SANYO STK672-732B-E

Ordering number : ENA1931A
STK672-732B-E
Thick-Film Hybrid IC
2-phase Stepping Motor Driver
Overview
The STK672-732B-E is a hybrid IC for use as a unipolar, 2-phase stepping motor driver with PWM current control.
Applications
• Office photocopiers, printers, etc.
Features
• Built-in motor terminal open detection function (output current OFF).
• Built-in overcurrent detection function (output current OFF).
• Built-in overheat detection function (output current OFF).
• FAULT signal (active low) is output when any of motor terminal open, overcurrent, or overheat is detected.
The FAULT2 signal is used to output the result of activation of protection circuit detection at 3 levels.
• Built-in power on reset function.
• Phase signal input driver activated with an active Low and incorporates a simultaneous ON prevention function.
• Supports schmitt input for 2.5V high level input.
• Incorporating a current detection resistor (0.141Ω: resistor tolerance ±2%), motor current can be set using two
external resistors.
• Provides the output current cutoff ENABLE pin.
Any and all SANYO Semiconductor Co.,Ltd. products described or contained herein are, with regard to
"standard application", intended for the use as general electronics equipment (home appliances, AV equipment,
communication device, office equipment, industrial equipment etc.). The products mentioned herein shall not be
intended for use for any "special application" (medical equipment whose purpose is to sustain life, aerospace
instrument, nuclear control device, burning appliances, transportation machine, traffic signal system, safety
equipment etc.) that shall require extremely high level of reliability and can directly threaten human lives in case
of failure or malfunction of the product or may cause harm to human bodies, nor shall they grant any guarantee
thereof. If you should intend to use our products for applications outside the standard applications of our
customer who is considering such use and/or outside the scope of our intended standard applications, please
consult with us prior to the intended use. If there is no consultation or inquiry before the intended use, our
customer shall be solely responsible for the use.
Specifications of any and all SANYO Semiconductor Co.,Ltd. products described or contained herein stipulate
the performance, characteristics, and functions of the described products in the independent state, and are not
guarantees of the performance, characteristics, and functions of the described products as mounted in the
customer' s products or equipment. To verify symptoms and states that cannot be evaluated in an independent
device, the customer should always evaluate and test devices mounted in the customer' s products or
equipment.
70611HKPC 018-10-0062/32311HKPC No. A1931-1/23
STK672-732B-E
Specifications
Absolute Maximum Ratings at Tc = 25°C
Parameter
Symbol
Conditions
Ratings
unit
Maximum supply voltage 1
VCC max
No signal
50
V
Maximum supply voltage 2
VDD max
No signal
-0.3 to +6.0
V
Input voltage
VIN max
Logic input pins
-0.3 to +6.0
V
Output current 1
IOP max
10μs, 1 pulse (resistance load)
10
A
Output current 2
IOH max
VDD=5V, CLOCK≥200Hz
2.65
A
Output current 3
IOF max
Pin16 output current
10
Allowable power dissipation 1
PdMF max
With an arbitrarily large heat sink. Per MOSFET
7.3
W
Allowable power dissipation 2
PdPK max
No heat sink
2.8
W
Operating substrate temperature
Tc
Metal surface temperature of the package
-20 to +105
°C
Junction temperature
Tj max
150
°C
Storage temperature
Tstg
-40 to +125
°C
mA
Allowable Operating Ranges at Ta=25°C
Parameter
Symbol
Conditions
Ratings
unit
Operating supply voltage 1
VCC
With signals applied
0 to 46
V
Operating supply voltage 2
VDD
With signals applied
5±5%
V
Input high voltage
VIH
Pins 13, 17, 12, 10, 14, 15
2.5 to VDD
V
0 to 0.8
V
2.0
A
2.2
A
0.14 to 1.38
V
Input low voltage
VIL
Pins 13, 17, 12, 10, 14, 15
Output current 1
IOH1
Tc=105°C, CLOCK≥200Hz,
Continuous operation, duty=100%
Output current 2
IOH2
Tc=80°C, CLOCK≥200Hz,
Continuous operation, duty=100%,
See the motor current (IOH) derating curve
Recommended Vref range
Vref
(* CLOCK ≥ 200Hz is the same as 200pps or more.)
