1
0.3
IOL=1mA
Fig.45
<CYLINDER PGAMP>
DC bias voltage
D_VPG+
D_VPGC
D_VPGSO
D_VPGSO
1.3
0.35
2.8
ዉ
1.5
ዉ
1.7
VCC-1.1
ዉ
V
V
V
V
ዉ
ዉ
In-phase input voltage range
Output H voltage
ዉ
ዉ
Output L voltage
0.14
0.3
Fig.46
<LOADING>
IOUT=200mA,L_REF=L_VM
Total saturation voltage of low and
high side output transistor
Fig.
Output saturation voltage
L_VSAT
ዉ
0.3
0.5
V
41,42
L_REF pin input current
Vout-L_REF offset
L_IIREF
0.3
2
ꢁA
L_REF=L_VM
ዉ
ዉ
ዉ
L_VOFS
100
200
mV
Fig.43
Forward rotation control
voltage range
Brake voltage range
Reverse rotation control
voltage range
L_REF output open voltage
L_VFWD
ዉ
ዉ
0.7
1.7
ዉ
V
ዉ
L_VBRK
L_VREV
L_VREF
1.3
2.3
ዉ
1.5
ዉ
V
V
V
ዉ
ዉ
ዉ
ዉ
1.3
<REEL AMP>
R_IIN
ዉ
-8
ዉ
1
8
ꢁA
mV
V
ዉ
ዉ
Input bias current
R_VOFS
R_VINCM
R_VSOL
Input offset voltage
In-phase input voltage range
ዉ
ዉ
0.35
ዉ
VCC-1.1
ዉ
Output L voltage
0.1
V
IOL=1mA
Fig.47
6/16
ʀReference data
BD6637KV/KS Characteristic data
BD6637KV/KS
BD6637KV/KS
BD6637KV/KS
100
90
80
70
60
50
40
30
20
10
0
20
100
90
80
70
60
50
40
30
20
10
0
75℃
18
25℃
16
14
12
-25℃
10
8
6
-25℃,25℃,75℃
4
-25℃,25℃,75℃
2
0
Operating Voltage Range
Operating Voltage Range
2.0
3.0
4.0
5.0
0
3
6
᎕᎙ᎌᎎ፯፰
9
12
2.0
2.5
3.0
3.5
VCC(V)
4.0
4.5
5.0
VCC(V)
Fig.1 VCC Circuit current 1ꢀ
Fig.2 VCC Circuit current 2
Fig.3 UNREG stand by current
0.0
BD6637KV/KS
BD6637KV/KS
BD6637KV/KS
16
14
12
10
8
16
14
12
10
8
-0.2
-0.4
75℃
UNREG=12V
25℃
-25℃
-0.6
-0.8
-1.0
-1.2
UNREG=7.2V
UNREG=5V
-25℃
6
6
25℃
75℃
4
4
2
2
0
0.0
0.2
0.4
0.6
0.8
1.0
0
IOUT(A)
0.0
2.0
4.0
6.0
0.0
2.0
4.0
6.0
IVG(mA)
IVG(mA)
Fig.4 VG voltage
Fig.5 VG voltage
Fig.6 CAPSTAN Output High-voltage
ዄTemperature characteristicsዅ
ዄVoltage characteristicsዅ
BD6637KV/KS
BD6637KV/KS
BD6637KV/KS
1.4
0.0
300
250
200
150
100
50
-25℃
1.2
-0.2
75℃
25℃
75℃
1.0
-0.4
-25℃
0.8
25℃
-0.6
0.6
-25℃
25℃ 75℃
-0.8
0.4
0.2
0.0
-1.0
-1.2
0
0.0
1.0
2.0
3.0
0.0
0.2
0.4
IOUT(A)
0.6
0.8
1.0
0.0
0.2
0.4
IOUT(A)
0.6
0.8
1.0
C.EC(V)
Fig.8 CAPSTAN Torque control
input/output gain
Fig.7 CAPSTAN Output High-voltage
Fig.9 CYLINDER Output
High-voltage
BD6637KV/KS
BD6637KV/KS
BD6637KV/KS
1.4
8.0
300
-25℃
25℃
6.0
25℃
75℃
1.2
75℃
250
75℃
4.0
1.0
discharge
-25℃
200
150
100
50
2.0
25℃
0.8
0.0
-25℃
2.0
2.5
3.0
3.5
4.0
4.5
5.0
0.6
-2.0
-4.0
-6.0
-8.0
-10.0
0.4
0.2
0.0
charge
-25℃,25℃,75℃
Operating Voltage Range
0
0.0
1.0
2.0
3.0
0.0
0.2
0.4
IOUT(A)
0.6
0.8
1.0
VCC(V)
D.EC(mV)
Fig.10 CYLINDER
Output Low-voltage
Fig.11 CYLINDER Torque control
input/output gain
Fig.12 DETECT terminal
charge/discharge current
7/16
BD6637KV/KS Characteristic data
BD6637KV/KS
BD6637KV/KS
BD6637KV/KS
discharge
1.6
0.43
0.42
0.41
0.40
0.39
0.38
0.37
40.0
30.0
20.0
10.0
0.0
1.4
H voltage
