LV8741V D

LV8741V
Bi-CMOS IC
PWM Current Control Stepper
Motor Driver
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Overview
The LV8741V is a 2-channel H-bridge driver IC that can switch a stepper
motor driver, which is capable of micro-step drive and supports
Quarter-step excitation, and two channels of a brushed motor driver,
which supports forward, reverse, brake, and standby of a motor. It is
ideally suited for driving brushed DC motors and stepper motors used in
office equipment and amusement applications.
Feature
SSOP44K (275mil)
 Single-channel PWM current control stepper motor driver (selectable
with DC motor driver channel 2) incorporated.
 BiCDMOS process IC
 On resistance (upper side : 0.5 ; lower side : 0.5 ; total of upper and
lower : 1.0 ; Ta = 25C, IO = 1.5A)
 Excitation mode can be set to Full-step, Half-step full torque, Half-step or Quarter-step
 Excitation step proceeds only by step signal input
 Motor current selectable in four steps
 IO max = 1.5A
 Output short-circuit protection circuit (selectable from latch-type or auto reset-type) incorporated
 Thermal shutdown circuit and power supply monitor circuit incorporated
 Support control power supply VCC = 2.7V to 5.5V
Typical Applications
 Stepper/Brush DC Motors
 Computing & Peripherals, Industrial
 Printers, Inkjet Printer, Multi-Function Printer
 Flatbed Scanner, Document Scanner
 Slot Machine, Vending Machine, Cash Machine
ORDERING INFORMATION
See detailed ordering and shipping information on page 28 of this data sheet.
© Semiconductor Components Industries, LLC, 2015
June 2015 - Rev. 2
1
Publication Order Number :
LV8741V/D
LV8741V
Specifications
Absolute Maximum Ratings at Ta = 25C
Parameter
Symbol
Supply voltage 1
VM max
Supply voltage 2
VCC max
Conditions
VM , VM1 , VM2
Output peak current
IO peak
tw  10ms, duty 20% , Per 1ch
Output current
IO max
Per 1ch
Logic input voltage
VIN
Ratings
ST , OE , DM , MD1/DC11 , MD2/DC12 ,
Unit
38
V
6
V
1.75
A
1.5
A
-0.3 to VCC+0.3
V
FR/DC21 , STP/DC22 , RST , EMM , ATT1 ,
ATT2
EMO input voltage
VEMO
Allowable power dissipation 1
Pd max1
Independent IC
Allowable power dissipation 2
Pd max2
*
-0.3 to VCC+0.3
V
0.55
W
2.9
W
Operating temperature
Topr
-20 to +85
C
Storage temperature
Tstg
-55 to +150
C
* Specified circuit board : 90901.7mm3 : glass epoxy printed circuit board with back mounting.
Caution 1) Absolute maximum ratings represent the value which cannot be exceeded for any length of time.
Caution 2) Even when the device is used within the range of absolute maximum ratings, as a result of continuous usage under high temperature, high current,
high voltage, or drastic temperature change, the reliability of the IC may be degraded. Please contact us for the further details.
Stresses exceeding those listed in the Maximum Ratings table may damage the device. If any of these limits are exceeded, device functionality should not be assumed,
damage may occur and reliability may be affected.
Recommended Operating Conditions at Ta = 25C
Parameter
Symbol
Supply voltage range 1
VM
Supply voltage range 2
VCC
VREF input voltage range
VREF
Logic voltage range
VIN
Conditions
VM , VM1 , VM2
ST , OE , DM , MD1/DC11 , MD2/DC12 ,
Ratings
Unit
9.5 to 35
V
2.7 to 5.5
V
0 to VCC-1.8
V
0 to VCC
V
FR/DC21 , STP/DC22 , RST , EMM , ATT1 ,
ATT2
Functional operation above the stresses listed in the Recommended Operating Ranges is not implied. Extended exposure to stresses beyond the Recommended
Operating Ranges limits may affect device reliability.
