Mitsubishi M56785FP Spindle motor driver Datasheet

MITSUBISHI <CONTROL / DRIVER IC>
M56785FP
SPINDLE MOTOR DRIVER
DESCRIPTION
PIN CONFIGURATION (TOP VIEW)
The M56785FP is a semiconductor integrated circuit in order to
drive the spindle motor.
N.C
1
42
N.C
S/S
2
41
W
RDS
3
40
V
FG
4
39
U
CI
5
38
RS
MODE2
6
37
MODE3
MODE1
7
36
MODE4
8
35
9
34
FEATURES
10
11
GND
M56785FP
● Large power dissipation (Power Package).
● 3.3V DSP available.
● The supply voltage with wide range.
● High motor drive current .
● Low saturation voltage. (typical 1.2V at load current 500mA)
● Motor current control for both motor torque directions.
● Reverse torque mode select [SHORT BRAKING,etc].
● Sleep mode. (Zero total current )
● Hall amplifier sensitivity select.
(Minimum voltage : 35mVp-p or 50mVp-p)
● FG signal output terminal.
● Automatic stop select. (Removable function)
● Reverse detected signal pin.
33
32
APPLICATION
12
CD-ROM,DVD,DVD-ROM,DVD-RAM etc.
13
30
14
29
GND
31
VM
15
28
Hw-
VCC2
16
27
Hw+
EC
17
26
Hv-
ECR
18
25
Hv+
VCC1
19
24
Hu-
HB
20
23
Hu+
N.C
21
22
N.C
Outline 42P9R-A
N.C: no connection
VCC2
16
MODE1
7
MODE2
6
W
S/S
RS
VCC1
39
40
41
2
38
19
Vref
I/I
Converter
BRAKING
MODE
CHANGE
MODE4
SENSE
TSD
MODE3
V/I Converter
37
FG
4
RDS
3
FG
RDS
GND
120°
MATRIX
36
GND
29 to 35
15
V
8 to 14
VM
U
++ -
BLOCK DIAGRAM
+
-
+
-
+
-
Hall
Bias
23
24
25
26
27
28
20
5
17
18
Hu+
Hu-
Hv+
Hv-
Hw+
Hw-
HB
CI
EC
ECR
MITSUBISHI <CONTROL / DRIVER IC>
M56785FP
SPINDLE MOTOR DRIVER
PIN DESCRIPTION
Pin No.
Symbol
20
N.C
S/S
RDS
FG
CI
MODE2
MODE1
GND
VM
VCC2
EC
ECR
VCC1
HB
21
N.C
1
2
3
4
5
6
7
– 14
8
15
16
17
18
19
Function
ABSOLUTE MAXIMUM RATING (Ta=25
Parameter
42
N.C
24
25
26
27
28
– 35
36
37
38
39
40
3
pin [RDS] and
4
Function
Hu+ Sensor amp. input
Hu- Sensor amp. input
Hv+ Sensor amp. input
Hv- Sensor amp. input
Hw+ Sensor amp. input
Hw- Sensor amp. input
GND
Hall amplifier sensitivity select
Automatic stop select
Motor current sense
Motor drive output U
Motor drive output V
Motor drive output W
pin[FG].
)
Conditions
Rating
Unit
pin
pin
19 pin
Note 1
16
16
7.0
1.5
V
V
V
A
– 28 pins
4.5
V
Power dissipation
Free Air
1.2
W
Thermal derating
Junction temperature
Operating temperature
Storage temperature
Free Air
9.6
150
-20 – +75
-40 – +125
mW/˚C
˚C
˚C
˚C
VM
VCC2
VCC1
Io
Motor supply voltage
12V supply voltage
5V supply voltage
Output current
VH(c)
Sensor amp.