75℃
1.2
25℃
-25℃
75℃
25℃
1.0
-25℃,25℃,75℃
0.8
L voltage
0.6
0.4
0.2
0.0
-10.0
-20.0
-30.0
-40.0
-25℃
-25℃
25℃
charge
Operating Voltage Range
Operating Voltage Range
Operating Voltage Range
75℃
2.5
2.0
2.5
3.0
3.5
4.0
4.5
5.0
2.0
3.0
3.5
4.0
4.5
5.0
2.0
2.5
3.0
3.5
4.0
4.5
5.0
VCC(V)
VCC(V)
VCC(V)
Fig.13 DETECT terminal
H/L voltage
Fig.14 ISET voltage
Fig.15 SL1,2 charge/discharge
current
BD6637KV/KS
BD6637KV/KS
BD6637KV/KS
9.0
8.0
7.0
6.0
5.0
4.0
3.0
2.0
1.0
0.0
0.6
0.0
-0.2
-0.4
-0.6
-0.8
-1.0
-1.2
-1.4
Operating Voltage Range
75℃
0.5
0.4
25℃
-25℃,25℃,75℃
H Voltage
L Voltage
0.3
-25℃
25℃
-25℃
0.2
0.1
0.0
75℃
-25℃,25℃,75℃
2.0
2.5
3.0
3.5
VCC(V)
4.0
4.5
5.0
0.0
0.2
0.4
0.6
0.8
1.0
0.0
0.2
0.4
0.6
0.8
1.0
L_IFWD(A)
L_IFWD(A)
Fig.16 SL1,2 H/L voltage
Fig.17 LOADING Output
High-voltage
Fig.18 LOADING Output
Low-voltage
BD6637KV/KS
BD6637KV/KS
BD6637KV/KS
1.4
1.2
1.0
0.8
0.6
0.4
0.2
0.0
0
80.0
70.0
60.0
50.0
40.0
30.0
20.0
10.0
0.0
ꢀ
-50
-100
-150
-200
-250
-300
-350
-400
-25℃
-25℃
75℃
25℃
-25℃,25℃,75℃
75℃
25℃
0.0
0.5
1.0
1.5
2.0
2.5
3.0
0
1
2
3
4
5
10
1000
100000
10000000
C_IF/D_IF/D_IP GSMT(mA)
L_REF (V)
Frequency (Hz)
Fig.21 C_FG/D_FG/D_PG
Output Low-voltage
Fig.19 Vout-L_REF offset
Fig.20 C_FG/D_FG/D_PG Voltage
gain
BD6637KV/KS
BD6637KV/KS
BD6637KV/KS
5.0
5.0
5.0
4.5
4.0
3.5
3.0
2.5
2.0
1.5
1.0
0.5
0.0
4.5
4.5
-25℃,25℃,75℃
-25℃,25℃,75℃
-25℃,25℃,75℃
4.0
4.0
3.5
3.0
2.5
2.0
1.5
1.0
0.5
0.0
3.5
3.0
2.5
2.0
1.5
1.0
0.5
0.0
-200
-100
0
100
200
-200
-100
0
100
200
-200
-100
0
100
200
D_PGAMP-D_FGPGINP (mV)
D_FGAMP-D_FGPGINP (mV)
C_FGAMP-C_FGINP (mV)
Fig.22 C_FG hysteresis width
Fig.23 D_PG hysteresis width
Fig.24 D_FG hysteresis width
8/16
ʀReference data
BD6300KU Characteristic data
BD6300KU
75℃
BD6300KU
BD6300KU
16
7
6
5
4
3
2
1
0
100
90
80
70
60
50
40
30
20
10
0
75℃
25℃
14
25℃
12
10
-25℃
-25℃
8
6
4
-25℃,25℃,75℃
2
0
Operating Voltage Range
Operating Voltage Range
2.0
3.0
4.0
5.0
0
3
6
᎕᎙ᎌᎎ፯፰
9
12
2.0
2.5
3.0
3.5
VCC(V)
4.0
4.5
5.0
VCC(V)
Fig.25 VCC Circuit current 1
Fig.26 VCC Circuit current 2
Fig.27 UNREG stand by current
BD6300KU
450
BD6300KU
BD6300KU
16
14
12
10
8
16
14
12
10
8
75℃
400
25℃
75℃
350
-25℃
UNREG=12
UNREG=7.2
UNREG=5V
300
25℃
250
200
150
100
50
-25℃
6
6
4
4
2
2
0
0
0
0.0
1.0
2.0
3.0
0.0
1.0
2.0
3.0
IVG(mA)
4.0
5.0
6.0
0.0
1.0
2.0
3.0
IVG(mA)
4.0
5.0
6.0
C_EC(V)
Fig.28 VG voltage
Fig.29 VG voltage
Fig.30 CAPSTAN
ꢀ Torque control input/output gain
ዄTemperature characteristicsዅ
ዄVoltage characteristicsዅꢀ
BD6300KU
BD6300KU
BD6300KU
ꢀ
0.0
1.2
1.0
0.8
0.6
0.4
0.2
0.0
300
75℃
-25℃
25℃
-0.1
250
-0.2
200
-25℃
75℃
25℃
-0.3
150
100
50
25℃
-25℃
75℃
-0.4
-0.5
-0.6
0
0.0
1.0
2.0
3.0
0.0
0.2
0.4
IOUT(A)
0.6
0.8