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LV8741V
Electrical Characteristics at Ta = 25°C, VM = 24V, VCC = 5V, VREF = 1.5V
Parameter
Symbol
Standby mode current drain 1
IMstn
Current drain 1
IM
Conditions
Ratings
min
typ
Unit
max
ST = ”L” , I(VM)+I(VM1)+I(VM2)
150
200
A
ST = ”H”, OE = ”H”, no load
0.75
1
mA
110
160
A
mA
I(VM)+I(VM1)+I(VM2)
Standby mode current drain 2
ICCstn
ST = ”L”
Current drain 2
ICC
ST = ”H”, OE = ”H”, no load
VCC low-voltage cutoff voltage
VthVCC
ST = ”H”, OE = ”H”, no load
Low-voltage hysteresis voltage
VthHIS
Thermal shutdown temperature
TSD
Design guarantee
180
C
Thermal hysteresis width
TSD
Design guarantee
40
C
Output on-resistance
Ronu
IO = 1.5A, Upper-side on resistance
0.5
0.7

Rond
IO = 1.5A, Lower-side on resistance
0.5
0.6

Output leakage current
IOleak
VM = 35V
50
A
Diode forward voltage 1
VD1
ID = -1.0A
1
1.3
V
Diode forward voltage 2
VD2
ID = -1.5A
Logic pin input current
IINL
ST , OE , DM , MD1/DC11 , MD2/DC12 ,
2.5
3
2.2
2.35
2.5
V
100
150
200
mV
1.1
1.5
V
3
8
15
A
ATT2 ,VIN = 0.8V
VIN = 5V
30
50
70
A
2.0
VCC
V
0
0.8
V
0.5
0.515
V
FR/DC21 , STP/DC22 , RST , EMM , ATT1 ,
IINH
Logic input
High
VINh
ST , OE , DM , MD1/DC11 , MD2/DC12 ,
voltage
Low
VINLl
FR/DC21 , STP/DC22 , RST , EMM , ATT1 ,
Current
Quarter step
Vtdac0_W
Step 0(When initialized : channel 1
selection
resolution
reference
voltage level
Half step
Vtdac1_W
Step 1 (Initial state+1)
0.485
0.5
0.515
V
Vtdac2_W
Step 2 (Initial state+2)
0.323
0.333
0.343
V
Vtdac3_W
Step 3 (Initial state+3)
0.155
0.167
0.179
V
Vtdac0_H
Step 0 (When initialized: channel 1
0.485
0.5
0.515
V
comparator level)
Vtdac2_H
Step 2 (Initial state+1)
0.323
0.333
0.343
V
Vtdac0_HF
Step 0 (Initial state, channel 1 comparator
0.485
0.5
0.515
V
level)
resolution
(full torque)
0.485
comparator level)
resolution
Half step
ATT2
Vtdac2_HF
Step 2 (Initial state+1)
0.485
0.5
0.515
V
Vtdac2_F
Step 2
0.485
0.5
0.515
V
Chopping frequency
Fchop
RCHOP = 20k
45
62.5
75
Current setting reference voltage
VRF00
ATT1 = L, ATT2 = L
0.485
0.5
0.515
V
VRF01
ATT1 = H, ATT2 = L
0.323
0.333
0.343
V
VRF10
ATT1 = L, ATT2 = H
0.237
0.25
0.263
V
VRF11
ATT1 = H, ATT2 = H
0.155
0.167
0.179
Iref
VREF = 1.5V
VREG5 output voltage
Vreg5
IO = -1mA
VG output voltage
VG
Rise time
tONG
Full step
resolution
VREF pin input current
kHz
V
A
-0.5
Charge pump
4.5
5
5.5
V
28
28.7
29.8
V
0.5
ms
125
150
kHz
50
100
mV
VG = 0.1F , Between CP1-CP2 0.1uF
ST=”H”→VG = VM+4V
Oscillator frequency
Fosc
RCHOP = 20k
90
Output short-circuit protection
EMO pin saturation voltage
Iemo = 1mA
Product parametric performance is indicated in the Electrical Characteristics for the listed test conditions, unless otherwise noted. Product performance may not be
indicated by the Electrical Characteristics if operated under different conditions.
