ROHM BD64550EFV-E2

Motor Drivers for Printers
System Driver
for Ink Jet Printers
BD64550EFV
No.10016EAT03
●Description
This is 1-chip system motor driver integrating 2-channel H-bridge driver, step-down switching regulator with built-in power
DMOS, series regulator and reset output.
●Features
1) Low-on resistance output H-bridge driver (2-channel)
2) Constant-current chopping drive H-bridge driver
3) Switching regulator with built-in P-channel power DMOS FET
4) Soft start function: 23.6 ms (Typ.)
5) Reset release timer: 80 ms (Typ.)
6) 16 bit serial interface
7) Logic input interface (serial/parallel changeable)
8) Ultra thin type high heat dissipation HTSSOP-B40 package
9) Overcurrent protection in H-bridge driver block
10) Input voltage low voltage protection in H-bridge driver block
11) Overcurrent protection in switching regulator block
12) Output overvoltage protection in switching regulator block
13) Output low voltage protection in switching regulator block
14) Thermal shutdown
●Applications
Inkjet printer, photo printer, etc.
●Absolute Maximum Ratings (Ta=25℃)
Parameter
Symbol
Ratings
Unit
VM
40
V
Logic input voltage
VL
-0.4 ~ 5.5
V
RIN applied voltage
VRIN
5.5
V
RNF voltage
VRNF
0.5
V
Pd
1600*
mW
Operating temperature range
TOPR
-25 ~ +85
℃
Storage temperature range
TSTG
-55 ~ +150
℃
Junction temperature
Tjmax
150
℃
Iomax (peak)
8.0
A
Iomax (DC)
2.5**
A
Switching regulator output current (DC)
Iomax
0.5
A
Series regulator output current (DC)
Iomax
0.25
A
VM applied voltage
Power dissipation
Motor driver output current (peak 500 ns)
Motor driver output current (DC)
* Reduced by 12.8 mW/℃ over 25 ℃, when mounted on a glass epoxy board (70 mm x 70 mm x 1.6 mm).
** Must not exceed Pd or ASO.
●Operating Conditions
Parameter
VM operating power supply voltage range
Symbol
Limit
Unit
VM
7 ~ 36
V
SCLK max. operating frequency
FSCLK
20
MHz
Switching regulator output voltage range
Vswreg
3~5
V
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1/16
2010.06 - Rev.A
BD64550EFV
Technical Note
●Electrical Characteristics (Unless otherwise specified,Ta=25℃,VM=24V)
Parameter
Symbol
Limit
Min.
Typ.
Max.
Unit
Conditions
Overall
VM current 1
IVM1
-
-
8
mA
VM=7V
VM current 2
IVM2
-
-
12
mA
VM=24V
H-bridge 1
Output on resistance (source side))
RONH1
-
0.6
0.78
Ω
Io=1A
Output on resistance (sinking side)
RONL1
-
0.4
0.52
Ω
Io=1A
Output leak current
ILEAK1
0
-
10
µA
VM=36V
VFH1
0.6
0.9
1.2
V
Io=1A
VFL1
0.6
0.9
1.2
V
Io=1A
Built-in diode forward direction voltage
(source side)
Built-in diode forward direction voltage
(sinking side)
H-bridge 2
Output on resistance (source side)
RONH2
-
0.7
0.91
Ω
Io=1A
Output on resistance (sinking side)
RONL2
-
0.5
0.65
Ω
Io=1A
Output leak current
ILEAK2
0
-
10
µA
VM=36V
VFH2
0.6
0.9
1.2
V
Io=1A
VFL2
0.6
0.9
1.2
V
Io=1A
VREF voltage range
VREF
0.8
-
3.5
V
VREF pin outflow current
IREF
-
0
1
µA
RNF pin outflow current
IRNF
5
15
30
µA
RNFS pin outflow current
IRNFS
-
0
1
µA
VOFFSET
-15
0
15
mV
High input voltage
VINH
2.0
-
5.5
V
Low input voltage