0.0
0.2
0.4
IOUT(A)
0.6
0.8
D_EC(V)
Fig.33 CYLINDER Torque control
input/output gain
Fig.31 CAPSTAN Output
High-voltage
Fig.32 CAPSTAN Output
Low-voltage
BD6300KU
BD6300KU
BD6300KU
0.0
1.2
1.0
0.8
0.6
0.4
0.2
0.0
8.0
25℃
6.0
-0.1
-0.2
-0.3
-0.4
-0.5
-0.6
-0.7
75℃
25℃
75℃
4.0
discharge
-25℃
2.0
0.0
-25℃
2.0
2.5
3.0
3.5
4.0
4.5
5.0
-25℃
-2.0
-4.0
-6.0
-8.0
-10.0
25℃
charge
-25℃,25℃,75@
75℃
0.6
Operating Voltage Range
VCC(V)
0.0
0.2
0.4
0.8
0.0
0.2
0.4
IOUT(A)
0.6
0.8
IOUT(A)
Fig.34 CYLINDER Output
High-voltage
ꢀ ꢀ ꢀ
Fig.35 CYLINDER Output
Low-voltage
ꢀ ꢀ ꢀ
Fig.36 DETECT terminal
charge/discharge current
9/16
BD6300KU Characteristic data
BD6300KU
BD6300KU
BD6300KU
discharge
1.6
1.4
1.2
1.0
0.8
0.6
0.4
0.2
0.0
0.43
0.42
0.41
0.40
0.39
0.38
0.37
40.0
30.0
20.0
10.0
0.0
H Voltage
75℃
25℃
75℃
25℃
-25℃
-25℃,25℃,75℃
L Voltage
-25℃
-10.0
-20.0
-30.0
-40.0
-25℃
25℃
charge
Operating Voltage Range
Operating Voltage Range
Operating Voltage Range
75℃
2.5
2.0
2.5
3.0
3.5
4.0
4.5
5.0
2.0
2.5
3.0
3.5
4.0
4.5
5.0
2.0
3.0
3.5
4.0
4.5
5.0
VCC(V)
VCC(V)
VCC(V)
Fig.37 DETECT terminal H/L voltage
Fig.39 SL1,2 charge/discharge
current
Fig.38 ISET voltage
BD6300KU
9.0
BD6300KU
BD6300KU
0.0
-0.2
-0.4
-0.6
-0.8
-1.0
-1.2
-1.4
0.6
Operating Voltage Range
8.0
75℃
25℃
7.0
6.0
0.5
0.4
0.3
0.2
0.1
0.0
-25℃,25℃,75℃
H Voltage
5.0
4.0
3.0
2.0
1.0
0.0
-25℃
-25℃
25℃
L Voltage
-25℃,25℃,75℃
75℃
2.0
2.5
3.0
3.5
VCC(V)
4.0
4.5
5.0
0.0
0.2
0.4
0.6
0.8
1.0
0.0
0.2
0.4
0.6
0.8
1.0
1.2
L_FWD(A)
L_FWD(A)
Fig.40 SL1,2 H/L voltage
Fig.41 LOADING Output High-voltage
ꢀ ꢀ ꢀ ꢀ
Fig.42 LOADING Output
Low-voltage
BD6300KU
BD6300KU
BD6300KU
3.0
3.0
ꢀ ꢀ ꢀ ꢀ ꢀ
0
-50
-100
-150
-200
-250
-300
-350
-400
-25℃
75℃
2.5
2.5
2.0
1.5
1.0
0.5
25℃
2.0
-25℃
-25℃
1.5
25℃
25℃
1.0
0.5
75℃
75℃
0.0
0.0
0.0
0.0
3.0
6.0
9.0
12.0
15.0
3.0
6.0
9.0
12.0
15.0
0
1
2
3
4
5
C_FGINM (mA)
D_FGINM (mA)
L_REF (V)
Fig.44 C_FGSMT Output
Low-voltage
Fig.45 D_FGSMT Output
Low-voltage
Fig.43 Vout-L_REF offset
BD6300KU
BD6300KU
3.0
2.5
2.0
1.5
1.0
0.5
0.0
3.0
2.5
2.0
1.5
1.0
0.5
0.0
-25℃
-25℃
25℃
75℃
25℃
75℃
0.0
3.0
6.0
9.0
12.0
15.0
0.0
3.0
6.0
9.0
12.0
15.0
D_PGINM (mA)
R_IOL1/2 (mA)
Fig.46 D_PGSMT Output L voltage
Fig.47 R_OUT1/2 Output L voltage
10/16
ʀBlock diagram
BD6637KV/KS
ꢀ ꢀ ꢀ ꢀ ꢀ
Terminal function table
PIN Name
PIN Name
(KS)
PIN Name
(KV)
PIN Name
(KS)
PIN NO.
PIN NO.
(KV)
L_VM
L_FBR
D_DETECT
VG
D_ISET D_SL1 D_SL2
1
N.C.
C_U
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
D_COM
D_W
D_VM
D_U
2
C_U
C_V
D_U
L_FBR
L_REF
L_FWD
L_GND
L_REV
L_VM
L_REF
Starting
3
C_V
C_RNF
C_W
D_V
L_FWD
Oscilator
detection
D_V
circuit
4
C_RNF
C_W
D_RNF
D_W
DC/DC
D_W
5
C_HU+
C_HU-
L_REV
Driver
FGHys.Amp.