Electrical Characteristics at Tc=25°C, VCC=24V, VDD=5.0V
Parameter
Symbol
Conditions
VDD supply current
ICCO
Pin 9 current
Output average current
Ioave
R/L=1Ω/0.62mH in each phase
FET diode forward voltage
Vdf
If=1A (RL=23Ω)
Output saturation voltage
Vsat
RL=23Ω
Input high voltage
VIH
Pins 13, 17, 12, 10, 14, 15
Input low voltage
VIL
Pins 13, 17, 12, 10, 14, 15
FAULT1 low output voltage
VOLF
Pin 16 (IO=5mA)
5V level FAULT1 leakage
IILF
Pin 16=5V
VOF1
Pin 8 (when all protection functions have
min
typ
0.273
max
unit
5
8
0.329
0.385
A
0.92
1.6
V
0.33
0.48
V
2.5
mA
V
0.8
0.25
V
0.5
V
10
μA
current
FAULT2 Motor terminal open
0.00
0.01
0.20
VOF2
2.4
2.5
2.6
VOF3
3.1
3.3
3.5
50
75
been activated)
detection output voltage
FAULT2 Overcurrent detection
output voltage
FAULT2 Overheat detection
V
output voltage
5V level input current
IILH
Pins 13, 17, 12, 10, 14, 15=5V
GND level input current
IILL
Pins 13, 17, 12, 10, 14, 15=GND
Vref input bias current
IIB
Pin 19=1.0V
PWM frequency
fc
Overheat detection temperature
TSD
Design guarantee
Drain-source cut-off current
IDSS
VDS=100V, Pins 2, 6, 9, 18=GND
29
45
μA
10
μA
1
μA
61
kHz
1
μA
°C
144
* Operation at the maximum VCC value may not be possible, depending on the motor current. See “8. Other Notes on
Use” in the Data Sheet for details.
*Ioave values are for when the lead frame of the product is soldered to the mounting substrate.
Notes: A fixed-voltage power supply must be used.
No. A1931-2/23
STK672-732B-E
Package Dimensions
unit:mm (typ)
24.2
(18.4)
4.5
11.0
(11.0)
14.4
14.4
(R1.47)
19
(3.5)
1
1.0
0.4
0.5
2.0
18 1.0=18.0
4.0
4.45
Derating curve of motor current, IOH, vs. STK672-732B-E Operating substrate temperature, Tc
IOH - Tc
3.0
200Hz 2-phase excitation
Motor current, IOH - A
2.5
Hold mode
2.0
1.5
1.0
0.5
0
0
10
20
30
40
50
60
70
80
90
Operating Substrate Temperature, Tc- °C
100
110
ITF02548
Notes
• The current range given above represents conditions when output voltage is not in the avalanche state.
If the output voltage is in the avalanche state, see the allowable avalanche energy for STK672-7** series hybrid ICs given
in a separate document.
• The operating substrate temperature, Tc, given above is measured while the motor is operating.
Because Tc varies depending on the ambient temperature, Ta, the value of IOH, and the continuous or intermittent
operation of IOH, always verify this value using an actual set.
• The Tc temperature should be checked in the center of the metal surface of the product package.
No. A1931-3/23
STK672-732B-E
Block Diagram
VDD=5V
9
φBB 10
FAULT2
N.C
A
AB
B
BB
8
4
5
7
3
1
VDD
BBIN
F1
N.C 11 BIN
FAO
φAB 17
FAB
φB 12
FBO
φA 13
RESETB 14
ABIN
F3
F4
FBB
AIN
R1
Power
on
reset
Latch
circuit
Over current
detection
Latch
circuit
Output open
detection
R2
P.G2
ENABLE 15
FAULT1 16
F2
2
FAULT1
FAULT2
signal
P.G1
Current control
chopper
circuit
AI
6
BI
Vref/4.9
Over heat
detection
Vref
Latch
circuit
Amplifier
VSS
VSS
N.C 18
Vref 19
No. A1931-4/23
STK672-732B-E
Sample Application Circuit
STK672-732B-E
VDD(5V)
9
φA
13
φAB
17
φB
12
φBB
10
ENABLE
15
RESETB
R01
2 phase stepping motor driver
5
7
3
14
1
A
VCC
24V
AB
B
BB
+
R03
C01
at least 100μF
FAULT1
16
FAULT2
8
Vref
2
6
19
P.G2
P.GND
P.G1
18
R02
N.C
Precautions
[GND wiring]
• To reduce noise on the 5V system, be sure to place the GND of C01 in the circuit given above as close as possible to
Pin 2 and Pin 6 of the hybrid IC. Also, to achieve accurate current settings, be sure to connect Vref GND to the point
where P.G1 and P.G2 share a connection.
[Input pins]
• If VDD is being applied, use care that each input pin does not apply a negative voltage less than -0.3V to P.GND, and
do not apply a voltage greater than or equal to VDD voltage.
• Do not wire by connecting the circuit pattern on the P.C.B side to Pin 4, 11, or 18 on the N.C. shown in the internal
block diagram.
• Apply 2.5V high level input to pins 13, 17, 12, 10, 14, and 15.
• Since the input pins do not have built-in pull-up resistors, when the open-collector type pins 13, 17, 12, 10, 14, and 15
are used as inputs, a 1 to 20kΩ pull-up resistor (to VDD) must be used.
At this time, use a device for the open collector driver that has output current specifications that pull the voltage down
to less than 0.8V at Low level (less than 0.8V at Low level when IOL=5mA).
