RENESAS M63151FP

M63151FP
Polygon Scanner Motor Driver (DMOS Driver)
REJ03F0028-0100Z
Rev.1.0
Sep.16.2003
Description
The M63151FP is a driver and controller for use with three-phase brushless motor. A DMOS element with high
withstand voltage and low levels of switching loss is used on each output. Acceleration and deceleration inputs are
operable at TTL levels.
Features
•
•
•
•
•
•
•
Power-supply voltage (max.): 30 V
Output current (max.): 2.5 A
RDS (typ.): 140 Ω (total of the upper and lower DMOS FETs)
Built-in chip circuit for preventing through current in commutation
Built-in chip comparator for current detection
Buil-in chip overheating protection circuit
Built-in chip motor-lock protection circuit
Applications
• OA equipment such as LBPs, copiers, and fax machines
Block diagram
PS
TEST
Vboot
Hw
Hv
Hw+
Hv+
Hw-
Hv-
Hu
Hu+
VCC
HuRegulator
12V / 6V
VREG
cp2
cp1
Frequency
Generator
Power
Save
TSD
HallAmp
Motor Lock
Protection
PWM
PWM
ON/OFF
Synhro-PWM
CRLP
Pre - driver
MOTOR
ON/OFF
RLP
U
V
W
Charge
Pump
/ACC /DEC RCP
Rev.1.0, Sep.16.2003, page 1 of 13
CPout Pref
Rfc Cfc
RNF
RS
GND
M
M63151FP
Pin Functions
VCC
VREG
1
42
2
41
CP2
3
40
4
39
5
38
6
37
7
36
8
35
9
34
10
33
11
32
12
31
13
30
14
29
15
28
16
27
17
26
18
25
19
24
20
23
21
22
Vboot
NC
W
V
GND
N.C.
RS
U
RNF
GND
N.C.
HwHw+
Pref
CPout
/ACC
/DEC
RLP
CRLP
TEST
PS
GND
N.C.
Cfc
Rfc
RCP
Hu+
HuHv+
Hv-
Package outline (42P9R)
Description of Pin Functions
Pin
No.
Pin
Name
Description
Pin
No.
Pin
Name
Description
1
2
3
VCC
VREG
cp2
Motor power supply
Internal power supply
Pin 2 for connection of the step-up
voltage capacitor
42
41
40
Pref
CPout
/ ACC
PWM control voltage input
Charge-pump output
Input: request for acceleration
4
cp1
Pin 1 for connection of the step-up
voltage capacitor
39
/ DEC
Input: request for deceleration
5
Vboot
Stepped-up voltage power-supply
(internal)
38
RLP
Resistor connection pin for lock
protection
6
N.C.
Open
37
CRLP
Capacitor connection pin for lock
protection
7
W
W-phase drive output
29
N.C.
Open
8
V
V-phase drive output
36
TEST
Test pin (Tj detection)
9 to
13
GND
Ground
35
PS
Power-save switchover
14
N.C.
Open
30 to
34
GND
Ground
15
Rs
Output of detected current
28
Cfc
For connecting the resistor used to set
the PWM cycle
16
U
U-phase drive output
27
Rfc
For connecting the capacitor used to set
the PWM cycle
17
Rss
Current detection
26
RCP
Charge-pump output current setting
18
GND
Ground
25
Hu+
Hall signal input pin
19
N.C.
Open
24
Hu-
Hall signal input pin
20
Hw-
Hall signal input pin
23
Hv+
Hall signal input pin
21
Hw+
Hall signal input pin
22
Hv-
Hall signal input pin
Rev.1.0, Sep.16.2003, page 2 of 13
M63151FP
Absolute Maximum Ratings
(Ta = 25°C)
No.