Differential input range
Pt
Kθ
Tj
Topr
Tstg
41
23
29
Symbol
N.C
Hu+
HuHv+
HvHw+
HwGND
MODE4
MODE3
RS
U
V
W
22
Start / Stop
Reverse detected signal
Frequency generator output
Phase Compensation
Reverse torque mode select 2
Reverse torque mode select 1
GND
Motor supply voltage
12V supply voltage
Motor speed control
The reference voltage for EC
5V supply voltage
Bias for Hall Sensor
* Pull-up resistors (10kohm) are included in the circuits connected to
Symbol
Pin No.
15
16
23
*Note1 ; The ICs must be operated within the Pt (power dissipation) or the area of safety operation
MITSUBISHI <CONTROL / DRIVER IC>
M56785FP
SPINDLE MOTOR DRIVER
RECOMMENDED OPERATING CONDITIONS
Symbol
VCC1
VCC2
VM
Io
Parameter
Limits
Typ.
5.0
12.0
12.0
Min.
4.5
4.5
4.5
5V Power supply
12V Power supply
Motor Power supply
Output drive current
Unit
Max.
5.5
13.2
13.2
700
V
V
V
mA
ELECTRICAL CHARACTERISTICS (VCC=5V, VCC2=12V, VM=12V, Ta=25˚C unless otherwise noted.)
Symbol
Icc1
Icc2
Icc3
Parameter
Sleep Mode Supply
current- 1
Sleep Mode Supply
current- 2
Supply current- 3
Conditions
Limits
Typ.
Max.
0
100
µA
500
µA
6.0
mA
1.2
1.9
V
-40
0
-21
+21
0
+40
mV
Min.
15
and 16 pin total Input Current ( 2 pin low or open)
19
pin Input Current ( 2 pin low or open)
19
pin Input Current (EC=ECR=2.5V) [
2
pin High]
Unit
Vsat
Saturation voltage
Top and Bottom saturation voltage.
(Load current :500mA)
ECdeadECdead+
Dead Zone Control
voltage dead zone
EC < ECR
EC > ECR
ECR
Reference voltage
Input range
18
pin
[3.3v DSP available]
0.5
1.65
4.0
V
EC
Control voltage Input
range
17
pin
[3.3v DSP available]
0.5
1.65
4.0
V
Gio
Vlim
Control gain
Control limit
Io = Gio / Rsense [A/V]
Ilim = Vlim / Rsense [A]
0.25
0.27
0.3
0.3
0.35
0.33
V/V
V
VH com
Hall sensor amp
common mode input
range
23
– 28 pins
4.5
V
VHmin1
VHmin2
Hall sensor amp.
input signal revel
23
– 28 pins
VHb
Hall bias terminal
output voltage
Load current (IHb) =10 mA.
IHb
Hall bias terminal sink
current
Von
Motor start voltage
2 pin input voltage when it starts up the motor.
*The IC is in the active condition.
*The hall bias is available.
Voff
Motor stop voltage
2 pin input voltage when it stops the motor.
*The IC is in the sleep condition.
*The hall bias is off.
ViH
mode pin input high
voltage
7 pin[MODE1], 6 pin[MODE2], 37 pin[MODE3]
and 36 pin[MODE4] input voltage
when they are HIGH.
ViL
VOL
mode pin input low
voltage
3pin[RDS],4pin[FG]
output low voltage
1.2
MODE4=OPEN or HIGH
MODE4=GND
50
35
0.6
mV
p-p
0.85
1.2
V
30
mA
2.0
V
0.8
2.0
V
V
7 pin[MODE1], 6 pin[MODE2], 37 pin[MODE3]
and 36 pin[MODE4] input voltage
when they are LOW.
0.8
V
Io current = 1mA
0.5
V
MITSUBISHI <CONTROL / DRIVER IC>
M56785FP
SPINDLE MOTOR DRIVER
ELECTRICAL CHARACTERISTICS (VCC1=5V, VCC2=12V, VM=12V, Ta=25˚C Unless otherwise noted. )
The relationship between the EC-ECR (the difference
between EC<(control voltage> and ECR <reference
voltage> ) and the torque is shown in Figure 1.