VINL
0
-
0.8
V
IIN
21
33
45
µA
DSEN threshold voltage
VSWBIAS
0.873
0.9
0.927
V
Output on resistance
RSWON
-
0.8
1.04
Ω
At Io=250mA
Leak current
VM=36V
Built-in diode forward direction voltage
(source side)
Built-in diode forward direction voltage
(sinking side)
Current control
VREF-RNFS offset voltage
VREF=2V
Control logic
Input current
Input voltage=3.3V
Switching power source
ISWLEAK
0
-
10
µA
DUTY_MAX value
DMAX
-
92
-
%
Clock frequency
FSW
130
200
270
kHz
DSEN pin outflow current
IDSEN
-
0
1
µA
Output voltage
VSOUT
1.425
1.5
1.575
V
Leak current
ISLEAK
0
-
10
µA
Series power source
At Io=70mA
RESET pin
Output voltage
VRSTL
0
-
0.2
V
Leak current
IRSTLEAK
0
-
10
µA
High VM threshold voltage
VMPORH
6.3
6.5
6.7
V
VM at power on
Low VM threshold voltage
VMPORL
5.9
6.1
6.3
V
VM at power off
High motor UVLO voltage
VMMTH
13.5
15
16.5
V
Off motor only
Low motor UVLO voltage
VMMTL
12.5
14
15.5
V
Reset delay time
TPOR
50
80
110
ms
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2/16
IDRAIN=1mA
2010.06 - Rev.A
BD64550EFV
Technical Note
●Reference Data
6
8.00
-25℃
6.00
2
1.2
0.8
Vref [V]
4
85℃
CLK8M [MHz]
4.00
0.4
2.00
0
0.00
0
8
16
24
32
0.0
-25
0
25
25
50
Temperature (℃)
Fig.2 Internal Reference Clock
(VM=24V)
Fig.3 Temperature dependence of
Internal Standard Voltage (VM=24V)
1.6
1.2
0.8
1.4
85℃
25℃
0.8
0.7
0.6
-25℃
0.4
Output H voltage :VOH[V]
0.9
Output L voltage :VOL[V]
Output H voltage :VOH[V]
-25
1.4
1.0
85℃
0.6
0.5
25℃
0.4
-25℃
0.3
0.2
0.2
0
400
800
1200
1600
0
Supply current :Io[mA]
Fig.4 OUT1 High Output Voltage
(source side)
400
800
1200
1600
Supply current :Io[mA]
85℃
1.0
25℃
0.8
0.6
-25℃
0.4
0
2000
400
800
1200
1600
2000
Supply current :Io[mA]
Fig.5 OUT1 Low Output Voltage
(sinking side)
1.4
1.2
75
0.0
0.0
2000
0
0.2
0.1
0.0
Fig.6 OUT2 High Output Voltage
(source side)
500
100
400
80
VM=7V
1.0
Swout voltage :Rsw[mV]
1.2
Output L voltage :VOL[V]
75
Temperature [℃]
Supply voltage :VM[V]
Fig.1 VM Current
50
85℃
0.8
25℃
0.6
-25℃
0.4
85℃
Output effect:[%]
Circuit current :Icc[mA]
25℃
300
25℃
200
-25℃
100
VM=24V
60
40
20
0.2
0
0.0
0
400
800
1200
1600
0
0
2000
100
200
300
500
Supply current :Io[mA]
Supply current :Io[mA]
Fig.7 OUT2 Low Output Voltage
(sinking side)
0
100
200
300
400
500
Output current :[mA]
Fig.8 Switching Regulator High Output
Voltage
Fig.9 Switching Regulator Efficiency
(Ta=25℃)
4
2.0
-25℃ 25℃
Swout voltage :SV[mV]
1.8
Rout voltage:[V]
400
1.6
1.4
1.2
1.0
85℃
3
2
1
0
0
50
100
150
200
250
Supply current :[mA]
Fig.10 Series Regulator Load Regulation
(VM=24V, Ta=25℃)
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0
2
4
6
8
Supply v oltage :VM[V]
Fig.11 Reset Output
(Pull up to switching regulator at 10kΩ)
3/16
2010.06 - Rev.A
BD64550EFV
Technical Note
●Block Diagram, Application Circuit Diagram, and Pin Function
Be sure to use VM1,VM2.VM3 and VM4 by short-circuit.
VM2
32
8
33
9
VM1
VM1
VM2
OUT2P
39
Pre
driver
34
OUT1P
7
Pre
driver
OUT1M
OUT2M
RNF2
0.2Ω
(0.04~0.35Ω)
RNF2
0.2Ω(0.04Ω~0.35Ω)
Io1=(VREF1/10)・(1/RNF1S)
See P.9.