FG Amp.
L_GND
6
N.C.
N.C.
D_RNF
D_FGIN-
PG Hys. Amp.
7
N.C.
C_HV+
C_HV-
L_FBR
L_REF
L_FWD
N_C
D_FGPGIN+
PG Amp.
8
C_HU+
C_HU-
C_HV+
C_HV-
C_HW+
C_HW-
D_PGSMT
D_PGAMP
D_PGIN-
D_FGPGIN+
D_FGIN-
D_FGAMP
D_FGSMT
VCC
C_FGIN+
C_FGIN-
C_FGAMP
C_FGSMT
VG
D_FGAMP
D_FGSMT
9
C_HW+
C_HW-
D_PGSMT
D_PGAMP
D_PGIN-
D_FGPGIN+
D_FGIN-
D_FGAMP
D_FGSMT
VCC
ȵϕ༫˂
Amp.
FG Hys.
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
D_PGIN-
D_PGAMP
L_GND
L_REV
L_VM
C_FGIN+
C_FGIN-
C_FGAMP
C_FGSMT
N.C.
D_PGSMT
D_PCV
D_COM
D_PCI
CP1
Current feed back Amp.
CP2
D_EC
Error Amp.
Torque control Amp.
GND
D_VS
GDX
GDX
D_VM
VREG
CP1
CP2
UNREG
GND
Booster
Circuit
PS
VCC
C_RCC
C_FBR
C_VM
C_VS
VG
C_VM
VG
Rotary
course
D_DETECT
D_ISET
D_SL1
VG
C_FBR
brake
C_U
HALL
CP1
C_HU+
C_HU-
Hall Amp.
CP2
DC/DC
C_V
HALL
HALL
C_HV+
C_HV-
D_DETECT
D_ISET
D_SL1
D_SL2
UNREG
N.C.
D_SL2
N.C.
C_EC
UNREG
D_VM
GND
C_PCI
C_PCV
C_W
C_HW+
C_HW-
C_RNF
GDX
Torque ripple
D_VS
PS
C_RCC
C_EC
cancel
Current feed back Amp.
D_EC
C_RCC
C_FBR
C_VM
C_VS
C_EC
C_PCI
C_PCV
Low side
C_PCV
C_PCI
ȵ
sat.prevention
D_PCI
Circuit
Torque control Amp.
FGHys. Amp.
C_FGIN-
C_FGIN+
Error Amp.
D_VM
D_PCV
D_COM
D_U
C_VS
Thermal
Power
D_VS
100k
FG Amp.
C_FGAMP
Q
Save
shut down
C_VM
D_EC
C_FGSMT
D_PCI
D_V
P.S.
D_PCV
D_RNF
ꢀ BD6300KUꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ
Terminal function table
PIN NO.
PIN Name
PIN NO.
PIN Name
R_IN+2
L_VM
L_FBR
D_DETECT
1
D_PH
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
VG
D_ISET D_SL1 D_SL2
D_VM
D_U
2
D_FGIN-
D_FGPGIN+
D_PGIN-
D_FGSMT
VCC
R_IN-2
R_OUT2
VG
L_REF
3
Starting
L_FWD
Oscilator
detection
D_V
4
circuit
DC/DC
5
CP2
D_W
L_REV
Driver
FGHys.Amp.
FG Amp.
6
CP1
L_GND
D_RNF
D_FGIN-
PG Hys. Amp.
7
D_DETECT
D_ISET
D_SL1
D_SL2
UNREG
D_VM
GND
D_FGPGIN+
PG Amp.
8
GDX
9
D_PS
C_PS
C_FBR
C_VM
C_VS
C_EC
C_PCI
C_PCV
FGND1
C_U
D_FGAMP
D_FGSMT
Amp.
FG Hys.
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
D_PGIN-
D_PGAMP
D_PGSMT
D_PCV
D_COM
D_VS
D_PCI
D_EC
Current feed back Amp.
D_EC
Error Amp.
Torque control Amp.
D_PCI
D_PCV
D_COM
D_U
D_VS
GDX
D_VM
VREG
CP1
CP2
UNREG
GND
Booster
Circuit
VCC
VG
C_VM
VG
Rotary
D_V
C_V
course
C_FBR
brake
D_RNF
D_W
C_RNF
C_W
C_U
C_V
HALL
C_HU+
C_HU-
Hall Amp.
DC/DC
HALL
HALL
N.C.
C_RCC
C_HV-
C_HV+
C_HU-
C_HU+
C_HW+
C_HW-
C_HV+
C_HV-
FGND2
L_FBR
L_REF
L_FWD
L_GND
L_REV
L_VM
C_W
C_HW+
C_HW-
C_RNF
Torque ripple
cancel
C_RCC
C_EC
Current feed back Amp.
Low side
C_PCV
C_PCI
sat.prevention
Circuit
Torque control Amp.
FGHys. Amp.
C_FGIN-
C_FGIN+
Error Amp.
C_VS
Thermal
Power
C_FGIN+
C_FGIN-
100k
FG Amp.