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LV8741V
Package Dimensions
unit : mm
SSOP44K (275mil) Exposed Pad
CASE 940AF
ISSUE A
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4
LV8741V
1.00
SOLDERING FOOTPRINT*
(Unit: mm)
7.00
(3.5)
(4.7)
0.65
0.32
*For additional information on our Pb−Free strategy and soldering details, please download the ON Semiconductor
Soldering and Mounting Techniques Reference Manual, SOLDERRM/D.
GENERIC
MARKING DIAGRAM*
XXXXXXXXXX
YMDDD
XXXXX = Specific Device Code
Y = Year
M = Month
DDD = Additional Traceability Data
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5
LV8741V
4.0
3.0
Pd max - Ta
*1 With components mounted on the exposed die-pad board
*2 With no components mounted on the exposed die-pad board
Two-layer circuit board 1 *1
2.90
Two-layer circuit board 2 *2
2.0
2.05
1.51
1.07
1.0
0
-20
0
20
40
60
80
100
Substrate Specifications (Substrate recommended for operation of LV8741V)
Size
: 90mm × 90mm × 1.7mm (two-layer substrate [2S0P])
Material
: Glass epoxy
Copper wiring density : L1 = 90% / L2 = 95%
L1 : Copper wiring pattern diagram
L2 : Copper wiring pattern diagram
Cautions
1) The data for the case with the Exposed Die-Pad substrate mounted shows the values when 95% or more of the
Exposed Die-Pad is wet.
2) For the set design, employ the derating design with sufficient margin.
Stresses to be derated include the voltage, current, junction temperature, power loss, and mechanical stresses such as
vibration, impact, and tension.
Accordingly, the design must ensure these stresses to be as low or small as possible.
The guideline for ordinary derating is shown below :
(1)Maximum value 80% or less for the voltage rating
(2)Maximum value 80% or less for the current rating
(3)Maximum value 80% or less for the temperature rating
3) After the set design, be sure to verify the design with the actual product.
Confirm the solder joint state and verify also the reliability of solder joint for the Exposed Die-Pad, etc.
Any void or deterioration, if observed in the solder joint of these parts, causes deteriorated thermal conduction,
possibly resulting in thermal destruction of IC.
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LV8741V
Pin Assignment
CP2 1
44 VM
CP1 2
43 VG
VCC 3
42 PGND
VREG5 4
41 NC
ATT2 5
40 GND
ATT1 6
39 NC
NC 7
38 NC
EMO 8
37 OUT1A
CEM 9
36 VM1
EMM 10
35 RF1
RCHOP 11
MONI 12
34 OUT1B
LV8741V
33 OUT2A
RST 13
32 VM2
STP/DC22 14
31 RF2
FR/DC21 15
30 OUT2B
MD2/DC12 16
29 NC
NC 17
28 NC
MD1/DC11 18
27 GND
DM 19
26 NC
OE 20
25 NC
ST 21
24 NC
VREF 22
23 SGND
Top view
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7
MONI
PGND
VM
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8
+
GND
VCC
VREF
VREG5
+
-
LVS
TSD
+
-
RCHOP
Oscillation
circuit
Regulator
ATT2
Attenuator
(4 levels
selectable)
ST ATT1
Charge pump
Output preamplifier stage
RF1
OUT1B VM1
VM2 OUT2A
RF2
DM
EMM
Current set
(Full/Half/
Half full-torque/
Quarter)
Current set
(Full/Half/
Half full-torque/
Quarter)
MD1/ MD2/ FR/ STP/ RST OE
DC11 DC12 DC21 DC22
+
Output control logic
OUT2B
+
OUT1A
Output preamplifier stage
VG
Output preamplifier stage
CP1
Output preamplifier stage
CP2
CEM
EMO
LV8741V
Block Diagram
LV8741V
Pin Functions
Pin No.
