Rohm BD6640KVT Silicon monolithic integrated circuit Datasheet

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Structure
Silicon Monolithic Integrated Circuit
Product Series
4ch Sensorless System Motor Driver for MD
Type
BD6640KVT
Features
・Operates at low power supply voltage (2.1V min)
・Power DMOS output with low ON resistance (0.8Ω Typ.)
・Incorporates a charge pump circuit for VG boost.
・3-phase full-wave soft-switching sensorless driver for spindle
・3-value control 3-phase driver for sled (built-in comparator for BEMF voltage detection)
・2ch, 3-value control H-bridges for focus/tracking
・PWM half-bridge for spindle VM power supply
○Absolute maximum ratings(Ta=25℃)
Parameter
Power supply voltage for control circuit
Power supply voltage for driver block
Symbol
Limit
Unit
VCC
7
V
VM
7
V
Power supply voltage for pre-driver block
VG
14
V
Input voltage
VIN
0~VCC
V
Iomax
*500
mA
Output current
Power dissipation
Operating temperature range
Storage temperature range
Junction temperature
Pd
**1250
mW
Topr
-25~+75
℃
Tstg
-55~+150
℃
Tjmax
+150
℃
*Must not exceed Pd or ASO, Tjmax=150℃.
**Reduced by 10mW/°C over Ta=25°C, when mounted on a glass epoxy board (70mm70 mm1.6mm).
○Operating conditions (Ta=-25~+75°C)
Parameter
Power supply voltage
Pulse input frequency
Symbol
Min.
Typ.
Max
Unit
VCC1,2
2.1
2.2
6.5
V
VM
-
-
5.0
V
VG
3
6.5
13
V
fin
-
-
500
kHz
This product described in this specification is not judged whether it applies to COCOM regulations.
Please confirm in case of export.
This product is not designed for protection against radioactive rays.
REV. C
2/4
○Electrical characteristics
(Unless otherwise specified, Ta=25°C, VCC1, 2=2.2V, VM=1.0V, fin=176kHz)
Parameter
Symbol
Limit
Unit
Conditions
Min.
Typ.
Max.
ICC
-
4.4
7.0
mA
at operation in all blocks
IST
-
1
10
μA
at standby in all blocks
RON
-
0.8
1.2
Ω
VG1
5.5
6.5
6.7
V
each input L
VG2
4.4
5.2
-
V
at operation in all blocks
Self-propelled oscillating frequency
fOSC
50
100
160
kHz
External clock synchronous range
fSYNC
-
-
500
kHz
Circuit current
Output ON resistance
upper and lower ON
resistance in total VG=10V
~Boost circuit~
Output voltage
~Oscillation circuit~
input from EXTCLK pin
~Spindle (3-phase full-wave sensorless driver) block~
Position
VCO
-10
-
+10
mV
Detection comparator input range
detection
comparator
VCD
0
-
VCC-
V
CST charge current
ICTO
-3.5
-2.1
-0.9
μA
CST=1V
CST discharge current
ICTI
1.0
3.6
7.5
mA
CST=1V
CSL charge current
ICLO
-3.5
-7.5
-13
μA
CSL=0.5V
CSL=0.5V
CSL discharge current
ICLI
1.2
3.0
6.5
μA
CSL clamp H voltage
VCLH
0.7
0.8
0.9
V
Brake comparator input current
IBR
-
-
2.0
μA
Brake comparator input offset
VBO
-15
-
+15
mV
Brake comparator input range
VBD
0
-
VCC-1
V
FG output pull-up resistance
RBF
10
20
30
kΩ
FG output L voltage
VOLF
-
0.2
0.3
V
RIB offset voltage
VRO
10
18
30
mV
Pre-drive loop gain
M-phase check
VRP
500
650
850
mV
VMCK
400
500
600
mV
BRK=VCC
Io=300μA
VM=0V
RIB=500Ω
~Sled, focus, tracking, PWM power supply (stepping, H-bridge, and half-bridge driver) block~
Logic H level input voltage
VINH
VCC-0.4
-
VCC
V
Logic L level input voltage
VINL
0
-
0.4
V
IINH1
-
-
1
μA
VIN=2.2V
IINH2
-
350
600
μA
VIN=2.2V EXTCLK pin
VIN=0V
Logic H level input current
Logic L level input current
Output propagation delay time
Short pulse response
IINL
-1
-
-
μA
TRISE
-
0.2
1
μsec
TFALL
-
0.1
0.7
μsec
tmin
120
-
-
nsec
◎This product is not designed for protection against radioactive rays.