[Current setting Vref]
If the motor current is temporarily reduced, the circuit given below (STK672-732B-E : IOH>0.2A) is recommended.
5V
5V
R01
R01
Vref
Vref
R3
R02
R3
R02
No. A1931-5/23
STK672-732B-E
• Motor current peak value IOH setting
IOH
0
IOH=(Vref÷4.9) ÷Rs
The value of 4.9 in Equation above represents the Vref voltage as divided by a circuit inside the control IC.
Vref=(R02÷ (R01+R02)) ×5V(or 3.3V)
Rs is an internal current detection resistor value of the hybrid IC.
Rs=0.141Ω when using the STK672-732B-E
Input Pin Functions
Pin Name
Pin No.
Function
Input Conditions When Operating
φA
13
Pin 5, phase A output
Low active (with a function to prevent simultaneous
φAB
17
Pin 7, phase AB output
ON of φA and φAB, or φB and φBB)
φB
12
Pin 3, phase B output
φBB
10
Pin 1, phase BB output
RESETB
14
System reset
A reset is applied by a low level
ENABLE
15
A, AB, B, and, BB outputs cut off
A, AB, B, and BB outputs are cut off by a low level
Output Pin Functions
Pin Name
FAULT1
Pin No.
16
Function
Monitor pin when any of motor terminal open, overcurrent,
Input Conditions When Operating
Low level is output when detected.
or overheat is detected.
FAULT2
8
Monitor pin used when over-current detection or overheat
3 levels output
detection function is activated.
Note: See the timing chart for the concrete details on circuit operation.
No. A1931-6/23
STK672-732B-E
Timing Charts
2-phase excitation
VDD
Power on reset
(or RESETB)
φA
φAB
φB
φBB
ENABLE
FAO
FAB
FBO
FBB
1-2 phase excitation
VDD
Power on reset
(or RESETB)
φA
φAB
φB
φBB
ENABLE
FAO
FAB
FBO
FBB
No. A1931-7/23
STK672-732B-E
1-2 phase excitation (ENABLE)
VDD
Power on
reset
φA
φAB
φB
φBB
ENABLE
FAO
Output off
FAB
FBO
FBB
1-2 phase excitation (Hold operation results during fixed CLOCK)
VDD
Power on reset
(or RESETB)
φA
φAB
φB
φBB
ENABLE
Hold mode
FAO
FAB
FBO
FBB
No. A1931-8/23
STK672-732B-E
Usage Notes
1. STK672-732B-E Input signal functions and timing
[ENABLE, power on reset, and RESETB (Input signal timing when power is first applied)]
The control IC of the driver is equipped with a power on reset function capable of initializing internal IC operations
when power is supplied. A 4V typ setting is used for power on reset. Because the specification for the MOSFET gate
voltage is 5V±5%, conduction of current to output at the time of power on reset adds electromotive stress to the
MOSFET due to lack of gate voltage. To prevent electromotive stress, be sure to set ENABLE=Low while VDD,
which is outside the operating supply voltage, is less than 4.75V.
3.8V typ
4V typ
Control IC power (VDD) rising edge
Control IC power on reset
RESETB signal input
No time specification
ENABLE signal input
φA to φBB signal
No time specification
No time specification
ENABLE, φA to φBB Signals Input Timing
[ENABLE (Forcible on/off control of the A, AB, B, and BB outputs, and hybrid IC internal operation)]
ENABLE=1: Normal operation
ENABLE=0: Outputs A, AB, B, and BB forced to the off state.
If the φA to φBB signal used for motor rotation suddenly stops, the motor shaft may advance beyond the control
position due to inertia. A SLOW DOWN setting where the φA to φBB cycle gradually decreases is required in order to
stop at the control position.
No. A1931-9/23
STK672-732B-E
[Configuration of Each Input Pin]
<Configuration of the φA, φAB, φB, φBB,
ENABLE, and RESETB input pins>
<Configuration of the FAULT2 pin>
5V
Output pin
Pin 8
10kΩ
Input pin
5V
50kΩ
50kΩ
50kΩ
100kΩ
VSS
Motor terminal open
Overcurrent
Overheating
(The buffer has an open drain configuration.)
All input pins of this driver support schmitt input. Typ specifications at Tc = 25°C are given below. Hysteresis voltage
is 0.3V (VIHa-VILa).
When rising
When falling
1.8V typ
1.5V typ
Input voltage
VILa
VIHa
Input voltage specifications are as follows.
VIH=2.5V min
VIL=0.8V max
<Configuration of the Vref input pin>
<Configuration of the FAULT1 output pin>
5V
Output pin
Pin 16
Vref/4.9
−
Amplifier
VSS
Motor terminal open
Overcurrent
Overheating
+
Input pin
Pin 19
VSS
<FAULT1, FAULT2 output>
FAULT1 Output
FAULT1 is an open drain output. It outputs low level when any of motor terminal open, overcurrent, or overheat is
detected.