C_FGAMP
Q
Save
shut down
C_VM
R_IN+1
R_IN-1
R_OUT1
C_FGSMT
D_PGSMT
C_FGSMT
P.S.
11/16
ʀDescription of operations
ꢀ
Description of capstan operation
1. Hall input - output
The Hall sensor input signal of the three-phase, is amplified by the Hall amplifier to produce a drive signal
waveform. This drive signal is amplified, once again, by the output amplifier to supply a drive current for the motor
coil. Output current is a trapezoidal waveform. Due to the trapezoidal waveform, gaps are generated in the
magnetic field by the three-phase coil, which causes a slight irregularity of rotation. In operation, the triangle wave
is superimposed upon the trapezoidal output waveform. (Torque ripple cancellation)
2. Torque control
Output current can be controlled by the voltage applied to C.EC (torque control terminal).
Internal reference voltage
C. RNF voltage
፧ ፧ ፧ ፧ ፧ ፧ ፧ ፧ ፧ ፧ ፧ ፧ ፧
፧ ፧ ፧ ፧ ፧ ፧ ፧
፧
Torque command
start voltage፧
1.05ᰆᰮ1.35ᰆ
1.2V
C. EC voltage
3. Brake
When the C.FBR terminal is set to M, each output voltage becomes low and the brake is applied.
Brake command voltage: C.FBR 1.3V to 1.7V
4. Motor power supply control function
In order to use power effectively (as well as to prevent exceeding permissible dissipation of IC), it is required to
change supply voltage according to output current, i.e. to reduce supply voltage when current output is low, and
increase when current output is high, thereby preventing extra voltage from being applied between Drain and
Source of output stage MOS. Power supply control function (VS terminal) is installed for this purpose. In this
function, the voltage between Drain and Source of upper MOS of output stage is detected, and output to VS
terminal as a power supply control signal. This gain signal is multiplied several times by DC/DC, for controlling
motor power supply.
5. Output TR saturation preventing circuit
This circuit is used to operate output MOS in linear region. It has good dynamic range from a low to high current,
and provides a good rotating performance under overload, etc.
ꢀ
Description of cylinder operation
1. Back electromotive force detecting comparator (BEMF)
Compares the output voltage of the motor with the midpoint potential BEMF and detects the position of the rotor
and stator (magnet and coil). Further, the BEMF is provided with hysteresis, which can be set by resistor RD.com,
connected to D.COM terminal.
2. Phase switching logic
Synthesizes the output from three-phase BEMF force detecting comparator. The noise pulse of BEMF by the motor
is eliminated by MASK signal, generated by D.SL terminal 1 and 2 with reference to each position-detected signal.
Only the rising edge of masked synthetic output is used as a signal for the secondary counter. While output from
secondary and drive signal is synthesized, FG signal is generated every 60 degrees (electric angle).
3. Slope
D.SL terminal 1 and 2 are charged and discharged in synchronization with the timing of the internal FG signal. For
driving soft switching, slope is applied to output current waveform by the slope rate of D.SL terminal 1 and 2.
MASK signal is generated by charging and discharging waveform of D.SL terminal 1 and 2. MASK signal L is
output only when the charging and discharging waveform of D.SL terminal 1 and 2 is clamped at L level, when
MASK is canceled. Otherwise, H is output and MASK is applied, and noise pulse by back electromotive force of
motor is removed.
4. Detection circuit - start signal synthesizing
When a capacitor is connected to D.DETECT terminal, charging and discharging are performed. When the motor is
stopped, D.DETECT terminal repeats charging and discharging between Low-level and High-level. Only the rising
edge of square wave (SEL) that is synchronized with D.DETECT terminal, is compared with rising edge of
synthesized output of BEMF detecting comparator. When the motor is stopped, BEMF detecting comparator is not
output. Therefore, the edge of SEL signal is input to secondary counter and attempts to force the motor to rotate
(synchronized mode). Before the motor rotates and D.DETECT terminal reaches High-level, BEMF detecting
comparator detects BEMF motor. When synthetic output of BEMF detection comparator is output, D.DETECT
terminal starts discharging on the corresponding edge. When Low-level is reached, charging is started again, and
discharging is started on the edge of BEMF detecting comparator output. Here the edge of synthetic output of
BEMF comparator is input to secondary counter, and the motor rotates. (BEMF mode)
12/16
5. Torque control
Output current can be controlled by the voltage applied to D.EC (torque control terminal), as with capstan
assembly.
6. Motor power supply control function
In order to use power effectively (as well as to prevent exceeding permissible dissipation of IC), it is required to
control supply voltage according to output current. For example, reduce supply voltage when current output is low,
and increase when current output is high, thereby preventing extra voltage from being applied between Drain and
Source of output stage MOS. Power supply control function (VS terminal) is used for this purpose. In this function,
the voltage between Drain and Source of upper MOS of output stage is detected, and sent to VS terminal as a
power supply control signal. This gain signal is multiplied several times by DC/DC, for controlling motor power
supply.
7. Output TR saturation preventing circuit
This circuit is used to operate output MOS in linear region. It has good dynamic range from a low to high current,
and provides a good rotating performance under overload, etc.
ꢀ
Description of loading assembly operation
1. L.FBR input - output
Output (L.REV and L.FWD) is three-mode output for forward/reverse rotation and braking, depending on the
voltage input to L.FBR.