2
37
RNF1
3
CONTROL LOGIC
38
N.C.
1
40
PGND
OUT1M
2
39
OUT2P
RNF1
3
38
RNF2
RNF1
4
37
RNF2
RNF1S
5
36
RNF2S
N.C.
6
35
N.C.
OUT1P
7
34
OUT2M
VM1
8
33
VM2
VM1
9
32
VM2
VM4
10
31
VM3
N.C.
11
30
N.C.
SWOUT
12
29
AGND
PGND
N.C.
13
28
RESET
DGND
21
ROUT
14
27
SCLK
N.C.
15
26
SDATA
RIN
16
25
STROBE
N.C.
17
24
DC2P
DSEN
18
23
DC2E
VREF2
19
22
SELECT
VREF1
20
21
DGND
RNF1
20
RNF1S
VREF1
36
RNF2S
VREF2 19
1/10
1/10
0.2Ω
(0.04Ω~0.35Ω)
4
5
Same as RNF1
SELECT 22
31
DC2P 24
28
SCLK(DC1P) 27
Serial
Selector
DC2E
23
STROBE(DC1E)
25
300µF
(220µF~470µF)
VM3
RESET
POWER
MONITOR
Control
RESET
40
SDATA 26
AGND
29
From
VDCDCOUT
OSC
UVLO
TSD
BG
16
10
RIN
REG
ROUT
VM4
BG BG
DRIVER
14
SWOUT
VDCDCOUT
220µH
2.7kΩ
12
1µF
(0.1µF~2.2µF)
4700pF
18
100µF
1kΩ
DSEN
The figure on the left-hand side shows
optimum recommended values.
See P.10 for setting.
Fig.12 Block Diagram and Application Circuit Diagram
No.
1
2
3
Function
No.
Non Connection
21
OUT1M H-bridge output pin 1M
22
Pin
name
DGND
Function
Digital GND
SELECT Input pin select pin
RNF1
Output current detection pin 1
23
DC2E
H-bridge 2 side enable input pin
4
RNF1
Output current detection pin 1
24
DC2P
H-bridge 2 side phase pin
5
RNF1S
6
NC
25
STROBE
26
SDATA
Serial port data input pin
27
SCLK
Serial port clock input pin /
H-bridge 1 side phase input pin
7
Output current detection input pin
Non Connection
OUT1P H-bridge output pin 1P
Serial port strobe input pin /
H-bridge 1 side enable pin
8
VM1
Motor power supply pin
9
VM1
Motor power supply pin
10
VM4
Switching regulator power supply pin
28
RESET Reset signal output pin
11
NC
Non Connection
29
AGND
12
*
Pin
name
NC
Fig.13 Pin Assignment Diagram
SWOUT Switching regulator output pin
13
NC
14
ROUT
ANALOG GND
30
NC
Non Connection
Non Connection
31
VM3
Power supply pin
Series regulator output pin
32
VM2
Motor power supply pin
VM2
Motor power supply pin
15
NC
Non Connection
33
16
RIN
Series regulator power supply pin
34
OUT2M H-bridge output pin 2M
17
NC
Non Connection
35
NC
18
DSEN
Switching regulator voltage sense pin
36
RNF2S
19
VREF2
Reference voltage input pin
37
RNF2
Output current detection pin 2
20
VREF1
Reference voltage input pin
RNF2
Output current detection pin 2
38
Non Connection
Output current detection input pin
39
OUT2P H-bridge output pin 2P
40
PGND
POWER GND
Precaution regarding VM pin
If you use VM1, VM2, VM3 and VM4 not by short-circuit, they may be destroyed. Be sure to use them by short-circuit.
And be sure to set up a bypass capacitor (220µF to 470µF) closer to VM3 pin as much as possible.
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4/16
2010.06 - Rev.A
BD64550EFV
Technical Note
●Pin selection function
Either serial control or external PWM control can be selected for motor control type with SELECT pin (pin 22).
SELECT
Output state
L
Serial input mode
H
External PWM control mode
STROBE/DC1E(25pin)
ENA PHA
SEL
Internal shift register
OUTPUT
SEL
SDATA(26pin)
Serial
Control
Logic
SEL
SCLK/DC1P(27pin)
Serial
SEL
DC2P(24pin)
Serial
DC2E(23pin)
SELECT(22pin)
Fig.14 Serial Input Block Diagram
The input/output logic at SELECT = H is as follows.