The current gain is 0.6A/V (at sensing resistor :0.5ohm)
in both torque directions, and the dead zone is from
±0mV to ±40mV.
When the all short brake mode is selected, the coil
current under the reverse torque control depends on
the back emf. and the coil resistance.
Reverse Torque
Current limit
0.6A/V
0 – +40mV
0
0.6A/V
EC - ECR
0 – -40mV
Current limit
Forward Torque
Figure 1. The characteristics of the control voltage
and motor current ( Torque ).
THERMAL DERATING
6.0
(W)
This IC's package is POWER-SSOP, so improving
the board on which the IC is mounted enables a
large power dissipation without a heat sink.
For example, using an 1 layer glass epoxy resin
board, the IC's power dissipation is 2.7W at least.
And it comes to 4.0W by using an improved 2 layer
board.
The information of the H, I, J type board is shown
in the board information.
4.0W
using A-type board
Power Dissipation (Pdp)
5.0
3.0W
using B-type board
4.0
2.7W
using C-type board
3.0
2.0
1.0
0
25
50
75
Ambient Temperature
100
Ta (
125
)
150
MITSUBISHI <CONTROL / DRIVER IC>
M56785FP
SPINDLE MOTOR DRIVER
HALL AMPLIFIER INPUT AND COMMUTATION
The relationship between the hall amplifier inputs voltage and the
motor current outputs is shown in Figure 2.
Hw+
Hv+
Hu+
Hall elements
U
V
Hall
inputs
V
U
Outer loator
U
V
W
SOURSE
W
W
V
V
U
W
U
Output
current
REVERSE
EC>ECR
W
V
SINK
U
W
V
U
W
FORWARD
EC<ECR
Figure 2.
HALL AMPLIFIER INPUT SENSITIVITY SELECT
MODE4
OPEN or HIGH
GND
120 degree switching
120 degree
soft switching
** Io current
changes sharply.
The hallamp
minimum input voltage
is 50 mVp-p.
Figure 3 shows the hall amplifier input sensitivity select function. You are
able to select a sensitivity of a hall amplifier out of two levels which is
suitable for the hall elements type.
If the output minimum level of the hall elements is lower than 50mVp-p,
please connect the MODE4 pin to external GND. In this case, the
output current changes shaply. If the output minimum level of the hall
elements is higher than 50mVp-p, please make the MODE4 pin open,
then the output current is commutated softly.
We recommend that the output level of the hall elements be set between
80mVp-p and 120mVp-p, and the MODE4 pin is an open.
The hallamp
minimum input voltage
is 35 mVp-p.
Figure 3.
SLEEP MODE FUNCTION
START / STOP (
2
pin)
LOW or OPEN
HIGH
Motor Stop
Motor on
Bias off
Bias on
Hall-Bias of
Hall-Bias on
Figure 4.
Figure 4 shows the sleep mode function. If the 2 pin [S/S] is set to be
open or low, the motor drive outputs have high impedance and the motor
stops. Then, the IC bias current wil be a slight current (please refer to the
electrical characteristics), and the hall bias output will be cut off. When
the 2 pin input is high, all the circuits will work.
MITSUBISHI <CONTROL / DRIVER IC>
M56785FP
SPINDLE MOTOR DRIVER
FORWARD AND REVERSE ROTATION DETECT
FUNCTION
Figure 5 shows the circuits and the functions of the forward and
reverse rotation detect .
The output of the RDS pin is determined by the signals of hall
inputs ( Hu+, Hu-, Hv+ and Hv- ) which indicate the direction of
rotation. When the motor is spinning forward, the RDS pin output
will be low. When the motor rotates reversely in stop mode, it will
be high.
The RDS pin is pulled-up to VCC1 by internal resistor (typ.10kohm).
RDS
MODE3
FG
VCC1
Hu+
VCC1
Hu-
Hv+
Hv-
+
FG-amp
CI
-
Q
Q
D
R
+
T
Hall sensor-amp
-
EC-ECR
FORWARD
Hw+
Hv+
REVERSE
Hu+
Comparator
Hysteresis
RDS
FG
Figure 5.