FAULT2 output
Output is resistance divided (3 levels) and the type of abnormality detected is converted to the corresponding output
voltage.
• Motor terminal open: 10mV (typ)
• Overcurrent: 2.5V (typ)
• Overheat: 3.3V (typ)
Abnormality detection can be released by a RESETB operation or turning VDD voltage on/off.
No. A1931-10/23
STK672-732B-E
2. STK672-732B-E overcurrent detection, overheat detection, and motor terminal open detection functions
Each detection function operates using a latch system and turns output off. Because a RESET signal is required to
restore output operations, once the power supply, VDD, is turned off, you must either again apply power on reset
with VDDON or apply a RESETB=High→Low→High signal.
[Motor terminal open detection]
This hybrid IC is equipped with a function for detecting open output terminals to prevent thermal destruction of the
MOSFET due to repeated avalanche operation that occurs when an output terminal connected to the motor is open.
The open condition is determined by checking the presence or absence of the flyback current that flows in the motor
inductance during the off period of the PWM cycle.
Detection is performed by using the fact that the flyback current does not flow when a motor terminal is open.
Terminal open
Used to set the motor current
Current detection
resistor voltage
0V (GND potential)
Used for open detection
(Negative current does not flow
when the terminal is open.)
MOSFET gate signal
PWM period
When the current level drops, the difference with the GND potential decreases, making detection difficult. The motor
current that can be detected by motor terminal open detection is 0.7A or more with the STK672-732B-E.
<Notes on the ENABLE high edge>
When ENABLE changes from low to high and the STK672-7XXB-E performs constant-current PWM operation
that flows a negative current during the 30μs period after the high edge, open detection may activate and stop the
driver.
The motor current setting voltage Vref must be set so that PWM operation is not performed within a period of 30μs
after the high edge.
If the motor current setup voltage is set for the rated motor current, PWM operation is not performed during this
30μs period after the high edge, so this is not a problem.
In addition, there is no problem with operation that lowers the current setting Vref after the motor rated current is
reached as shown in the diagram on the following page.
Whether constant-current PWM operation is performed during the 30μs period after the high edge can be judged by
substituting the motor L and R values into the formula on the following page.
Vref= (R02÷ (R01+R02)) ×5V (or 3.3V)
IOH1= (Vref÷4.9) ÷Rs
IOH1: Motor current value to be set
IOH2= (VCC÷R) × (1-e-tR/L)
IOH2: Current value 30μs after the ENABLE high edge
⇒ Judgment standard: IOH1>IOH2
R01, R02, 5V (or 3.3V): See the Sample Application Circuit documents.
Rs: Current detection resistance value (Ω)
VCC: Motor supply voltage (V)
R: Motor winding resistance (Ω)
L: Motor winding inductance (H)
⇒ There is no problem if the IOH2 obtained by substituting t = 30μs and the motor L and R values is smaller than
the current setting value IOH1.
No. A1931-11/23
STK672-732B-E
ENABLE
Vref
Output current
Constant-current PWM operation must not be performed for 30μs or less.
<Connection of capacitors between output pins and GND prohibited>
Capacitors must not be connected between the phase A (pin 5), phase AB (pin 7), phase B (pin 3) and phase BB
(pin 1) outputs and GND. What happens if capacitors are connected is that open-circuit detection may be triggered
by the discharge current of the capacitors when the internal MOSFET is set ON. This current is not an inductance
current generated by the motor winding but a capacitor current so a negative current will not flow to the other phase
in each pair of phases, possibly causing the driver to shut down.
<Excessive external noise>
If, when the motor current rises prior to the PWM operation, a spike-shaped current exceeding the Vref-setting
current is generated by excessive external noise, for instance, before the current level (0.7A for the STK672-732B-E
motor driver) at which motor pin open-circuiting can be detected is reached, the internal MOSFET is set OFF. Since
the MOSFET has been set OFF before the actual motor current reaches 0.7A, the level of the negative current
subsequently flowing to the other phase in each pair of phases is low, and it may be judged that no negative current
is flowing, possibly causing open-circuit detection to be triggered.
During normal constant-current PWM operation, the duration of 5.5μs, which is equivalent to 25% of the initial
operation in the PWM period, corresponds to the section where the current is not detected, and this ensures that no
current is detected for the linking part of the current that is generated in this section. The no-current detection
section is not synchronized at the current rise prior to the PWM operation so when a spike-shaped current exceeding
the Vref-setting current is generated, the MOSFET is set OFF at the stage where the level of the actual motor
current is low. As a result, the level of the negative current subsequently flowing to the other phase in each pair of
phases is low, and it may be judged that no negative current is flowing, possibly causing open-circuit detection to be
triggered.
Spike-shaped current
Vref setting
current (IOH)
Motor
current
Current level at
which opencircuiting is
detected
No-current detection time (5.5μs typ)
PWM period
No. A1931-12/23
STK672-732B-E
[Overcurrent detection]
This hybrid IC is equipped with a function for detecting overcurrent that arises when the motor burns out or when there
is a short between the motor terminals.