DC1E/DC2E
Output state
L
Open
H
ACTIVE
DC1P/DC2P
OUTP
OUTM
L
SINK
SOURCE
H
SOURCE
SINK
○Procedure of DC motor drive by external PWM control
1) Serial setting
Set the serial by SELECT pin = L. (WORD_S and WORD_D setting)
・WORD_S (see P.7) is a drive parameter for setting OFF_TIME, BLANK TIME etc.
・WORD_D (see P.7) is for drive setting to set drive mode of each H-bridge.
When setting WORD_D (see P.7), make sure that ENABLE signal (ENABLE_1､ENABLE_2) of serial bit is L.
If ENABLE signal is H, the motor may operate.
Input of DC2P pin can be either H or L.
2) External PWM drive mode switch
Set external PWM drive mode by SELECT pin = H.
Switch by DC1E (STROBE)/CD2E pin = L when switching SELECT pin.
3) Drive
PHASE, ENABLE pin input signal (DC1E/DC1P/DC2E/DC2P) drives in external PWM mode.
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5/16
2010.06 - Rev.A
BD64550EFV
Technical Note
●Serial interface
16-bit 3-linear type serial interface (SDATA (pin 26), SCLK (pin 27), STROBE (pin 25)) is provided to set the operation and
the value of current limit. Data are sent to the internal shift register by falling edge of SCLK pin in the area L of STROBE pin.
Data of shift register are written in an appropriate address of internal memory of 2*15 bits by rising edge of STROBE pin
according to address data of D15.The input order of serial data is from D0 to D15.
Address data
D15
Word select
0
WORD_S
1
WORD_D
Memory data allocation
BIT
WORD_S
Default
WORD_D
Default
D0
Rohm_Reserve[2]
0
Rohm_Reserve[11]
0
D1
Rohm_Reserve[1]
0
Rohm_Reserve[10]
0
D2
Rohm_Reserve[0]
0
Rohm_Reserve[9]
0
D3
OFF TIME_2[2]
0
Rohm_Reserve[8]
0
D4
OFF TIME_2[1]
0
Rohm_Reserve[7]
0
D5
OFF TIME_2[0]
0
Rohm_Reserve[6]
0
D6
BLANK TIME_2[1]
0
Rohm_Reserve[5]
0
D7
BLANK TIME_2[0]
0
Rohm_Reserve[4]
0
D8
OFF TIME_1[2]
0
Rohm_Reserve[3]
0
D9
OFF TIME_1[1]
0
PWM_MODE_2
0
D10
OFF TIME_1[0]
0
S_PHASE_2
0
D11
BLANK TIME_1[1]
0
S_ENABLE_2
0
D12
BLANK TIME_1[0]
0
PWM_MODE_1
0
D13
MASK SELECT
0
S_PHASE_1
0
D14
SWOFF
0
S_ENABLE_1
0
The timing of serial report writing is shown in the right figure.
And the minimum timing of each is as follows:
A：SDATA setup time･･･････････････････
10nsec
B：SDATA hold time････････････････････
10nsec
C：Setup STROBE to SCLK falling edge･･
50nsec
D：SCLK low pulse width････････････････
25nsec
E：SCLK High pulse width･･･････････････
25nsec
F：Setup SCLK falling edge to STROBE･･･
25nsec
G：STROBE pulse width････････････････
50nsec
H：Setup RESET to SCLK Rising･････････
50µsec
H
RESET
STROBE
D
E
F
G
C
SCLK
A
SDATA
B
D0
D1
D15
○RESET signal is an internal RESET signal and generated inside IC at the same timing of external RESET output.
○STROBE, SCLK and SDATA signals are input signals through external ASIC.
Fig.15 Serial Signal Input Timing
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6/16
2010.06 - Rev.A
BD64550EFV
Technical Note
●Serial Port Explanation
WORD_S
○SWOFF
Set on/off of switching regulator circuit.
0
Switching regulator on
1
Switching regulator off
○MASK SELECT
Common mask can be provided to 2-phase H-bridge drive noise mask (BLANK time).
0
Independent mask on single-phase/two-phase.
1
Common mask on single-phase/two-phase.