Pin name
Description
36
VM1
Channel 1 motor power supply pin
37
OUT1A
Channel 1 OUTA output pin
34
OUT1B
Channel 1 OUTB output pin
35
RF1
Channel 1 current-sense resistor connection pin
32
VM2
Channel 2 motor power supply connection pin
33
OUT2A
Channel 2 OUTA output pin
30
OUT2B
Channel 2 OUTB output pin
31
RF2
Channel 2 current-sense resistor connection pin
42
PGND
Power system ground
12
MONI
Position detection monitor pin
14
STP/DC22
STM STEP signal input pin/DCM2 output control input pin
22
VREF
Constant current control reference voltage input pin
18
MD1/DC11
STM excitation mode switching pin/DCM1 output control input pin
16
MD2/DC12
STM excitation mode switching pin/DCM1 output control input pin
13
RST
Reset signal input pin
20
OE
Output enable signal input pin
15
FR/DC21
STM forward/reverse rotation signal input pin/DCM2 output control input pin
6
ATT1
Motor holding current switching pin
5
ATT2
Motor holding current switching pin
21
ST
Chip enable pin
44
VM
Motor power supply connection pin
Logic power supply connection pin
3
VCC
23
GND
Signal system ground
11
RCHOP
Chopping frequency setting resistor connection pin
19
DM
Drive mode (STM/DCM) switching pin
4
VREG5
Internal power supply capacitor connection pin
2
CP1
Charge pump capacitor connection pin
1
CP2
Charge pump capacitor connection pin
43
VG
Charge pump capacitor connection pin
8
EMO
Output short-circuit state warning output pin
10
EMM
Overcurrent mode switching pin
9
CEM
Pin to connect the output short-circuit state detection time setting capacitor
27,40
GND
Ground
7, 17, 24,
25, 26, 28,
NC
No Connection
(No internal connection to the IC)
29, 38, 39,
41
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LV8741V
Equivalent Circuits
Pin No.
Pin
5
ATT2
6
ATT1
10
EMM
13
RST
14
STP/DC22
15
FR/DC21
16
MD2/DC12
18
MD1/DC11
19
DM
20
OE
21
ST
Equivalent Circuit
VCC
5kΩ
100kΩ
GND
30
OUT2B
31
RF2
36
32
VM2
32
33
OUT2A
34
OUT1B
35
RF1
36
VM1
37
OUT1A
42
PGND
VCC
37 33
34 30
35
GND
42
1
CP2
2
CP1
43
VG
44
VM
2
31
44
1
43
100Ω
VREG5
GND
Continued on next page.
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LV8741V
Continued from preceding page.
Pin No.
22
Pin
VREF
Equivalent Circuit
VCC
500Ω
GND
4
VREG5
VM
2kΩ
78kΩ
26kΩ
GND
12
MONI
VCC
500Ω
GND
Continued on next page.
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LV8741V
Continued from preceding page.
Pin No.
8
Pin
Equivalent Circuit
EMO
VCC
GND
9
CEM
VCC
500Ω
GND
11
RCHOP
VCC
GND
1kΩ
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LV8741V
Description of operation
1. Input Pin Function
1-1) Chip enable function
This IC is switched between standby and operating mode by setting the ST pin. In standby mode, the IC is set to
power-save mode and all logic is reset. In addition, the internal regulator circuit and charge pump circuit do not
operate in standby mode.
ST
Mode
Internal regulator
Charge pump
Low or Open
Standby mode
Standby
Standby
High
Operating mode
Operating
Operating
1-2) Drive mode switching pin function
The IC drive mode is switched by setting the DM pin. In STM mode, stepper motor channel 1 can be controlled by the
CLK-IN input. In DCM mode, DC motor channel 2 or stepper motor channel 1 can be controlled by parallel input.
Stepper motor control using parallel input is Full-step or Half-step full torque.
DM
Drive mode
Application
Low or Open
STM mode
Stepper motor channel 1 (CLK-IN)
High
DCM mode
DC motor channel 2 or stepper motor channel 1 (parallel)
2.STM mode (DM = Low or Open)
2-1) STEP pin function
Input
Operating mode
ST
STP
Low
*
Standby mode
High
Excitation step proceeds
High
Excitation step is kept
2-2) Excitation mode setting function
MD1
MD2
Micro-step resolution
(Excitation mode)
Low
Low
High
Low
Initial position
Channel 1
Channel 2
Full step (2 phase excitation)
100%
-100%
Half step (1-2 phase excitation)
100%
0%
full torque
Low
High
Half step (1-2 phase excitation)
100%
0%
High
High
Quarter step
100%
0%
(W1-2 phase excitation)
This is the initial position of each excitation mode in the initial state after power-on and when the counter is reset.