2. Loading assembly output H voltage control
Output High-voltage of loading assembly can be set by the voltage input to L.RFF terminal.
Output High-voltage VOH can be represented by the formula below:
L.REF voltage where the formula above holds true is 1.7 V - L. VM voltage.ꢀ
Output H voltage
ꢀ
ꢀꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ
ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ
L L. REF voltage
L.VM
፸፵፧
Output H voltage setting range
ʀApplication part selecting procedure
Selection of constant in the example of recommended circuit is shown below:
1) Capstan hall bias resistor (RH1 and RH2)ꢀ
The amplitude and bias point of hall element can be set by hall bias resistor. Hall amplitude varies with hall element
in use even when the same bias resistor is used, therefore adjust the bias resistor so that the amplitude of hall
element is 50 - 100mvp-p as well as within the range of hall amplifier in-phase input voltage range of capstan
assembly (1.2 - VCC-1.1V).
Vcc
Upper limit of hall input voltage range (VCC-1.1V)
Amplitude of hall element
Lower limit of hall input voltage range (1.2V)
GND
2) Capstan C.RCC resistor
Canceling rate of torque ripple canceling circuit of capstan assembly can be adjusted by the resistor equipped
externally on C.RCC terminal. Select the optimum value, considering the vibrations, when the IC is mounted to the
motor. The optimum value depends on the motor, while 2k ꢁ to 4k ꢁ is recommended.
3) Cylinder D.COM terminal connection terminal
By inserting a resistor in the middle point of D.COM terminal and motor, the BEMF detecting comparator can also
generate hysteresis, thereby preventing any noise from causing malfunction. Hysteresis width can be calculated as
follows:
Hysteresis width = R.D.COM x 20 ) A (Typ. value)
The optimum value depends on the motor, while 200 ꢁ to 300ꢁ is recommended.
13/16
4) Cylinder and output current slope setting capacitor (CSL1, CSL2)
Triangle wave is output from D.SL terminal 1 and 2 for normal rotation of the cylinder. Level 1 is output for Low-
level of the triangle wave. The level determined by cylinder rotating speed is output for High-level. Adjust the
capacitor of terminal D.SL1 and D.SL2 and the resistance of ISET terminal so that this High-level is approximately
1.8V. It can be set as follows:
Example: When normal rotation speed of cylinder is 9000 rpm, capacitor of terminal D.SL1 and D.SL2 0.047ꢂF and
resistance 18 k ꢁ are recommended.
ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ
185ꢂs4ISL
ISET terminal voltageዄTyp.:0.4Vዅ
CSL1,CSL2
(ꢂF)
ꢀ ꢀ
(where ISLዙ
ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ
ዅ
ዙ
ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ
0.8V
RISET
ꢀ
ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ
5) Setting of drive signal frequency in cylinder startup
Drive signal frequency in cylinder startup can be controlled by changing the capacitor of D.DETECT terminal.
Adjust the optimum value, so that starting time is shortest on your motor. Drive signal frequency during startup
can be calculated as follows: Optimum value depends on motor, while 0.1 - 0.2 ꢂ F is recommended.
ꢀ
DETECT terminal charging and discharging current
(Hz)
ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ ꢀ
(DETECT terminal H voltage ዉ DETECT terminal L voltage)4 CDETECT 4 6
DETECT terminal H voltage
DETECT terminal L
: 1.3V (Typ. value)
: 0.65V (Typ. value)
DETECT terminal charging and discharging current : 5ꢂA (Typ. value)
6) PCI/PCV terminal connecting capacitor (capstan/cylinder)
Capacitor connected to PCI and PCV terminal is used to compensate the phase of upper and lower saturation
prevention circuit and current feedback loop. When it is too large, the entire loop (including servo system), becomes
unstable. When it is too small, the output waveform oscillates. Recommended are 100pF for PCI terminal, 0.1 ꢂ F
for PCV terminal of cylinder, 0.1 ꢂ F for PCI terminal and 0.1 ꢂ F for PCV terminal of capstan.
7) DC/DC (capstan/cylinder)
When the output of VS terminal of capstan/cylinder is connected to the DC/DC converter, the motor voltage can be
controlled according to the output voltage waveform of the motor. When the DC/DC converter gain is low, the
maximum VM voltage cannot be output. The output current waveform is distorted, therefore adjust to an optimum
value.
8) RNF terminal
Connect a small resistor (0.33 ꢁ to 0.5 ꢁ) between RNF terminal and GND for detecting output current. Because
High current flows in this resistor, take precautious against high resistor wattage. The value of the torque command
gain versus this resistor (0.33 ꢁ), is described in the electrical characteristics. Note that this value also changes
when resistance changes.
9) Voltage rising circuit
This IC applies Nch DMOS on output stage, and incorporates a voltage boost current for the corresponding gate
voltage. When the capacitance value between CP1 terminal and CP2 terminal is low, the current capability of VG
terminal voltage is low. When the capacitance value between VG terminal and GND terminal is low, the ripple of
VG voltage becomes high. Recommended capacitance value between terminal CP1 and CP2 is 0.1 to 0.22 ꢂ F
and that between terminal VG and GND is 1 to 10 ꢂ F.