○BLANK TIME
Current-limit comparator monitors RNF pin voltage to set limit to current, but during the period from switching on to BLANK
TIME, detection becomes invalid in order to avoid wrong detection caused by spike noise that happens at the time of
switching on. See P.8 for details.And during the period from ENABLE signal on to BLANK TIME at switching of PHASE
signal, detection becomes invalid as well.
[1]
[0]
BLANK TIME
Unit
0
0
2.0
µs
0
1
3.0
µs
1
0
4.0
µs
1
1
5.0
µs
○OFF TIME
Set current decay time.
[2]
[1]
[0]
OFF TIME
Unit
6
µs
0
0
0
0
0
1
8
µs
0
1
0
10
µs
0
1
1
12
µs
1
0
0
14
µs
1
0
1
16
µs
1
1
0
18
µs
1
1
1
20
µs
WORD_D
○S_ENABLE_1/S_ENABLE_2
Each bridge on/off signal. Output state is as follows.
Output state
0
Open
1
ACTIVE
○S_PHASE_1/S_PHASE_2
Set the direction of current of each bridge. Output state is as follows.
P
M
0
SINK
SOURCE
1
SOURCE
SINK
○PWM_MODE_1/PWM_MODE_2
Set current decay mode in bridge1 and 2. (See page 8 for details about each mode.)
0
FAST DECAY
1
SLOW DECAY
(※)Rohm_Reserve
Rohm_Reserve is special mode setting port for inspection at shipment. Especially, if Rohm Reserve [3], [4], [5], [7], [8], [9], [10], [11] is set to H by mistake,
malfunction may be caused. Be sure not to set.
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7/16
2010.06 - Rev.A
BD64550EFV
Technical Note
●H-bridge Driver Operation
This IC has built-in 2-channel H-bridge driver.
Each can be used for DC motor drive independently.
1. Current setting
Motor output current-limit value can be set according to the equation below.
Io=(VREF/10)・(1/RNFS)
[A]
Decide within the range VREF = 0.8V to 3.5V, RNFS = 0.04Ωto 0.35Ω.
2. DECAY mode
Current decay mode can be selected from serial input at the time of motor chopping drive.
Each mode and timing is as follows.
○SLOW DECAY mode
○FAST DECAY Mode
○Timing chart
VM
VM
OFF→OFF ON→OFF
ON→OFF
0
OFF→OFF
48
1
FBASE
(Internal 8 MHz)
Limit value
Output current
ON→OＮ
OFF→OFF
ON→OFF
OFF→OFF
On time
Off time
(Set by off time)
SLOW
At the time on
At the time on
At the time off (at DECAY)
At the time off (at DECAY)
Fig.16 On/Off Timing at SLOW
3.
FAST
Fig.17 On/Off Timing at FAST
Fig.18 DECAY Mode Timing Chart
Protection area for output current value wrong detection
In order to avoid wrong detection of current detection comparator by varistor current element in each motor, current
detection are masked at the timing as follows.
①PHASE switching time
②ENABLE on time
③When output is on after OFF_TIME is finished at the time of current chopping drive
①PHASE switching time
PHASE signal
Motor current
Mask area
BLANK TIME
Fig.19 Timing Chart of PHASE Switching Time
②ENABLE on time
③Current chopping driving time
RNF voltage
ENABLE
Motor current
Mask area
BLANK TIME
Mask area
OFF TIME
BLANK TIME
Fig.20 Timing Chart of ENABLE On Timing
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Fig.21 Timing Chart of Current Chopping Driving Time
8/16
2010.06 - Rev.A
BD64550EFV
Technical Note
●Switching regulator operation
○Basic operation
A switching regulator circuit that repeats on/off being synchronized with internal CLK (200 KHz) is built-in.
The start up output voltage SWOUT (pin 12) becomes up and run step by step with soft start at the VM power-on
(VM≧VMPORH).The output voltage is determined by the equation below with external resistance.
VOUTDCDC=VBIAS・｛(R1+R2)/R2 ｝ [V]
The setting should be performed so that the switching regulator output voltage (VOUTDCDC) waveform is optimized within
the range of VOUTDCDC = 3V to 5V, VBIAS = 0.9V (Typ.), R1 + R2 = 1kΩ to 10kΩ, C1 = 1,000pF to 10,000pF.