Hw+
D
D
T
T
Q
Q
High
High
Low
High
Low
RDS
FG
Low
High
Low
Hw+
Hu+
Hv+
Hw-
MITSUBISHI <CONTROL / DRIVER IC>
M56785FP
SPINDLE MOTOR DRIVER
AUTOMATICALY STOP AFTER REVERSE
BRAKING FUNCTION
Figure 5 also shows the automaticaly stop (after the reverse
braking) circuit. Figure 6 is its function table which shows whether
the automaticaly stop function is on or off, and its state is
determined by MODE3 input.
When the MODE3 is open or high, the motor will stop rotating
automaticaly after the reverse braking.
When the MODE3 is low or connected to GND, the motor will
continue the reverse rotation. This function is useful for the case
that the system doesn't require the automaticaly stop function, and
in the system a motor receives a stop command from the outside
of this IC. For example, a µcom can detect the reverse rotation
from the RDS pin output, and can control all the torque of a motor.
So it can stop the motor outside this IC.
FG FUNCTION
Figure 5 also shows the circuits and the functions of the frequency
generator. The FG pin outputs the square pulse signal
synchronizing with the hall inputs [Hv+ and Hv-] timming .
The FG pin is pulled-up to VCC1 by an internal resistor [typ.
10Kohm].
MODE3
OPEN or HIGH
REVERSE TORQUE MODE SELECT FUNCTION
In the 4 times speed and the 6 times speed CDROM drive
system, the reverse braking style has been used for a
deceleration of the rotation speed. However, in the CDROM
drive system above an 8 times speed, the motor current above
0.5A is needed, because a high speed access time are required
for motor driver ICs. If the reverse braking is used at 0.5A, the
IC junction temperature will be too much high, and the heat loss
of the IC will be large.
Therefore, this motor driver has the braking mode select
function (REVERSE BRAKING MODE and SHORT BRAKING
MODE). The breaking mode can be determined by the external
logic signals synchronizing with servo timing, and it can make a
heat loss of the IC smaller by adjusting the junction
temperature.
Figure 7 shows the reverse torque mode select function table. If
you want the former braking style (the reverse braking ), please
select only the REVERSE BRAKING mode [MODE1=LOW or
OPEN and MODE2=HIGH]. But the heat loss will be larger, and
sometimes external heat sink would be necessary.
If it is possible to get ports more than two from µcom, you can
flexibly control the four kinds of BRAKING MODE. So the heat
loss can be half as usual. For example, the REVERSE
BRAKING MODE is on under the CLV control, and the ALL
SHORT BRAKING MODE is for seeking. When the motor
should be stopped, the ALL SHORT BRAKING MODE or the
REVERSE BRAKING MODE is available.
If you can only get one port, you can control only the MODE2.
At this time, you can control the two kinds of BRAKING MODE
[commutated short or reverse] on condition that the MODE1 is
set to be LOW or OPEN.
GND
BRAKING MODE (ECR < EC) SELECT FUNCTION TABLE
MODE1
AUTOMATIC
STOP
Figure 6.
UN-AUTOMATIC
(NON-STOP)
LOW or OPEN
HIGH
LOW
or
OPEN
COMMUTATED SHORT
BRAKING
ALL SHORT
BRAKING
HIGH
REVERSE BRAKING
OUTPUT OPEN
[only inertia]
MODE2
Figure 7.
MITSUBISHI <CONTROL / DRIVER IC>
M56785FP
SPINDLE MOTOR DRIVER
REVERSE TORQUE MODE SELECT FUNCTION
Figure 8 shows an example for the reverse torque mode select.
The CASE1 is an example for controlled REVERSE and
COMMUTATED SHORT BRAKING.
The CASE2 is an example for controlled REVERSE and ALL
SHORT BRAKING.
