MITSUBISHI M54544AL

MITSUBISHI <CONTROL / DRIVER IC>
M54544AL
Bi-DIRECTIONAL MOTOR DRIVER
WITH BRAKE FUNCTION AND THERMAL SHUT DOWN FUNCTION
DESCRIPTION
PIN CONFIGURATION (TOP VIEW)
The M54544AL is a semiconductor integrated circuit that is
capable of directly driving a smallsize bi-directional motor rotating
in both forward and reverse directions.
FEATURES
VCC1
1
VCC’1
2
Output 2
O2
3
Input 1
IN1
4
GND
5
IN2
6
Input 2
APPLICATION
Output 1
O1
7
Output power supply 2
VCC’2
8
Power supply 2
VCC2
9
Sound equipment such as tape deck and radio cassette, VTR, and
other general consumer appliances
FUNCTION
M54544AL
●Wide range of operating voltage (VCC=4 – 16V)
●Possible direct driving with TTL, PMOS and CMOS IC outputs
●Low output saturation voltage (large voltage across motors)
●Built-in clamp diode
●Large output current drive (IO(max)=±1.5A)
●Provided with brake function
●Built-in thermal shutdown protection circuit
Power supply 1
Output power supply 1
Outline 9P9
The M54544AL is an IC for driving a smallsize bi-directional motor
that rotates in both forward and reverse directions. When both
inputs 1 and 2 are set to low-level, outputs 1 and 2 are set to
“OFF”. When input 1 is set to high-level and input 2 is set to lowlevel, output 1 is set to high-level and output 2 is set to low-level
(forward rotation status). When input 1 is set to low-level and input
2 is set to high-level, output 1 is set to low-level and output 2 is set
to high-level (reverse rotation). When both inputs 1 and 2 are set to
high-level, both outputs 1 and 2 are set to low-level (brake status).
The power supply (VCC) to the control circuit and the power supply
(VCC’) for output are independently provided. The rotating speed of
the motor can be therefore changed by using VCC and VCC’ as
different power supplies and by making VCC or VCC’ variable.
If the motor resistance is high (light load and small driving current:
tens of mA), and VCC is larger than VCC’, current does not flow
backward from the V CC pin to VCC’ pin.
In addition, built-in thermal protection circuit protects the IC from
thermal destruction in case of abnormal condition such as motor
blocking.
LOGIC TRUTH TABLE
Input
IN1
L
H
L
H
IN2
L
L
H
H
Output
Remarks
O1
O2
“OFF” state “OFF” state No operation of IC
ex Forward rotation
H
L
Reverse rotation
L
H
Brake
L
L
BLOCK DIAGRAM
Power supply 1
Output power supply 1
Output power supply 2
Power supply 2
VCC1
VCC’1
Output 2 Output 1
O2
O1
VCC’2
VCC2
1
2
3
7
8
9
Thermal
protection
circuit
Input control
circuit
4
IN1
Input 1
5
6
GND
IN2
Input 2
MITSUBISHI <CONTROL / DRIVER IC>
M54544AL
Bi-DIRECTIONAL MOTOR DRIVER
WITH BRAKE FUNCTION AND THERMAL SHUT DOWN FUNCTION
ABSOLUTE MAXIMUM RATINGS (Ta=25°C, unless otherwise noted)
Symbol
VCC(1)
VCC(2)
VCC’
VI
VO
IO(max)
IO(1)
IO(2)
Pd
Topr
Tstg
Parameter
Conditions
Supply voltage(1)
Supply voltage(2)
Output supply voltage
Input voltage
Output voltage
Allowable motor rush current
Continuous output current(1)
Continuous output current(2)
Power dissipation
Operating temperature
Storage temperature
With an external heat sink (3000mm2 x 1.5mm)
top=10ms : cycle time 0.2Hz or less
With an external heat sink (3000mm2 x 1.5mm)
Ta=75˚C
Ratings
Unit
-0.5 – +16
-0.5 – +20
-0.5 – +16
0 – VCC
-0.5 – VCC’+2.5
±1.5
±330
±600
1.15
-10 – 75
-55 – 125
V
V
V
V
V
A
mA
mA
W
°C
°C
RECOMMENDED OPERATING CONDITION (Ta=25°C, unless otherwise noted)
Symbol
VCC
IO
VIH
VIL
tB
t j (shut)
Parameter
Conditions
Supply voltage
Output current
“H” input voltage
“L” input voltage
Motor braking interval
Thermal shutdown temperature
Min.