200KHzCLK
SWOUT
DSEN
+
+
VOUTDCDC
DRIVER
R1
0.9V
SWOFF
C1
DSEN
BIAS
R2
DAC
SS
COUNTER
CLK（=1.95kHz）
Fig.22 Switching Regulator Block Diagram
Reference clock
（200kHz）
DUTY MAX
Output voltage
MAX_DUTY 92%
⇒
SWOUT
Fig.23 Timing Chart of Switching Regulator Operation
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9/16
2010.06 - Rev.A
BD64550EFV
Technical Note
○Soft start
As shown in Fig.24, VOUTDCDC output voltage becomes up and run step by step with soft start at the time of power-on.
VM voltage
VMPORH
CLK195
Oscillation
(Internal)
Counter output
1 2 3 4 5 ・・ ・・・・・49・・・ ・・63 64
SWOUT
Constant ON Duty
~Duty increase~
ON Duty= VDCOUT/VM
1.21V
0.90V
DAC output
0V
5.0Vor3.3V
VOUTDCDC output voltage
0V
T1=23.6[msec]
T2=32.8[msec]
Fig.24 Soft Starting Time Timing Chart
This soft start method is realized by changing comparator positive side voltage that determines output duty of switching
regulator to linear using DAC.
Soft start time T1 is constant value regardless of VM voltage.
Soft start time
T1=23.6msec(typ.)
Count finish time
T2=32.8msec(typ.)
○Series regulator operation
Inputting switching regulator output into RIN pin (pin 16) enables to drive series regulator circuit.
At the time of power-on, output voltage start up step by step with soft starting at the same timing as switching regulator
circuit.^Soft start time is 23.6ms (Typ.).
Regarding external capacitor of ROUT pin (pin 14), it works normally without setting. But switching noise of switching
regulator becomes easy to get in due to dragging on board pattern and the like. Pay attention to switching noise.
RIN
Switching regulator
Regulator
ROUT
0.9V
20kΩ
(typ.)
Internal CLK
1.95kHz
SS
COUNTER
DAC
30kΩ
(typ.)
Fig.25 Series Regulator Block Diagram
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© 2010 ROHM Co., Ltd. All rights reserved.
10/16
2010.06 - Rev.A
BD64550EFV
Technical Note
●Protection function
○Protection circuit function
Overall
Overheating protection
DC motor drive circuit
Overcurrent protection
Switching regulator circuit
Overcurrent protection, output overvoltage protection, output low voltage protection
Series regulator circuit
None
○Operation at protection circuit operation
①Overheating protection・・・All functions are shutout along with junction temperature rise
Thermal shutdown temperature
175℃(typ.)
Switching regulator
Series regulator
DC motor
RESET
Re-start
OFF
OFF
OFF
L
Again power-on
At protection operation
②Overcurrent protection (Switching regulator)
Set current
ISWOC
2.6(A)
0.5µsec
(※)
State after operation
All function shutout
Switching regulator
Series regulator
DC motor
RESET
Re-start
OFF
OFF
OFF
L
Again power-on
Operating
③Overcurrent protection (DC motor)
Set current
IDCOC
3.8(A)
Operating
Mask time
Switching regulator
ON
Mask time
1.5µsec
Series regulator
ON
State after operation
Shown below
DC motor
OFF
Motor current
RESET
L_PULSE
Re-start
Serial re-input
IDCOC setting value
RESET signal
L
Data default
Serial data
1.5μsec
40msec
Fig.26 Timing Chart of Motor Overcurrent Protection
(※)
If the output pulse of switching regulator is 0.5µs or below, the overcurrent function does not operate even at the time of overcurrent outflow.
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11/16
2010.06 - Rev.A
BD64550EFV
Technical Note
④Low voltage protection/overvoltage protection circuit
All functions are shutout on the condition of setting value (+30%, -30%) while DSEN pin voltage (pin 18) of switching
regulator circuit is monitored.
Set voltage
Mask time
State after operation
VSWLV
0.60(V)
10µsec
All function shutout
VSWOH
1.20(V)
10µsec
All function shutout
Note that output overvoltage and output low voltage protection does not work until soft start count finish (32.8 ms, Typ.)
at the time of start up of DC/DC power after power-on.