2-3) Constant-current control reference voltage setting function
ATT1
ATT2
Current setting reference voltage
Low
Low
VREF/3100%
High
Low
VREF/367%
Low
High
VREF/350%
High
High
VREF/333%
The voltage input to the VREF pin can be switched to four-step settings as the reference voltage for setting the output current. This is effective for
reducing power consumption when motor holding current is supplied.
Set current value calculation method
The reference voltage is set by the voltage applied to the VREF pin and the two inputs ATT1 and ATT2. The output
current (output current at a constant-current drive current ratio of 100%) can be set from this reference voltage and the
RF resistance value.
IOUT = (VREF/3  Voltage setting ratio)/RF resistor
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LV8741V
(Example) When VREF = 0.66V, setting current ratio = 100% [(ATT1, ATT2) = (Low, Low)] and RF resistor =
0.22, the following output current flows :
IOUT = 0.66V/3  100%/0.22 = 1A
2-4) Input Timming
TstepH TstepL
STEP
Tdh
Tds
(md1 step) (step md1)
MD1
Tdh
Tds
(md2 step) (step md2)
MD2
Tdh
Tds
(fr step) (step fr)
FR
TstepH/TstepL : Clock H/L pulse width (min 500ns)
Tds : Data set-up time (min 500ns)
Tdh : Data hold time (min 500ns)
2-5) Blanking period
If, when exercising PWM constant-current chopping control over the motor current, the mode is switched from decay
to charge, the recovery current of the parasitic diode may flow to the current sensing resistance, causing noise to be
carried on the current sensing resistance pin, and this may result in erroneous detection. To prevent this erroneous
detection, a blanking period is provided to prevent the noise occurring during mode switching from being received.
During this period, the mode is not switched from charge to decay even if noise is carried on the current sensing
resistance pin. In the blanking time for this IC, it is fixed one sixteenth of chopping cycle.
2-6) Reset function
RST
Operating mode
High
Normal operation
Low
Reset state
RESET
RST
STEP
MONI
1ch output
0%
2ch output
Initial state
When the RST pin is set Low, the output excitation position is forced to the initial state, and the MONI output also
goes Low.
When RST is set High after that, the excitation position proceeds to the next STEP input.
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LV8741V
2-7) Output enable function
OE
Operating mode
Low
Output OFF
High
Output ON
OE
Power save mode
STEP
MONI
1ch output
0%
2ch output
Output is high-impedance
When the OE pin is set Low, the output is forced OFF and goes to high impedance.
However, the internal logic circuits are operating, so the excitation position proceeds when the STEP signal is input.
Therefore, when OE is returned to High, the output level conforms to the excitation position proceeded by the STEP
input.
2-8) Forward/reverse switching function
FR
Operating mode
Low
Clockwise (CW)
High
Counter-clockwise (CCW)
FR
CW mode
CCW mode
CW mode
STEP
Excitation position
(1)
(2)
(3)
(4)
(5)
(6)
(5)
(4)
(3)
(4)
(5)
1ch output
2ch output
The internal D/A converter proceeds by one bit at the rising edge of the input STEP pulse.
In addition, CW and CCW mode are switched by setting the FR pin.
In CW mode, the channel 2 current phase is delayed by 90° relative to the channel 1 current.
In CCW mode, the channel 2 current phase is advanced by 90° relative to the channel 1 current.
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LV8741V
2-9) Setting the chopping frequency
For constant-current control, chopping operation is made with the frequency determined by the external resistor
(connected to the RCHOP pin).
The chopping frequency to be set with the resistance connected to the RCHOP pin (pin 11) is as shown below.