Item
Symbol
Rated
Value
Unit
1
2
3
4
5
Power-supply voltage
Output current
Hall-sensor amp. differential input range
Voltage on input pins
Allowable dissipation
Vcc
lpeak
VHA
Vin
Pd
30
3.0
4.5
−0.3 to 7
2.5
V
A
V
V
W
6
7
Parameter for thermal derating
Conjunction temperature
Kθ
Tj
25
150
mW / °C
°C
8
Ambient temperature during operation
Ta
−20 to
°C
Remarks
/ ACC, / DEC, / PS, Pref
During start-up at Ta = 60°C,
with the device mounted on an iron
substrate
+75
9
Temperature during storage
Tstg
−40 to
°C
+125
Thermal derating
6.0
Allowable power dissipation (Pdp)
(W)
With the A-type board: 4.7 W
5.0
With the B-type board: 3.4 W
4.0
With the C-type board: 2.8 W
3.0
2.0
1.0
0
25
50
75
100
Ambient Temperature (Ta)
Note:
125
150
(˚C)
The large values for allowable power dissipation make it possible to use this device without a heat sink. At the
very least, dissipation of 2.8 W is possible with a glass-epoxy single-layered board, and 4.7 W is obtained by
applying special design measures to the board. For details on the configurations of boards A, B, and C, refer to
‘Boards used in the evaluation of thermal dating’ on page 11.
Rev.1.0, Sep.16.2003, page 3 of 13
M63151FP
Electrical Characteristics (DC)
(Unless otherwise noted, Ta = 25°C, Vcc = 24 V)
Item
Symbol
Rated Values
Unit
Conditions of Measurement and
Remarks
Min.
Typ.
Max.
Output DMOS on-resistance
RDS
—
1.40
2.20
Ω
Total of on-resistance for upper and lower
DMOS FET Iout = 1.0 A
Power-supply voltage range
Circuit current with no signal
RNF pin threshold voltage
Vcc
lcc
VRNF
21.6
—
212
24.0
5.4
250
26.4
10.0
288
V
mA
mV
PREF threshold voltage
Vpref
1.00
1.25
1.50
V
PREF voltage that satisfies RS current > 1
mA
/ACC input current H
/ACC input current L
IACCH
IACCL
–1.0
–50
—
–10
1.0
—
/ ACC = 5V
/ ACC = 0V
/DEC input current H
IDECH
—
250
500
/DEC input current L
Acceleration current
IDECL
ISS
–50
–240
–10
–200
—
–160
µA
µA
µA
µA
µA
Deceleration current
ISD
160
200
240
µA
/ ACC = Hi, / DEC = Lo, Rcp = 12KΩ at
CPout = 2.0 V
Detent current
IZ
–100
0
+100
nA
/ ACC =5V, / DEC = Hi or Lo, at
CPout =2.0 V
CPout output voltage range
VCPout
0.85
—
3.90
V
Less than the min. rated value when / ACC
= 5 V, / DEC = 0 V;
More than the max. rated value when /
ACC = 0 V, / DEC = 5 V
Output leakage current
I leak
–100
0
100
µA
Hall-sensor amp. same-phase
input voltage range
VHA1
1.5
—
Vcc–2
V
Hall-sensor amp input current
IHA
—
0.5
4.0
µA
Hµ+ = Hµ, Hv+ = Hv, Hw+ = Hw–
Hall-sensor amp input voltage
hysteresis
Vhys
6.95
11.0
15.45
mV
Between Hµ+ and Hµ–, Hv+ and Hv–, and
HW+ and HW-
Hall-sensor amp. min. input
amplitude for operation
VHA2
50
—
—
mV
Between Hµ+ and Hµ–, Hv+ and Hv–, and
Hw+ and Hw–;
The amplitude that satisfies phase delay <
5 deg for the above variation of hysteresis
voltage
PREF input current
IPref
–100
10
100
nA
Pref = 2.5 V
Rev.1.0, Sep.16.2003, page 4 of 13
PS = 0 V
/ ACC = 5V
/ ACC = 0V
/ ACC = Lo, / DEC = Hi, Rcp = 12KΩ at
CPout = 2.0 V
M63151FP
Electrical Characteristics (AC)
(Unless otherwise noted, Ta = 25°C, Vcc = 24 V)
Item
Symbol
Rated Values
Unit
Measurement Conditions and Remarks
Min.
Typ.
Max.
Delay from turning on
to output
Delay from turning off
to output
Tdon
—
1.0
1.5
µS
Tdoff
—
0.5
1.0
µS
Frequency of Fc
oscillation
Fc
17.3
21.6
25.9
KHz
When RfC = 24 KΩ , Cfc = 470 pF
Time for motor-lock
protection to operate
TML - ON
10.0
—
20.0
SEC
Between RLP and CRLP, 4.7 MΩ,
between CRLP and GNDE, 1 µF, load for
resistors U, V, W: 2R = 10 Ω
Time to resume after
motor-lock protection
TML - OFF
10.0
—
20.0
SEC
As above
Unit
Measurement Conditions and Remarks
Items for Confirmation in Evaluation
Item
Overheating shutdown
operating temperature
Overheating shutdown
temperature hysteresis
Symbol
Rated Values
Min.