REV. C
input pulse width 200 ns
S3(33)
S2(32)
S1(31)
Decoder
Pre Drive
PreDrive
SLPG1,2
(42,38)
VG
+
-
+
-
+
-
REV. C
C1P
(51)
C2P
(49)
C1M
(50)
C2M
(48)
EXT
CLK
(52)
STALL
(4)
Pre Drive
Stand-by
STHB
(5)
SPVM1,2
(6,11)
SPUOUT SPVOUT SPWOUT
(7)
(10)
(12)
SPPG1,2
(8,13)
VG
(47)
Oscillator
Charge Pump
PWPG
(16)
PW1
OUT
(15)
PWVM
(14)
Pre
Drive
PreDrive
PW
IN1
(17)
IN2R
(3)
H2ROUT H2PG1,2
(55)
(58,54)
H2VM
(56)
H2FOUT
(57)
IN2F
(2)
TSD
RIB
(22)
control
Logic
FG CST
(26) (23)
gain
M A T R IX
BEFMU
SLVOUT
SLWO
BEFMW
(34)
(41)
(36)
UT
BEFMV
SLUOUT
SLVM1,2 (39)
(35)
(43)
(40,44)
SLCOM
(37)
N.C.
(9,53)
H1VM
IN1R
IN1F
(61)
(1)
(64)
H1FOUT H1ROUT H1PG1,2
(62)
(60)
(63,59)
Brake
comparator
VCC1, 2
(46,45)
CSL2 CSL1
(25) (24)
SLOPE
SIGNAL
+
ASGND
(29)
ー
+
+
+
ー
ー
ー
SGND
(30)
SPCOM
(21)
SPWIN
(20)
SPVIN
(19)
SPUIN
(18)
BRK-(28)
BRK+(27)
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○Package outlines
Type
BD6640KVT
Lot No.
TQFP64V outlines (Unit:mm)
○Block diagram
○Pin No./Pin name
NO.
Pin name
NO.
Pin name
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
IN1R
IN2F
IN2R
STALL
STHB
SPVM1
SPUOUT
SPPG1
N.C
SPVOUT
SPVM2
SPWOUT
SPPG2
PWVM
PWOUT
PWPG
PWIN1
SPUIN
SPVIN
SPWIN
SPCOM
RIB
CST
CSL1
CSL2
FG
BRK+
BRKASGND
SGND
S1
S2
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
S3
BEMFU
BEMFV
BEMFW
SLCOM
SLPG2
SLWOUT
SLVM2
SLVOUT
SLPG1
SLUOUT
SLVM1
VCC2
VCC1
VG
C2M
C2P
C1M
C1P
EXTCLK
N.C
H2PG2
H2ROUT
H2VM
H2FOUT
H2PG1
H1PG2
H1ROUT
H1VM
H1FOUT
H1PG1
IN1F
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○Notes on the use
(1)
Absolute maximum ratings
If the input voltage or the operating temperature range exceeds absolute maximum ratings, IC may be damaged. No
destruction mode (e.g., short-circuiting or open) can be specified in that case. If such special mode as will exceed
absolute maximum ratings is assumed, take the physical safety measures, such as a fuse.
(2)
Power supply lines
The regenerated current by BEMF of the motor will return. Therefore, take measures, such as the insertion of a capacitor
between the power supply and GND as the pass of the regenerated current. Determine the capacitance in full consideration
of all the characteristics of the electrolytic capacitor, because the electrolytic capacitor may loose some capacitance at low
temperatures. If the connected power supply does not have sufficient current absorption capacity, regenerative current will
cause the voltage of the power supply line to rise, which the product and its peripheral circuit may exceed the absolute
maximum ratings. It is recommended to implement physical safety measures such as the insertion of a voltage clamp diode
between the power supply and GND pins.
(3)
Ground potential
Ensure a minimum GND pin potential in all operating conditions.
(4)
Design for heat
Use the design for heat that allows for a sufficient margin in light of the power dissipation (Pd) in actual using conditions.
(5)
Operation in strong magnetic field
Use caution when using the IC in the strong magnetic field as doing so may cause the IC to malfunction.
(6)
ASO
When using the IC, make settings so that the output transistors for the motor will not be used under conditions in excess
of the absolute maximum ratings and ASO.
(7)
Thermal shutdown circuit
This IC incorporates thermal shutdown circuit(TSD circuit).
When the chip temperature becomes the one shown in below, TSD circuit operates and makes the coil output to motor
open. It is designed to shut the IC off from 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.
TSD ON temperature[℃]
(typ.)
Hysteresis temperature
175
(8)
[℃]
(typ.)
20
Ground wiring pattern
When having both small signal and large current GND, it is recommended to isolate the two GND patterns, placing a
single ground point at the application's reference point so that the pattern wiring resistance and voltage variations caused
by large currents do not cause voltage variations of the small signal GND. Be careful not to change the GND wiring
pattern of any external parts, either.
REV. C
Notice
Notes
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R1120A
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