Chopping frequency settings (reference data)
100
Fchop – kHz
80
60
40
20
0
0
10
20
30
RCHOP – kΩ
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40
50
60
PCA01883
LV8741V
2-10) Output current vector locus (one step is normalized to 90 degrees)
100.0
θ2 (Full-step/
Half-step
full torque)
θ4
Channel 1 phase current ratio (%)
θ3
66.7
θ2
33.3
θ1
θ0
0.0
0.0
33.3
66.7
100.0
Channel 2 current ratio (%)
Setting current ration in each micro-step mode
STEP
Quarter-step (%)
Channel 1
Half-step (%)
Channel 2
Channel 1
0
0
100
1
33.3
100
2
66.7
66.7
3
100
33.3
4
100
0
Half-step full torque (%)
Channel 2
Channel 1
Full-step (%)
Channel 2
Channel 1
0
100
0
100
66.7
66.7
100
100
100
0
100
0
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100
Channel 2
100
LV8741V
2-11) Examples of current waveform in each micro-step mode
Full step (CW mode)
STEP
MONI
(%)
100
l1
0
-100
(%)
100
I2
0
-100
Half step full torque (CW mode)
STEP
MONI
(%)
100
I1
0
-100
(%)
100
I2
0
-100
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LV8741V
Half step (CW mode)
STEP
MONI
(%)
100
I1
0
-100
(%)
100
I2
0
-100
Quarter step (CW mode)
STEP
MONI
(%)
100
I1
0
-100
(%)
100
I2
0
-100
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LV8741V
2-12) Current control operation specification
(Sine wave increasing direction)
STEP
Set current
Set current
Coil current
Forced CHARGE
section
fchop
Current mode CHARGE
SLOW
FAST
CHARGE
SLOW
FAST
(Sine wave decreasing direction)
STEP
Set current
Coil current
Forced CHARGE
section
Set current
fchop
Current mode CHARGE
SLOW
Forced CHARGE
section
FAST
FAST
CHARGE
SLOW
In each current mode, the operation sequence is as described below :
 At rise of chopping frequency, the CHARGE mode begins.(The section in which the CHARGE mode is forced
regardless of the magnitude of the coil current (ICOIL) and set current (IREF) exists for 1/16 of one chopping cycle.)
 The coil current (ICOIL) and set current (IREF) are compared in this forced CHARGE section.
When (ICOIL<IREF) state exists in the forced CHARGE section ;
CHARGE mode up to ICOIL  IREF, then followed by changeover to the SLOW DECAY mode, and finally
by the FAST DECAY mode for the 1/16 portion of one chopping cycle.
When (ICOIL<IREF) state does not exist in the forced CHARGE section;
The FAST DECAY mode begins. The coil current is attenuated in the FAST DECAY mode till one cycle of
chopping is over.
Above operations are repeated. Normally, the SLOW (+FAST) DECAY mode continues in the sine wave increasing
direction, then entering the FAST DECAY mode till the current is attenuated to the set level and followed by the SLOW
DECAY mode.
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LV8741V
3.DCM Mode (DM-High)
3-1) DCM mode output control logic
Parallel input
Output
Mode
DC11 (21)
DC12 (22)
OUT1 (2) A
OUT1 (2) B
Low
Low
OFF
OFF
Standby
High
Low
High
Low
CW (Forward)
Low
High
Low
High
CCW (Reverse)
High
High
Low
Low
Brake
3-2) Reset function
RST
Operating mode
MONI
High or Low
Reset operation not performed
High output
The reset function does not operate in DCM mode. In addition, the MONI output is High, regardless of the RST pin
state.
3-3) Output enable function
OE
Operating mode
Low
Output OFF
High
Output ON
When the OE pin is set Low, the output is forced OFF and goes to high impedance. When the OE pin is set High,
output conforms to the control logic.
3-4) Current limit control time chart
Set current
Current mode
Coil current
Forced CHARGE
section
fchop
Current mode
CHARGE
SLOW
3-5) Current limit reference voltage setting function
ATT1
ATT2
Current setting reference voltage
Low
Low
VREF/3100%
High
Low
VREF/367%
Low
High
VREF/350%
High
High
VREF/333%
The voltage input to the VREF pin can be switched to four-step settings as the reference voltage for setting the current limit.
Set current calculation method
The reference voltage is set by the voltage applied to the VREF pin and the two inputs ATT1 and ATT2. The current
limit can be set from this reference voltage and the RF resistance value.