Typ.
Max
TSG - ON
—
160
—
°C
TSD - OFF
—
30
—
°C
Temperature for resumption after reaching
the shutdown operating temperature
Note: Operation of the device within the above TSD operating temperature range is not guaranteed. The guaranteed
operation range of the device is up to Tjmax, that is, the absolute max. rating. The TSD operation is thus
activation of the thermal protection circuit when Tjmax has been exceeded by mistake. Accordingly, the device
must be operated at Tj = 150°C or below.
Rev.1.0, Sep.16.2003, page 5 of 13
M63151FP
Precautions during Use
Protection from overheating:
The impedance between the power supply and output pins of the circuit board is low when the IC is in use.
Contingencies such as the application of excessive voltage by voltage surges may lead to short-circuits forming
between the output pins of the IC can lead to damage which includes destruction of the TSD module. The chip is then
liable to catch fire. Accordingly, we strongly recommend that you consider the application of safety measures such as
fuses.
Dissipation of heat:
Sufficient thermal evaluation must be performed before changes to the thermal environment (including power-supply
voltage, output current, the circuit board, etc.). The new design must be brought within the margins for thermal
dissipation. Also, note that a higher carrier frequency setting leads to a larger level of IC-internal switching loss.
Wiring on the board:
Within the IC, the output current flows through the current-sense resistor (in the 0.17-Ω level), and current control is
applied when a fall in this voltage is detected. Also, since the flow of output current is for a high-speed switching
operation, take care to avoid the generation of crosstalk between the wiring which carries the current and the wiring
which is connected to the high-impedance input pins (Hall output), etc.
The motor-lock protection circuit:
Holding of the motor by some external or other factor leads to a continuous flow of the maximum current to the IC. The
IC is thus equipped with a module that detects this condition; at specified intervals after the condition has been
detected, the module stops the flow of current to the motor and automatically attempts to resumes operation. The time
constant set by the resistor and capacitor which are externally connected to pins 37 and 38 determines the time from
when the maximum current begins to flow until the motor is stopped; the same R and C values set the time from
stopping to restarting of the motor. Make sure that the specified interval is longer than the time the motor takes to start
up.
When the motor characteristics and setting for maximum current are such that the maximum current is exceeded when
the duty cycle is 75% (RS voltage high period: low period = 3:1) or more, the IC judges that the maximum current is
not continuously flowing. In such a case, this protection circuit does not operate.
If the IC junction temperature rises before or during the operation of this protective circuit, the overheat-protection
circuit operation takes precedence.
Short circuits between output pins and adjacent pins
This IC does not incorporate protection against short-circuits between pins. An attempt to output a current while there
is a short-circuit between an output and VCC or ground, an output and VREG, or VCC and VREG may cause an overcurrent to flow; this may adversely affect the IC.
Rev.1.0, Sep.16.2003, page 6 of 13
M63151FP
M63151FP PWM control method
A triangular waveform is output on the CFC pin under the control of the values of the external capacitor connected to
Cfc and the external resistor connected to Rfc. The PWM duty cycle is determined through comparison of this voltage
with the control voltage determined by the current output from CPout and the external filter connected to the CPout and
PREF pins, i.e. the voltage on PREF.
That is, PWM-ON is satisfied when the triangular waveform is at a level below the control voltage and PWM-OFF is
satisfied (regenerative) when the triangular waveform rises above the control voltage. How the relation between the
voltages on Cfc and Pref determines the output voltage is depicted below.
Cfc output voltage
VPREF (control voltage) →
PREF threshold voltage →
PWM - Duty cycle →
High:PWM - ON
Low:PWM - OFF
VPREF Operating range
Min.0.85 V less to max.4.00 V or more
(a) When VPREF < 1.25 V,
PWM duty cycle = 0% (always regennerative)
(b) When1.25 V < VPREF < 3.75 V, PWM control
(c) When3.75 V < VPREF, PWM duty cycle =100%
Cfc output waveform rage
Peak = 3.75 V
Trough = 1.25 V
(a) Minimum voltage: 1.25 V ±0.25 V
(b) Maximum voltage: 3.75 V ±0.25 V
VPREFthrehold voltage (VtPREF)
1.25V ± 0.25 V
(a) When VPREF< VtVPREF, motor ison
(b) When VPREF< VtVPREF, motor is always off.