Switching regulator
Series regulator
DC motor
RESET
Re-start
OFF
OFF
OFF
L
Again power-on
Operating
DSEN
SWOUT
DRIVER
0.9V
BIAS
DAC
DSEN
SS
COUNTER
All function
off circuit
Mask during
soft starting
0.60V
1.21V
Fig.27 Switching Regulator Block Diagram
○RESET function
Power-on RESET circuit is built-in for VM power source.
H is output at RESET pin through DELAY time of internal counter when power voltage goes up to VMPORH (6.5 V, Typ.) or
higher at the time of power-on. In addition, hysteresis is set up at the time of power-down to output L at RESET pin with
VMPORL (6.1 V, Typ.) And no response time (2.5µs, Typ.) of voltage detection is set in order to avoid wrong detection by
sudden power-off.If protection circuits other than overcurrent protection of motor starts operating, RESET is not released if
VM power is not on again.
VM
Internal
regulator
OSC
B.G
RESET1
DCOC
VM
RESET1
POWER
monitor
AND
BG
BG
Protection detection other than
DCOC
RESET
RESET2
VM
UVLO
DCOC
Counter
POR
Counter
AND
OSC
Latch circuit
SWOFF
SS
Counter
（SOFT START）
Fig.28 RESET Internal Circuit Block Diagram
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© 2010 ROHM Co., Ltd. All rights reserved.
12/16
2010.06 - Rev.A
BD64550EFV
Technical Note
●I/O Circuit Diagram
① OUT1P, OUT1M, OUT2P, OUT2M, RNF1 and RNF2
② RNF1S and RNF2S
VM1, VM2
OUT1P, OUT2P
OUT1M, OUT2M
Overcurrent protection circuit
RNF1S, RNF2S
RNF1, RNF2
15μA(TYP.)
③ SWOUT
④ RIN and ROUT
RIN
VM4
ROUT
SWOUT
⑤ DSEN
DSEN
⑥ VREF1 and VREF2
⑦ Logic input
⑧ RESET
RESET
Fig.29 I/O Circuit
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© 2010 ROHM Co., Ltd. All rights reserved.
13/16
2010.06 - Rev.A
BD64550EFV
Technical Note
●Power Dissipation Reduction
On the backside of HTSSOP-B40 package, metal is filled in. Heat dissipation is possible by letting in a through hole from
backside. Power dissipation can be improved by providing heat dissipation pattern of copper foil or the like not only on the
board surface but also on the backside. The metal on the backside shorts with the backside of IC tip and the potential is GND.
Therefore, avoid shorts with other potential than GND, or malfunction or destruction may happen. It is recommended that
backside metal should short with GND by soldering.
5.0
Measuring instrument: TH156 (Kuwano Denki)
Measuring state: ROHM substrate mounted
Board size:70mm×70mm×1.6mm(Thermal via on the board)
Solder the board and exposed heat release part of package backside.
Board①:1-layer board (Backside copper foil area: 0 mm x 0 mm)
Board②:2-layer board (Backside copper foil area: 15 mm x 15 mm)
Board③:2-layer board (Backside copper foil area: 15 mm x 15 mm)
Board④:4-layer board (Backside copper foil area: 70 mm x 70 mm)
④4.7W
4.5
4.0
Power Dissipation ：Pd （W)
③3.6W
3.5
Board①:θja=78.1℃/W
Board②:θja= 64.1℃/W
Board③:θja=34.7℃/W
Board④:θja=26.6℃/W
3.0
2.5
②1.95W
2.0
①1.6W
1.5
1.0
0.5
0.0
0
25
50
75
100
125
150
175
Ambient Temperature : Ta(℃)
Fig.30 Power Dissipation Reduction
●Notes for Use
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 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) Connecting the power supply connector backward
Connecting the power supply connector backwards may result in damage to the IC. Insert external diodes between the power
supply and the IC's power supply pins as well as the motor coil to protect against damage from backward connections.
3) Power supply lines
As return of current regenerated by back EMF of motor happens, take steps such as putting capacitor between power
supply and GND as a electric pathway for the regenerated current. Be sure that there is no problem with each property
such as emptied capacity at lower temperature regarding electrolytic capacitor to decide capacity value.
If the connected power supply does not have sufficient current absorption capacity, regenerative current will cause the
voltage on the power supply line to rise, which combined with the product and its peripheral circuitry may exceed the
absolute maximum ratings. It is recommended to implement a physical safety measure such as the insertion of a voltage
clamp diode between the power supply and GND pins.