Ilimit = (VREF/3  Current setting ratio) /RF resistance
(Example) When VREF = 0.66V, setting current ratio = 100% [(ATT1, ATT2) = (Low, Low)] and RNF1 (2) = 0.22,
the current limit value is as follows :
Ilimit = 0.66V/3  100%/0.22 = 1A
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LV8741V
3-6) Examples of current waveform in each micro-step mode when stepper motor parallel input control
Full step (CW mode)
DC11
DC12
DC21
DC22
(%)
100
lOUT1
0
-100
(%)
100
lOUT2
0
-100
Half step full torque (CW mode)
DC11
DC21
DC12
DC22
(%)
100
l1
0
-100
(%)
100
l2
0
-100
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LV8741V
4.Output short-circuit protection circuit
To protect the IC from damage due to short-circuit of the output caused by lightening or ground fault, the output
short-circuit protection circuit to put the output in standby mode and turn on the alarm output is incorporated. Note
that when the RF pin is short-circuited to GND, this output short-circuit protection is not effective against shorting to
power.
4-1) Output short-circuit protection mode switching function
Output short-circuit protection mode of IC can be switched by the setting of EMM pin.
EMM
State
Low or Open
Auto reset method
High
Latch method
4-2) Auto reset method
When the output current is below the output short-circuit protection current, the output is controlled by the input
signal. When the output current exceeds the detection current, the switching waveform as shown below appears
instead.
(When a 20k resistor is inserted between RCHOP and GND)
Exceeding the
over-current
detection
current
ON
OFF
ON
OFF
ON
Output current
1V
OCP voltage
Tscp
1 to 2μs
256μs (TYP)
When detecting the output short-circuit state, the short-circuit detection circuit is activated.
When the short-circuit detection circuit operation exceeds the timer latch time described later, the output is changed
over to the standby mode and reset to the ON mode again in 256s (TYP). In this event, if the overcurrent mode still
continues, the above switching mode is repeated till the overcurrent mode is canceled.
4-3) Latch method
Similarly to the case of automatic reset method, the short-circuit detection circuit is activated when it detects the
output short-circuit state.
When the short-circuit detection circuit operation exceeds the timer latch time described later, the output is changed
over to the standby mode.
In this method, latch is released by setting ST = “L”
4-4) Output short-circuit condition warning output pin
EMO, warning output pin of the output short-circuit protection circuit, is an open-drain output.
EMO outputs ON when output short-circuit is detected.
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LV8741V
4-5) Timer latch time (Tscp)
The time to output OFF when an output short-circuit occurs can be set by the capacitor connected between the CEM
pin and GND. The capacitor (C) value can be determined as follows :
Tscp  Td+C  V/I [sec]
Td : Internal delay time TYP 4s
V : Threshold voltage of comparator TYP 1V
I : CEM charge current TYP 2.5A
Timer latch : Tscp
The Tscp time must be set so as not to exceed 80% of the chopping period.
The CEN pin must be connected to (S) GND when the output short protection funtion is not to be used.
5.Charge Pump Circuit
When the ST pin is set High, the charge pump circuit operates and the VG pin voltage is boosted from the VM voltage
to the VM + VREG5 voltage. If the VG pin voltage is not boosted sufficiently, the output cannot be controlled, so be
sure to provide a wait time of tONG or more after setting the ST pin High before starting to drive the motor.
ST
VG pin voltage
VM+VREG5
VM+4V
VM
tONG
OE (STM mode)
High after the tONG wait time has elapsed
DC11, DC12, DC21 and DC22
(DCM mode)
VG Pin Voltage Schematic View
When controlling the stepping motor driver with the CLK-IN input, set the ST pin High, wait for the tONG time
duration or longer, and then set the OE pin High. In addition, when controlling the stepping motor and DC motor
driver with parallel input, set the ST pin High, wait for the tONG time duration or longer, and then start the control for
each channel.
6.Thermal shutdown function
The thermal shutdown circuit is included, and the output is turned off when junction temperature Tj exceeds 180°C
and the abnormal state warning output is turned on at the same time.
When the temperature falls hysteresis level, output is driven again (automatic restoration)
The thermal shutdown circuit doesn’t guarantee protection of the set and the destruction prevention of IC, because it
works at the temperature that is higher than rating (Tjmax=150°C) of the junction temperature
TTSD = 180°C (typ)
ΔTSD = 40°C (typ)
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LV8741V
7.Recommended Power-on Sequence
Provide a wait time of 10s or more after the VCC power supply rises before supplying the motor power supply.