4
2
0
10
VCC ≥ 7V
Limits
Typ.
12
Max.
15
±300
VCC
0.4
100
150
Unit
V
mA
V
V
ms
˚C
ELECTRICAL CHARACTERISTICS (Ta=25°C, unless otherwise noted)
Symbol
Parameter
Test conditions
Output leak current
VCC=VCC’=20V
VI1=VI2=0V
VOH(1)
“H” output saturation
voltage(1)
VCC=VCC’=12V
VI1=2V
VI2=0V
VOH(2)
“H” output saturation
voltage(2)
VCC=VCC’=12V
VI1=0V
VI2=2V
VOL(1)
“L” output saturation
voltage(1)
VCC=VCC’=12V
VOL(2)
“L” output saturation
voltage(2)
IIH(1)
IIH(2)
“H” input current(1)
“H” input current(2)
ICC
Supply current
Limits
Typ.
VO=20V
VO=0V
IO(leak)
VI1=0V
VI2=2V
VI1=VI2=2V
VI1=2V
VI2=0V
VCC=VCC’=12V
VI1=VI2=2V
VCC=VCC’=12V, VI1=2V, VI2=0V
VCC=VCC’=12V, VI1=0V, VI2=2V
VCC=VCC’=16V
Output open
Min.
IOH(1)=-200mA
IOH(1)=-500mA
IOH(2)=-200mA
IOH(2)=-500mA
IOL(1)=200mA
10.8
10.7
10.8
10.7
IOL(1)=500mA
IOL(2)=200mA
IOL(2)=500mA
50
50
VI1=2V, VI2=0V
VI1=0V, VI2=2V
VI1=VI2=2V
VI1=VI2=0V
11.2
11.1
11.2
11.1
0.2
0.95
0.95
0.2
0.95
0.95
Max.
100
-100
Unit
µA
V
V
0.5
1.35
1.35
0.5
1.35
1.35
120
120
V
V
µA
µA
15
20
4
mA
MITSUBISHI <CONTROL / DRIVER IC>
M54544AL
Bi-DIRECTIONAL MOTOR DRIVER
WITH BRAKE FUNCTION AND THERMAL SHUT DOWN FUNCTION
TYPICAL CHARACTERISTICS
Thermal Derating (Absolute Maximum Rating)
Power Dissipation Pd(max) (W)
8
When Al heat sink of
25cm2 x 1.5mm(t) is used
6
4
Free
Air
2
0
0
25
50
75
100
Ambient Temperature Ta (°C)
“H” Output Saturation Characteristics
“L” Output Saturation Characteristics
-600
600
VCC=VCC’=12V
VCC=VCC’=12V
500
“L” Output Current IOL (mA)
“H” Output Current IOH (mA)
-500
-400
Ta=75˚C
-300
Ta=25˚C
-200
Ta=-20˚C
-100
0
0.0
0.2
0.4
400
300
Ta=75˚C
Ta=25˚C
200
Ta=-20˚C
100
0.6
0.8
“H” Output Voltage VCC’– VOH (V)
1.0
0
0.0
0.2
0.4
0.6
0.8
“L” Output Voltage VOL (V)
1.0
MITSUBISHI <CONTROL / DRIVER IC>
M54544AL
Bi-DIRECTIONAL MOTOR DRIVER
WITH BRAKE FUNCTION AND THERMAL SHUT DOWN FUNCTION
CAUTIONS
Since the thermal protection function of this IC may not work in
abnormal status (oscillation, low supply voltage, output shortcircuit, etc.), check the operation in the IC installation status when
using this function.
When the motor back electromotive force is large with the brakes
applied, for example, malfunction may occur in internal parasitic Di.
If flyback current of 1A or more flows, add Schottky Di to the
portion between the output and the GND.
When the IC is used at a high speed for PWM, etc., note that
switching of output results in delay of approx. 10µs.
APPLICATION EXAMPLES
1) When VCC and VCC’ are used as the same power supply
R2=3Ω
VB
R1=2Ω
VCC’2
C
10 – 100µF
VCC’1
M
Input 1
Input 2
VCC1
VCC2
9
8
7
6
5
4
3
2
1
M54544AL
2) When VCC is used as a fixed power supply and VCC’ is used as
a variable power supply
VCC
2Ω
C
C
10 – 100µF
VCC’1
VCC’2
1 – 10µF
M
Input 1
Input 2
VCC1
VCC2
9
8
7
6
5
4
M54544AL
3
2
1