ʀThermal derating characteristics
BD6637KV/KS
BD6300KU
፧
᎗Ꭻ
፹፵፷
᎗Ꭻ
፹፵፷
፸፵፼
፸፵፼
፸፵፼
፸፵፹፼
፸፵፷
፸፵፷
፷፵፼
፷፵፼
፷
፹፼
፼፷
፼
፸፷፷
፸፹፼
፸፼፷
Ꭸᚴ
፷
፹፼
፼፷
፼፧
፸፷፷፧
፸፹፼፧
፸፼፷
Ꭸᚴ
* 70 mm x 70 mm x 1.6 mm glass epoxy board mounted
Reduce by 10m W/°C when Ta = 25 °C
* 70 mm x 70 mm x 1.6 mm glass epoxy board mounted
Reduce by 14m W/°C when Ta = 25 °C
14/16
ʀOperation Notes
1) Absolute maximum ratings
An excess in the absolute maximum ratings, such as supply voltage, temperature range of operating conditions, etc., can break
down the devices, thus making impossible to identify breaking mode, such as a short circuit or an open circuit. If any over rated
values will expect to exceed the absolute maximum ratings, consider adding circuit protection devices, such as fuses.
2) Power supply lines
Design PCB layout pattern to provide low impedance GND and supply lines. To obtain a low noise ground and
supply line, separate the ground section and supply lines of the digital and analog blocks. Furthermore, for all power
supply terminals to ICs, connect a capacitor between the power supply and the GND terminal. When applying
electrolytic capacitors in the circuit, note that capacitance characteristic values are reduced at low temperatures.
3) 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 less than or equal to the GND pin, including during actual transient phenomena. The voltage of the motor
output pin may, however, drop below the GND potential due to the BEMF voltage of the motor. Malfunctions or other
failures may result, depending on the operating conditions, environment, and individual characteristics of the motor.
Check that the IC has no operational problems.
4) Thermal Design
Use a proper thermal design that allows for a sufficient margin of the power dissipation (Pd) at actual operating conditions.
5) Pin short and mistake fitting
Use caution when positioning the IC for mounting on printed circuit boards. The IC may be damaged if there is any
connection error or if positive and ground power supply terminals are reversed. The IC may also be damaged if pins are
shorted together or are shorted to other circuit’s power lines.
6) Operation in a strong electromagnetic field
Use caution when using the IC in the presence of a strong magnetic field, as doing so may cause the IC to malfunction.
7) ASO
When using the IC, set the output transistor so that it does not exceed absolute maximum ratings or ASO.
8) Thermal shutdown circuit
If the junction temperature (Tj) reaches 175°C (Typ.), the TSD circuit will operate, and the coil output circuit of the motor
will open. There is a temperature hysteresis of approximately 25°C (Typ.). The TSD circuit is designed only to shut off the
IC in order to prevent runaway thermal operation. It is not designed to protect the IC or guarantee its operation. The
performance of the IC’s characteristics is not guaranteed and it is recommended that the device is replaced after the TSD
is activated.
9) 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. Always turn the IC's power supply off before connecting it to, or
removing it from a jig or fixture, during the inspection process. Ground the IC during assembly steps as an antistatic
measure. Use similar precaution when transporting and storing the IC.
10) Ground wiring patterns
If small-signal GND and large-current GND are provided, It will be recommended to separate the large-current GND pattern
from the small-signal GND pattern and establish a single ground at the reference point of the set PCB so that resistance to the
wiring pattern and voltage fluctuations due to a large current will cause no fluctuations in voltages of the small-signal GND. Pay
attention not to cause fluctuations in the GND wiring pattern of external parts as well.
11) Capacitors connected between output and ground pins
If a large capacitance value is connected between the output and ground pins, and if the VCC falls to 0 V or becomes
shorted with the ground pin, the current stored in the capacitor may flow to the output pin. This can cause damage to the
IC. The capacitance value between the output and GND must be 100ꢂF or lower.
12) Regarding input pin of the IC
If no Vcc voltage is applied to the IC do not apply any voltage to the input pins. If a voltage higher, or as high as the Vcc, or
a voltage lower than, or as low as, the GND is applied, parasitic elements may result due to the structure of the IC. The
operation of parasitic elements can cause interference with circuit operation as well as IC malfunction and damage. Use
caution so that the IC is not used in a manner that will trigger the operation of parasitic elements.
13) Operating Precautions
Although ROHM is confident that the example application circuit reflects the best possible recommendations, be sure to
verify circuit characteristics for your particular application. Modification of constants for other externally connected circuits
may cause variations in both static and transient characteristics for external components as well as this Rohm IC. Allow
for sufficient margins when determining circuit constants.