Overcurrent detection occurs at 3.5A typ with the STK672-732B-E
Current when motor terminals are shorted
PWM period
Set motor
current,
IOH
Over-current detection
IOH max
MOSFET all OFF
No detection interval
(5.5μs typ)
Normal operation
5.5μs typ
Operation when motor pins are shorted
Overcurrent detection begins after an interval of no detection (a dead time of 5.5μs typ) during the initial ringing part
during PWM operations. The no detection interval is a period of time where overcurrent is not detected even if the
current exceeds IOH.
[Overheat detection]
Rather than directly detecting the temperature of the semiconductor device, overheat detection detects the temperature
of the aluminum substrate (144°C typ).
Within the allowed operating range recommended in the specification manual, if a heat sink attached for the purpose of
reducing the operating substrate temperature, Tc, comes loose, the semiconductor can operate without breaking.
However, we cannot guarantee operations without breaking in the case of operations other than those recommended,
such as operations at a current exceeding IOH max that occurs before overcurrent detection is activated.
No. A1931-13/23
STK672-732B-E
3. Calculating STK672-732B-E HIC Internal Power Loss
The average internal power loss in each excitation mode of the STK672-732B-E can be calculated from the
following formulas.
Each excitation mode
2-phase excitation mode
2PdAVex= (Vsat+Vdf)× (1/ (t1+t2+t3))×IOH×t2+ (1/ (t1+t2+t3))×IOH× (Vsat×t1+Vdf×t3)
1-2 Phase excitation mode
1-2PdAVex= (Vsat+Vdf)× (1/ (t1+t2+t3))×IOH×t2+ (1/ (t1+t2+t3))×IOH× (Vsat×t1+Vdf×t3)
Motor hold mode
HoldPdAVex= (Vsat+Vdf)×IOH
Vsat: Combined voltage represented by the Ron voltage drop + shunt resistor
Vdf: Combined voltage represented by the MOSFET body diode + shunt resistor
t1, t2, and t3 represent the waveforms shown in the figure below.
t1: Time required for the winding current to reach the set current (IOH)
t2: Time in the constant current control (PWM) region
t3: Time from end of phase input signal until inverse current regeneration is complete
IOH
0A
t1
t2
t3
Motor COM Current Waveform Model
t1= (-L/(R+0.33)) ln (1-((R+0.33)/VCC) ×IOH)
t3= (-L/R) ln ((VCC+0.33)/(IOH×R+VCC+0.33))
VCC: Motor supply voltage (V)
L: Motor inductance (H)
R: Motor winding resistance (Ω)
IOH: Motor set output current crest value (A)
For Vsat and Vdf, be sure to substitute values from the graphs of Vsat vs. IOH and Vdf vs. IOH while the set current
value is IOH.
Then, determine whether a heat sink is required by comparing with the graph of ΔTc vs. Pd based on the average HIC
power loss calculated.
When designing a heat sink, refer to the section “Thermal design” found on the next page. The average HIC power
loss, PdAV, described above does not have the avalanche’s loss. To include the avalanche’s loss, be sure to add
Equation (2), “STK672-7** Allowable Avalanche Energy Value” to PdAV above. When using this IC without a fin
always check for temperature increases in the set, because the HIC substrate temperature, Tc, varies due to effects of
convection around the HIC.
No. A1931-14/23
STK672-732B-E
STK672-732B-E Output saturation voltage, Vsat - Output current, IOH
Vsat - IOH
05
°C
0.8
0.6
Tc
=1
Output saturation voltage, Vsat - V
1.0
°C
25
0.4
0.2
0
0
0.5
1.0
1.5
2.0
2.5
Output current, IOH - A
3.0
ITF02571
STK672-732B-E Forward voltage, Vdf -Output current, IOH
Vdf- IOH
1.4
Forward voltage, Vdf - V
1.2
25°C
Tc=
C
105°
1.0
0.8
0.6
0.4
0.2
0
0
0.5
1.0
1.5
2.0
2.5
Output current, IOH - A
3.0
ITF02572
Substrate temperature rise, ΔTc (no heat sink) - Internal average power dissipation, PdAV
ΔTc - PdAV
Substrate temperature rise, ΔTc - °C
80
70
60
50
40
30
20
10
0
0
0.5
1.0
1.5
2.0
2.5
Hybrid IC internal average power dissipation, PdAV - W
3.0
ITF02717
No. A1931-15/23
STK672-732B-E
4. STK672-732B-E Allowable Avalanche Energy Value
(1) Allowable Range in Avalanche Mode
When driving a 2-phase stepping motor with constant current chopping using an STK672-7** Series hybrid IC,
the waveforms shown in Figure 1 below result for the output current, ID, and voltage, VDS.