CASE 1
CASE 2
REVERSE AND COMMUTATED
SHORT BRAKING SELECT
REVERSE AND ALL SHORT
BRAKING SELECT
EC PIN INPUT VOLTAGE [ECR VOLTAGE = 2.5V]
EC PIN INPUT VOLTAGE [ECR VOLTAGE = 2.5V]
5.0V
5.0V
3.0V
ECR 2.5V
2.0V
3.0V
ECR 2.5V
2.0V
0V
0V
HIGH
HIGH
MODE2
MODE2
LOW
LOW
MODE1
MODE1
LOW
LOW
Commutated short
BRAKING
BRAKING
MODE
+1A
FORWARD
CURRENT
REVERSE
TORQUE
CURRENT
-1A
BRAKING
MODE
REVERSE
BRAKING
REVERSE
BRAKING
+1A
MOTOR CURRENT [ Rsense = 0.5 ohm ]
+60 0mA
-60 0mA
ALL
SHORT
BRAKING
MOTOR CURRENT
+60 0mA
FORWARD
CURRENT
MOTOR
STOP
REVERSE
TORQUE
CURRENT
-1A
-60 0mA
MOTOR
STOP
( Vbemf-Vd-Vsat ) / Ra
Vd ; diode voltage
Vsat ; npn transistor saturation voltage
Ra ; motor inner resistance
Figure 8.
MITSUBISHI <CONTROL / DRIVER IC>
M56785FP
SPINDLE MOTOR DRIVER
BASICALLY CHARACTERISTICS
This data is an example for typical sample.
Output saturation voltage and Load current Characteristics.
(Condition Vcc2=Vm=12V, Vcc=5V)
12.0
Top side
saturation
voltage
11.5
0.76
0.79
0.86
0.89
0.91
0.98
11.0
1.05
Output Voltage (V)
1.18
10.5
This device can use this
voltage value due to motor
drive.
1.5
1.0
0.76
0.62
0.49
0.38
0.5
0.07
0.13
0.25
Bottom side
saturation
voltage
0.32
0
0
200
400
600
800
1000
1200
Load current (mA)
Output saturation voltage and Load current Characteristics. (At bootstrap)
By taking advantage of bootstrap function, the output saturation
voltage can be lower.
(Condition Vcc2=6V,Vm=5V,Vcc=5V)
5.0
0.06
0.29
0.12
0.35
0.47
0.23
4.5
0.83
4.0
Output Voltage (V)
Top side
saturation
voltage
0.62
3.5
This device can use this
voltage value due to motor
drive.
1.5
1.0
0.38
0.5
0.07
0.13
0.49
0.62
0.76
0.25
Bottom side
saturation
voltage
0.32
0
0
200
400
600
Load current (mA)
800
1000
1200
MITSUBISHI <CONTROL / DRIVER IC>
M56785FP
SPINDLE MOTOR DRIVER
HB terminal voltage and Hall current characteristics.
(Condition :Vcc=4.4V – 7V)
1.6
1.4
HB terminal voltage (V)
1.2
1.0
0.85
0.8
0.6
0.4
0.2
0
0
10
20
30
Hall current (mA)
40
50
MITSUBISHI <CONTROL / DRIVER IC>
M56785FP
SPINDLE MOTOR DRIVER
APPLICATION CIRCUIT
Forward reverse
rotation signal
µcom control
BRAKING
MODE
SELECT
FG signal
12V
Motor
power
supply
0 to 1.5
10µF
15
16
6
7
36
37
4
3
5V
BRAKING
MODE
CHANGE
SENSE
FG
RDS
Hall bias
resistor
+
24
-
39
23
HU
104
104
-
40
+
26
120°
MATRIX
25
HV
104
+
28
-
41
27
HW
Hall
Bias
20
I/I
Converter
5
++
Motor current sense resistor
38
Vlim
0.5
19
18
V/I Converter
17
Control
PWM1
Start / Stop
2
TSD
104
Reference
PWM2
8 to 14 and 29 to 35
5V
Power
Supply
10µF
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