4) GND potential
Ensure a minimum GND pin potential in all operating conditions.
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14/16
2010.06 - Rev.A
BD64550EFV
Technical Note
5) Setting of heat
Use a thermal design that allows for a sufficient margin in light of the power dissipation (Pd) in actual operating conditions.
BD64550EFV expose its frame of the backside of package. Note that this part is assumed to use after providing heat
dissipation treatment to improve heat dissipation efficiency . Try to occupy as wide as possible with heat dissipation
pattern not only on the board surface but also the backside.
6) Pin short and mistake fitting
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 pins caused by the
presence of a foreign object may result in damage to the IC.
7) Actions in strong magnetic field
Use caution when using the IC in the presence of a strong magnetic field as doing so may cause the IC to malfunction.
8) ASO
When using the IC, set the output transistor so that it does not exceed absolute maximum ratings or ASO.
9) Thermal shutdown circuit
The IC has a built-in thermal shutdown circuit (TSD circuit). If the chip temperature becomes Tjmax=150℃, and higher,
coil output to the motor and regulator output will be OFF, and reset output will be L. The TSD circuit is designed only to
shut the IC off to prevent runaway thermal operation. It is not designed to protect or indemnify peripheral equipment. Do
not use the TSD function to protect peripheral equipment.
10) 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.
11) Regarding input pin of the IC
This monolithic IC contains P+ isolation and P substrate layers between adjacent elements in order to keep them
isolated/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 Fig. 31,
○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 (P substrate) voltage to input pins.
Resistor
Tr
Pin A
Pin B
C
Pin B
B
E
Pin A
N
P+
N
P+
P
N
P substrate
Parasitic element
Parasitic
element
N
P+
N
B
P+
P
E
P substrate
GND
GND
N
C
Parasitic element
Fig.31 example of IC structure
GND
Parasitic
element
GND
Other adjacent elements
12) Ground Wiring Pattern
When using both small signal and large current GND patterns, it is recommended to isolate the two ground 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 variations in the small signal ground voltage. Be careful not to change the
GND wiring pattern of any external components, either.
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© 2010 ROHM Co., Ltd. All rights reserved.
15/16
2010.06 - Rev.A
BD64550EFV
Technical Note
●Ordering Part Number
B
D
6
Part No.
4
5
5
0
E
Part No.
F
V
Package
EFV : HTSSOP-B40
-
E
2
Packaging and forming specification
E2: Embossed tape and reel
HTSSOP-B40
<Tape and Reel information>
13.6±0.1
(MAX 13.95 include BURR)
4 +6
−4
(8.4)
1
Tape
Embossed carrier tape (with dry pack)
Quantity
2000pcs
Direction
of feed
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
)
20
1PIN MARK
1.0Max.
0.625
1.2 ± 0.2
(3.2)
0.5 ± 0.15
21
5.4±0.1
7.8±0.2
40
+0.05
0.17 −0.03
0.85±0.05
0.08±0.05
S
+0.05
0.24 −0.04
0.65
0.08
M
0.08 S
1pin
(Unit : mm)
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© 2010 ROHM Co., Ltd. All rights reserved.
Reel
16/16
Direction of feed
∗ Order quantity needs to be multiple of the minimum quantity.
2010.06 - Rev.A
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
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
failure of any Product, such as derating, redundancy, fire control and fail-safe designs. ROHM
shall bear no responsibility whatsoever for your use of any Product outside of the prescribed
scope or not in accordance with the instruction manual.
The Products are not designed or manufactured to be used with any equipment, device or
system which requires an extremely high level of reliability the failure or malfunction of which
may result in a direct threat to human life or create a risk of human injury (such as a medical
instrument, transportation equipment, aerospace machinery, nuclear-reactor controller, fuelcontroller or other safety device). ROHM shall bear no responsibility in any way for use of any
of the Products for the above special purposes. If a Product is intended to be used for any
such special purpose, please contact a ROHM sales representative before purchasing.
If you intend to export or ship overseas any Product or technology specified herein that may
be controlled under the Foreign Exchange and the Foreign Trade Law, you will be required to
obtain a license or permit under the Law.
Thank you for your accessing to ROHM product informations.
More detail product informations and catalogs are available, please contact us.
ROHM Customer Support System
http://www.rohm.com/contact/
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R1010A