VDSS: Voltage during avalanche operations
VDS
IOH: Motor current peak value
IAVL: Current during avalanche operations
ID
tAVL: Time of avalanche operations
ITF02557
Figure 1 Output Current, ID, and Voltage, VDS, Waveforms 1 of the STK672-7** Series when
Driving a 2-Phase Stepping Motor with Constant Current Chopping
When operations of the MOSFET built into STK672-7** Series ICs is turned off for constant current chopping,
the ID signal falls like the waveform shown in the figure above. At this time, the output voltage, VDS, suddenly
rises due to electromagnetic induction generated by the motor coil.
In the case of voltage that rises suddenly, voltage is restricted by the MOSFET VDSS. Voltage restriction by
VDSS results in a MOSFET avalanche. During avalanche operations, ID flows and the instantaneous energy at
this time, EAVL1, is represented by Equation (1).
EAVL1=VDSS×IAVL×0.5×tAVL ------------------------------------------- (1)
VDSS: V units, IAVL: A units, tAVL: sec units
The coefficient 0.5 in Equation (1) is a constant required to convert the IAVL triangle wave to a
square wave.
During STK672-7** Series operations, the waveforms in the figure above repeat due to the constant current
chopping operation. The allowable avalanche energy, EAVL, is therefore represented by Equation (2) used to find
the average power loss, PAVL, during avalanche mode multiplied by the chopping frequency in Equation (1).
PAVL=VDSS×IAVL×0.5×tAVL×fc ------------------------------------------- (2)
fc: Hz units (fc is set to the PWM frequency of 50kHz.)
For VDSS, IAVL, and tAVL, be sure to actually operate the STK672-7** Series and substitute values when
operations are observed using an oscilloscope.
Ex. If VDSS=110V, IAVL=1A, tAVL=0.2μs when using a STK672-732B-E driver, the result is:
PAVL=110×1×0.5×0.2×10-6×50×103=0.55W
VDSS=110V is a value actually measured using an oscilloscope.
The allowable loss range for the allowable avalanche energy value, PAVL, is shown in the graph in Figure 3.
When examining the avalanche energy, be sure to actually drive a motor and observe the ID, VDSS, and tAVL
waveforms during operation, and then check that the result of calculating Equation (2) falls within the allowable
range for avalanche operations.
No. A1931-16/23
STK672-732B-E
(2) ID and VDSS Operating Waveforms in Non-avalanche Mode
Although the waveforms during avalanche mode are given in Figure 1, sometimes an avalanche does not result during
actual operations.
Factors causing avalanche are listed below.
• Poor coupling of the motor’s phase coils (electromagnetic coupling of A phase and AB phase, B phase and
BB phase).
• Increase in the lead inductance of the harness caused by the circuit pattern of the P.C. board and motor.
• Increases in VDSS, tAVL, and IAVL in Figure 1 due to an increase in the supply voltage from 24V to 36V.
If the factors above are negligible, the waveforms shown in Figure 1 become waveforms without avalanche as
shown in Figure 2.
Under operations shown in Figure 2, avalanche does not occur and there is no need to consider the allowable loss
range of PAVL shown in Figure 3.
VDS
IOH: Motor current peak value
ID
ITF02558
Figure 2 Output Current, ID, and Voltage, VDS, Waveforms 2 of the STK672-7** Series when Driving a
2-Phase Stepping Motor with Constant Current Chopping
Average power loss in the avalanche state, PAVL- W
Figure 3 Allowable Loss Range, PAVL-IOH During Avalanche Operations
PAVL - IOH
4.0
3.5
Tc=
80°
C
3.0
2.5
105
°C
2.0
1.5
1.0
0.5
0
0
0.5
1.0
1.5
Motor phase current, IOH - A
2.0
2.5
ITF02573
Note:
The operating conditions given above represent a loss when driving a 2-phase stepping motor with constant current
chopping.
Because it is possible to apply 2.6W or more at IOH=0A, be sure to avoid using the MOSFET body diode that is used
to drive the motor as a zener diode.
No. A1931-17/23
STK672-732B-E
5. Thermal design
[Operating range in which a heat sink is not used]
Use of a heat sink to lower the operating substrate temperature of the HIC (Hybrid IC) is effective in increasing the
quality of the HIC.
The size of heat sink for the HIC varies depending on the magnitude of the average power loss, PdAV, within the HIC.
The value of PdAV increases as the output current increases. To calculate PdAV, refer to “Calculating Internal HIC
Loss for the STK672-732B-E”.
Calculate the internal HIC loss, PdAV, assuming repeat operation such as shown in Figure 1 below, since conduction
during motor rotation and off time both exist during actual motor operations,
IO1
Motor phase current
(sink side)
IO2
0A
-IO1
T1
T2
T3
T0
Figure 1 Motor Current Timing
T1: Motor rotation operation time
T2: Motor hold operation time
T3: Motor current off time
T2 may be reduced, depending on the application.