While the motor is rotating, the Cfc output voltage is driven low with the same timing as switching of phase for the
motor in order to improve changes in the rotation speed.
Therefore, the voltage waveform output on Cfc during actual motor operation is as shown in the following figure.
Phase U
The dashed lines indicate
the timing of phase switching.
Phase V
Phase W
The hold line shows the PWM
output voltage wavform.
→ 3.75 V
VPREF
Cfc output voltage
→ 1.25 V
→ 0V
Rev.1.0, Sep.16.2003, page 7 of 13
M63151FP
Motor-Lock Protection Circuit (1)
As well as the overheating protection function, this IC incorporates a module that turns off current to the motor after the
motor has been mechanically held over a specified period. This prevents overheating. The operating conditions of this
module and a timing chart that depicts its operation are given below. Note, however, that when the IC does become
overheated, the overheating protection circuit still operates because it takes precedence over the lock protection
function.
(1) Conditions of operation
(a) The RS current detection resistor detects a continuous flow of the limit current (in practice, the current-limiting
circuit leaves the IC operating as long as the voltage on RS stays within the range 0 to 0.25 V).
(b) Normally, the period at 0 V in item (a) will be 3.5 µs, and this is approximately equal to the period at 0.25 V.
However, this circuit does not operate when motor characteristics, etc. mean that the period at 0.25 V is three times
the period at 0 V (duty cycle = 75%) or longer.
(c) The period of the lock-protection circuit operations (the period from locking of the motor to the time when current
to the motor is stopped) is determined by the time constant set up by the capacitor and resistor externally connected
to pins 37 (CRLP) and 38 (RLP).
(d) After the motor has been turned off, automatic resumption is attempted at a time determined by the same R and C
values as in point (c). External signals are not accepted until resumption.
(2) Block diagram
VREG(6V)
VREG
↓I1
Comp2
Comp1
A
+
RNF 17
C1
-
1V
0.25V
Current - Limiting
control signal
+
RFP
38
Hi: PWM-ON
Lo: PWM-OFF
(Regeneration)
R=4.7M Ω
CRLP
37
+
Lock protection
5.4V
or 4V
circuit control signal
1.2
Comp4
Hi: Normal operation
Low: MOTOR - lock protection circuit
0.25V
C=1µF
Comp3
RNF
0
POINT A
4V
1V
Current limiting
control signal
Comp3 output
0.7V
0
When the maximum current no longer flows to the RNF,
the CRLP voltage is driven low to cancel the protective finction.
5.4V
CRLP
Lock protection circuit
Currnt flows to
control signal
the motor
↑Initiation
Rev.1.0, Sep.16.2003, page 8 of 13
1.2V
Flow of current to
the motor stops
Currnt flows to
the motor
M63151FP
Motor Lock Protection Circuit (2)
The time intervals in the block diagram on the previous page are set up in the following ways.
(1) Current-limiting control signal low period
The flow of the limiting current to the RNF pin is detected, and the motor is regenaratively operated over the period
indicated below:
Toff = C1 x V1 ÷ LI
= 17.5pF x 1V ÷ 6.25 µA
= 2.8 µs
Note, however, that a delay time of about 0.5 µs from the time when the high-side or low-side of a phase is turned off
to the time when the output of the opposite side is turned on is set in the pre-drive stage of output. This prevents
through current to and from upper and lower transistors within the same phase. Accordingly, the output voltage off
period (regenerative time) is 0.5 µs plus the result of the above calculation, which is about 3.3 µs.
(2) Operation time of the motor-lock protection circuit
The following equation gives the time from locking of the motor to stoppage of current flow.
TML-ON = C x R x ln ((Vreg – R x I) ÷ ((Vreg – R x I) – V3))
= 1 µF x 4.7 MΩ x ln ((6 V – 4.7 MΩ x 17 nA ÷ ((6 V – 4.7 MΩ x 17 nA) – 5.4V))
= 11.42 s
Similarly, the period from the time when the motor is turned off to automatic resumption is:
TML-OFF = C x R x ln ((V3 – 0.7 V – R x I) ÷ (V4-7V))
= 1 µF x 4.7 MΩ x ln (5.4 V – 0.7 V – 4.7 MΩ x 17 nA ÷ 1.2 V – 0.7 V)
= 10.45 s
Rev.1.0, Sep.16.2003, page 9 of 13
M63151FP
Timing chart: motor output current / Hall input
Hall sensor input
Note: Hall sennsor input. Bold lines are positive phase.