15/16
●Physical Dimension
VQFP64
SQFP56
UQFP64
〈Dimension〉
〈Dimension〉
〈Dimension〉
12.0 0.2
10.0 0.1
12.4 0.3
10.0 0.2
42 29
9.0 0.2
7.0 0.1
48
33
48
33
49
64
32
17
49
64
32
17
43
56
28
15
0.5 1
16
+0.05
−0.03
1
16
0.145
1.25
14
+0.05
1
0.145
−0.03
0.15 0.1
°+6
−4°
°
+6°
4
4°
−4°
0.4
0.08
S
0.08
0.5 0.1
0.05
+
−0.04
0.65
0.3 0.1
+0.05
0.17
−0.03
0.15
M
0.08
0.2
M
0.08
(Unit:mm)
(Unit:mm)
(Unit:mm)
●Ordering part number
・Please order by ordering part number.・Please confirm the combination of each items.・Please write the letter close to left when column is blank
―
K
B
D
6
6
3
7
V
2
E
Part Number
・BD6637KV
・BD6637KS
・BD6300KU
Package Type
・KV : VQFP64
・KS : SQFP56
・KU : UQFP64
E1 Emboss tape reel Pin 1 on draw-out side
E2 Emboss tape reel Pin 1 opposite draw-out side
<Packing information>
Container
Quantity
Tray(with dry pack)
1000pcs
Direction of product is fixed in a tray.
Direction
of feed
※When you order , please order in times the amount of package quantity.
The contents described herein are correct as of October, 2005
The contents described herein are subject to change without notice. For updates of the latest information, please contact and confirm with ROHM CO.,LTD.
Any part of this application note must not be duplicated or copied without our permission.
Application circuit diagrams and circuit constants contained herein are shown as examples of standard use and operation. Please pay careful attention to the peripheral conditions when designing circuits and deciding
upon circuit constants in the set.
Any data, including, but not limited to application circuit diagrams and information, described herein are intended only as illustrations of such devices and not as the specifications for such devices. ROHM CO.,LTD. disclaims any
warranty that any use of such devices shall be free from infringement of any third party's intellectual property rights or other proprietary rights, and further, assumes no liability of whatsoever nature in the event of any such
infringement, or arising from or connected with or related to the use of such devices.
Upon the sale of any such devices, other than for buyer's right to use such devices itself, resell or otherwise dispose of the same, implied right or license to practice or commercially exploit any intellectual property rights or other
proprietary rights owned or controlled by ROHM CO., LTD. is granted to any such buyer.
The products described herein utilize silicon as the main material.
The products described herein are not designed to be X ray proof.
Published by
Application Engineering Group
Catalog No.05T350Be '05.10 ROHM C 2000 TSU
Appendix
Notes
No technical content pages of this document may be reproduced in any form or transmitted by any
means without prior permission of ROHM CO.,LTD.
The contents described herein are subject to change without notice. The specifications for the
product described in this document are for reference only. Upon actual use, therefore, please request
that specifications to be separately delivered.
Application circuit diagrams and circuit constants contained herein are shown as examples of standard
use and operation. Please pay careful attention to the peripheral conditions when designing circuits
and deciding upon circuit constants in the set.
Any data, including, but not limited to application circuit diagrams information, described herein
are intended only as illustrations of such devices and not as the specifications for such devices. ROHM
CO.,LTD. disclaims any warranty that any use of such devices shall be free from infringement of any
third party's intellectual property rights or other proprietary rights, and further, assumes no liability of
whatsoever nature in the event of any such infringement, or arising from or connected with or related
to the use of such devices.
Upon the sale of any such devices, other than for buyer's right to use such devices itself, resell or
otherwise dispose of the same, no express or implied right or license to practice or commercially
exploit any intellectual property rights or other proprietary rights owned or controlled by
ROHM CO., LTD. is granted to any such buyer.
Products listed in this document are no antiradiation design.
The products listed in this document are designed to be used with ordinary electronic equipment or devices
(such as audio visual equipment, office-automation equipment, communications devices, electrical
appliances and electronic toys).
Should you intend to use these products with equipment or devices which require an extremely high level
of reliability and the malfunction of which would directly endanger human life (such as medical
instruments, transportation equipment, aerospace machinery, nuclear-reactor controllers, fuel controllers
and other safety devices), please be sure to consult with our sales representative in advance.
It is our top priority to supply products with the utmost quality and reliability. However, there is always a chance
of failure due to unexpected factors. Therefore, please take into account the derating characteristics and allow
for sufficient safety features, such as extra margin, anti-flammability, and fail-safe measures when designing in
order to prevent possible accidents that may result in bodily harm or fire caused by component failure. ROHM
cannot be held responsible for any damages arising from the use of the products under conditions out of the
range of the specifications or due to non-compliance with the NOTES specified in this catalog.
Thank you for your accessing to ROHM product informations.
More detail product informations and catalogs are available, please contact your nearest sales office.
THE AMERICAS / EUROPE / ASIA / JAPAN
ROHM Customer Support System
Contact us : webmaster@ rohm.co.jp
www.rohm.com
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Copyright © 2008 ROHM CO.,LTD.
21 Saiin Mizosaki-cho, Ukyo-ku, Kyoto 615-8585, Japan
Appendix1-Rev2.0
相关型号:
BD63130AFM
本产品是能驱动1个DC有刷电机的H桥电机驱动器。通过直接PWM驱动或恒流PWM控制可实现高效率驱动。内置各种保护电路,可输出通知各种保护电路动作的支持Wired-Or的异常检出信号,有利于实现组件的高可靠性。
ROHM
BD63150AFM
本产品是能驱动1个DC有刷电机的H桥电机驱动器。通过直接PWM驱动或恒流PWM控制可实现高效率驱动。内置各种保护电路,可输出通知各种保护电路动作的支持Wired-Or的异常检出信号,有利于实现组件的高可靠性。
ROHM
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