T0: Single repeated motor operating cycle
IO1 and IO2: Motor current peak values
Due to the structure of motor windings, the phase current is a positive and negative current with a pulse form.
Note that figure 1 presents the concepts here, and that the on/off duty of the actual signals will differ.
The hybrid IC internal average power dissipation PdAV can be calculated from the following formula.
PdAV= (T1×P1+T2×P2+T3×0) ÷TO ---------------------------- (I)
(Here, P1 is the PdAV for IO1 and P2 is the PdAV for IO2)
If the value calculated using Equation (I) is 1.5W or less, and the ambient temperature, Ta, is 60°C or less, there is no
need to attach a heat sink. Refer to Figure 2 for operating substrate temperature data when no heat sink is used.
[Operating range in which a heat sink is used]
Although a heat sink is attached to lower Tc if PdAV increases, the resulting size can be found using the value of
θc-a in Equation (II) below and the graph depicted in Figure 3.
θc-a= (Tc max-Ta) ÷PdAV ---------------------------- (II)
Tc max: Maximum operating substrate temperature =105°C
Ta: HIC ambient temperature
Although a heat sink can be designed based on equations (I) and (II) above, be sure to mount the HIC in a set and
confirm that the substrate temperature, Tc, is 105°C or less.
The average HIC power loss, PdAV, described above represents the power loss when there is no avalanche operation.
To add the loss during avalanche operations, be sure to add Equation (2), “Allowable STK672-7** Avalanche Energy
Value”, to PdAV.
No. A1931-18/23
STK672-732B-E
Figure 2 Substrate temperature rise, ΔTc (no heat sink) - Internal average power dissipation, PdAV
ΔTc - PdAV
80
Substrate temperature rise, ΔTc - °C
70
60
50
40
30
20
10
0
0
0.5
1.0
1.5
2.0
2.5
3.0
Hybrid IC internal average power dissipation, PdAV - W
ITF02717
Figure 3 Heat sink area (Board thickness: 2mm) - θc-a
θc-a - S
Heat sink thermal resistance, θc-a - °C/W
100
7
5
3
2
Wi t
10
Wi t
7
5
ha
3
2
1.0
10
2
3
5
hn
o su
rfac
e fi
nish
flat
blac
k su
rfac
e fi
nish
7
2
100
3
5
7 1000
Heat sink area, S - cm2
ITF02554
6. Mitigated Curve of Package Power Loss, PdPK, vs. Ambient Temperature, Ta
Package power loss, PdPK, refers to the average internal power loss, PdAV, allowable without a heat sink.
The figure below represents the allowable power loss, PdPK, vs. fluctuations in the ambient temperature, Ta.
Power loss of up to 2.8W is allowable at Ta=25°C, and of up to 1.5W at Ta=60°C.
Allowable power dissipation, PdPK(no heat sink) - Ambient temperature, Ta
PdPK - Ta
Allowable power dissipation, PdPK - W
3.0
2.5
2.0
1.0
1.5
0.5
0
0
20
40
60
80
Ambient Temperature, Ta - °C
100
120
ITF02718
No. A1931-19/23
STK672-732B-E
7. Example of Stepping Motor Driver Output Current Path (1-2 phase excitation)
2-phase stepping motor
IOA
FAULT2
8
VDD=5V 9
φBB 10
N.C
4
AB
7
F2
F1
FAO
φAB 17
FAB
φA 13
A
5
B
3
BB
1
VDD
BBIN
N.C 11 BIN
φB 12
IOAB
F3
F4
VCC
24V
FBO
ABIN
FBB
C02
at least 100μF
AIN
R1
Power
on
reset
RESETB 14
Latch
circuit
Over current
detection
Latch
circuit
Output open
detection
P.G2
2
ENABLE 15
FAULT1 16
FAULT1
FAULT2
signal
AI
Current control
chopper circuit
R2
P.G1
6
P.GND
BI
Vref/4.9
Over heat
detection
N.C 18
Vref
Latch
circuit
Amplifier
VSS
VSS
Vref 19
φA(Pin 13)
φAB(Pin 17)
Phase A output current
IOA
PWM operations
Phase AB output current
When PWM operations of IOA
are OFF, for IOAB, negative
current flows through the
parasitic diode, F2.
IOAB
When PWM operations of IOAB are
OFF, for IOA, negative current flows
through the parasitic diode, F1.
No. A1931-20/23
STK672-732B-E
8. Other Notes on Use
In addition to the “Notes” indicated in the Sample Application Circuit, care should also be given to the following
contents during use.
(1) Allowable operating range
Operation of this product assumes use within the allowable operating range. If a supply voltage or an input
voltage outside the allowable operating range is applied, an overvoltage may damage the internal control IC or
the MOSFET.
If a voltage application mode that exceeds the allowable operating range is anticipated, connect a fuse or take
other measures to cut off power supply to the product.