Hu +
Hu−
Hv−
Hv +
Hw +
Output voltage (Duty cycle = 100%)
Hw−
Outward flow
U
Inward flow
Outward flow
V
Inward flow
Outward flow
W
Output voltage (Duty cycle = 30%)
Inward flow
Outward flow
U
Inward flow
Outward flow
V
Inward flow
Outward flow
W
Inward flow
0
180
360
540
Inward flow QE (degrees)
720
* : The above waveforms represent the tinming, and are not the same a
the waveforms seen in actual operation of the motor.
Rev.1.0, Sep.16.2003, page 10 of 13
M63151FP
Boards used in the evaluation of thermal derating
Board material
layer 1 [TOP view]
Glass-epoxy FR - 4
Size
70 × 70 mm
1
42
21
22
1
42
21
22
A - Typeboard
thickness
t = 1.6 mm
[layer 2]
1&2 layer
material: cupper
thichness: t = 18 µm
B - Typeboard
[layer 2]
1
42
21
22
C - Typeboard
[layer 1]
POWER-SSOP
TOP VIEW
BOTTOM VIEW
mounted
Evaluation board
Rev.1.0, Sep.16.2003, page 11 of 13
layer 2 [rear view]
M63151FP
Sample circuit application
100µF
1 VCC
PREF 42
0.03µF
24V
2 VREG
CPOUT41
300 K Ω
0.01µF
0.1µF
3 CP2
/ACC 40
4
CP1
/ D E C 39
5 Vboot
0.33µF
RLP 38
4.7MΩ
6
N.C.
CRLP 37
7 W
TEST 36
8 V
PS 35
1.0µF
0.167Ω
14 N.C.
N.C. 29
470pF
15 RS
Cfc
28
16 U
Rfc 27
17 RNF
RCP 26
18 GND
HU+ 25
19 N.C.
HU- 24
20 HW-
HV+ 23
21 HW+
HV - 2 2
1K Ω
24K Ω
100pF
HW
12K Ω
HV
HU
Rev.1.0, Sep.16.2003, page 12 of 13
HE
G
Z1
e
1
42
z
y
Detail G
D
b
21
22
JEDEC Code
−
x
M
A
Weight(g)
−
F
Detail F
A2
Lead Material
Cu Alloy
c
A1
A
A1
A2
b
c
D
E
e
HE
L
L1
z
Z1
x
y
Symbol
b2
e1
I2
b2
Dimension in Millimeters
Min
Nom
Max
−
−
2.2
0
0.1
0.2
−
−
2.0
0.27
0.32
0.37
0.23
0.25
0.3
17.5
17.3
17.7
8.4
8.6
8.2
−
−
0.8
12.23
11.93
11.63
0.7
0.5
0.3
−
−
1.765
−
−
0.75
−
0.9
−
−
−
0.16
−
−
0.1
−
0°
10°
−
−
0.5
−
−
11.43
−
−
1.27
Recommended Mount Pad
e
Plastic 42pin 450mil HSSOP
e1
MMP
L1
EIAJ Package Code
HSSOP42-P-450-0.8
E
Rev.1.0, Sep.16.2003, page 13 of 13
L
l2
42P9R-C
M63151FP
Package Dimensions
Sales Strategic Planning Div.
Nippon Bldg., 2-6-2, Ohte-machi, Chiyoda-ku, Tokyo 100-0004, Japan
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Renesas Technology (Shanghai) Co., Ltd.
26/F., Ruijin Building, No.205 Maoming Road (S), Shanghai 200020, China
Tel: <86> (21) 6472-1001, Fax: <86> (21) 6415-2952
Renesas Technology Singapore Pte. Ltd.
1, Harbour Front Avenue, #06-10, Keppel Bay Tower, Singapore 098632
Tel: <65> 6213-0200, Fax: <65> 6278-8001
© 2003. Renesas Technology Corp., All rights reserved. Printed in Japan.
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