(2) Input pins
If the input pins are connected directly to the PC board connectors, electrostatic discharge or other overvoltage
outside the specified range may be applied from the connectors and may damage the product. Current generated
by this overvoltage can be suppressed to effectively prevent damage by inserting 100Ω to 1kΩ resistors in lines
connected to the input pins.
Take measures such as inserting resistors in lines connected to the input pins.
(3) Power connectors
If the motor power supply VCC is applied by mistake without connecting the GND part of the power connector
when the product is operated, such as for test purposes, an overcurrent flows through the VCC decoupling
capacitor, C1, to the parasitic diode between the VDD of the internal control IC and GND, and may damage the
power supply pin block of the internal control IC.
To prevent destruction in this case, connect a 10Ω resistor to the VDD pin, or insert a diode between the VCC
decoupling capacitor C1 GND and the VDD pin.
Overcurrent protection measure: Insert a resistor.
VDD=5V
5V
Reg.
9
A
5
VDD
AB
7
F1
B
3
F2
BB
1
F3
F4
FAO
φA
FABO
FBO
φAB
FBBO
VCC
φB
φBB
R1
ENABLE
AI
RESETB
BI
R2
GND
2
C1
24V
Reg.
6
Vref
FAULT1
Vref
18
VSS
N.C
open
Overcurrent protection measure: Insert a diode.
Over-current path
(4) Input Signal Lines
1) Do not use an IC socket to mount the driver, and instead solder the driver directly to the PC board to minimize
fluctuations in the GND potential due to the influence of the resistance component and inductance component
of the GND pattern wiring.
2) To reduce noise caused by electromagnetic induction to small signal lines, do not design small signal lines
(sensor signal lines, and 5V or 3.3V power supply signal lines) that run parallel in close proximity to the motor
output line A (Pin 5), AB (Pin 7), B (Pin 3), or BB (Pin 1) phases.
3) Pin 4, 11 and Pin 18 of this product are N.C pins. Do not connect any wiring to these pins.
No. A1931-21/23
STK672-732B-E
(5) When mounting multiple drivers on a single PC board
When mounting multiple drivers on a single PC board, the GND design should mount a VCC decoupling
capacitor, C1, for each driver to stabilize the GND potential of the other drivers. The key wiring points are as
follows.
24V
5V
9
9
Motor
1
Input
9
Motor
2
Input
Motor
3
Input
IC2
IC1
IC3
2
2
6
6
2
6
19 18
19 18
19 18
GND
GND
Short
Thick
Thick and short
(6) VCC operating limit
When the output (for example F1) of a 2-phase stepping motor driver is turned OFF, the AB phase back
electromotive force eab produced by current flowing to the paired F2 parasitic diode is induced in the F1 side,
causing the output voltage VFB to become twice or more the VCC voltage. This is expressed by the following
formula.
VFB = VCC + eab
= VCC + VCC + IOH × RM + Vdf (1.5 V)
VCC: Motor supply voltage, IOH: Motor current set by Vref
Vdf: Voltage drop due to F2 parasitic diode and current detection resistor R1, RM: Motor winding resistance
value
Using the above formula, make sure that VFB is always less than the MOSFET withstand voltage of 100V. This
is because there is a possibility that operating limit of VCC falls below the allowable operating range of 46V, due
to the RM and IOH specifications.
VCC
VCC
AB phase
A phase
AB phase
A phase
eab
eab is generated by the
mutual induction M.
Current path
VFB
M
eab
F2
OFF
F1
ON
R1
GND
Current path
M
VCC
F2
OFF
F1
OFF
R1
GND
The oscillating voltage in excess of VFB is caused by LCRM (inductance, capacitor, resistor, mutual inductance)
oscillation that includes micro capacitors C, not present in the circuit. Since M is affected by the motor
characteristics, there is some difference in oscillating voltage according to the motor specifications. In addition,
constant voltage drive without constant current drive enables motor rotation at VCC > 0V.
No. A1931-22/23
STK672-732B-E
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products at values that exceed, even momentarily, rated values (such as maximum ratings, operating condition
ranges, or other parameters) listed in products specifications of any and all SANYO Semiconductor Co.,Ltd.
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SANYO Semiconductor Co.,Ltd. strives to supply high-quality high-reliability products, however, any and all
semiconductor products fail or malfunction with some probability. It is possible that these probabilistic failures or
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to smoke or fire, or accidents that could cause damage to other property. When designing equipment, adopt
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limited to protective circuits and error prevention circuits for safe design, redundant design, and structural
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product/technology improvement, etc. When designing equipment, refer to the "Delivery Specification" for the
SANYO Semiconductor Co.,Ltd. product that you intend to use.
Information (including circuit diagrams and circuit parameters) herein is for example only; it is not guaranteed
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This catalog provides information as of July, 2011. Specifications and information herein are subject
to change without notice.
PS No. A1931-23/23