Provide a wait time of 10s or more after the motor power supply rises before setting the ST pin High.
VCC
VM
10μs or longer
10μs or longer
ST
The above power-on sequence is only a recommendation, and there is no risk of damage to the IC even if this
sequence is not followed.
Notes on Board Design Layout
 Use thick GND lines and connect to GND stabilization points by the shortest distance possible to lower the
impedance.
 Use thick VM, VM1 and VM2 lines, and short-circuit these lines to each other by a short distance.
 Place the capacitors connected to VCC and VM as close to the IC as possible, and connect each capacitor to a
separate GND stabilization point using a thick independent line.
 Place the RF resistor as near to the IC as possible, and connect it to the GND stabilization point using a thick
independent line.
 When thermal radiation is necessary for the exposed die-pad on the bottom of the IC, solder it to GND. Also, do not
connect the exposed die-pad to other than GND.
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LV8741V
Application Circuits
 Stepper motor driver application circuit example
24V
+ 0.1μF
5V
- +
VM 44
2 CP1
VG 43
3 VCC
PGND 42
4 VREG5
0.1μF
47kΩ
Short-circuit state
detection monitor
1 CP2
5 ATT2
GND 40
6 ATT1
NC 39
7 NC
NC 38
OUT1A 37
9 CEM
VM1 36
10 EMM
RF1 35
LV8741V
8 EMO
12 MONI
Position detection monitor
13 RST
15 FR/DC21
Logic input
0.22Ω
OUT2A 33
VM2 32
RF2 31
0.22Ω
OUT2B 30
16 MD2/DC12
NC 29
17 NC
NC 28
18 MD1/DC11
0.66V
- +
M
OUT1B 34
14 STP/DC22
Clock input
0.1μF
NC 41
11 RCHOP
43kΩ
10μF
GND 27
19 DM
NC 26
20 OE
NC 25
21 ST
NC 24
22 VREF
GND 23
The setting conditions for the above circuit diagram example are as follows :
 Auto recovery-type output short-circuit protection function (EMM = High)
 Reset function fixed to normal operation (RST = High)
 Chopping frequency : 37kHz (RCHOP = 43k)
ATT1
ATT2
Current setting reference voltage
L
L
VREF/3×100%
H
L
VREF/3×67%
L
H
VREF/3×50%
H
H
VREF/3×33%
At the time of VREF = 0.66V, setting electric current ratio 100% [(ATT1, ATT2) =(L,L)], RF resistance 0.22,
the set current value is as follows.
IOUT = (VREF/3  Voltage setting ratio) /0.22
= (0.66/3  100 % / 0.22) = 1A
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LV8741V
 DC motor driver application circuit example
24V
+ -
0.1μF
5V
- +
47kΩ
2 CP1
VG 43
3 VCC
PGND 42
5 ATT2
GND 40
6 ATT1
NC 39
7 NC
NC 38
8 EMO
OUT1A 37
9 CEM
VM1 36
10 EMM
RF1 35
11 RCHOP
12 MONI
13 RST
14 STP/DC22
15 FR/DC21
Logic input
0.1μF
0.22Ω
OUT2A 33
VM2 32
RF2 31
M
0.22Ω
OUT2B 30
NC 29
17 NC
NC 28
GND 27
19 DM
NC 26
20 OE
NC 25
21 ST
NC 24
22 VREF
M
OUT1B 34
16 MD2/DC12
18 MD1/DC11
0.66V
- +
10μF
NC 41
LV8741V
20kΩ
VM 44
4 VREG5
0.1μF
Sort-circuit state
detection monitor
1 CP2
GND 23
The setting conditions for the above circuit diagram example are as follows :
At the time of VREF = 0.66V, setting electric current ratio 100% [(ATT1, ATT2) =(L,L)], RF resistance 0.22,
the current limit value is as follows .
IOUT = (VREF/3  Voltage setting ratio) /0.22
= (0.66/3  100 % / 0.22) = 1A
 Auto recovery-type output short-circuit protection function (EMM = High)
 Chopping frequency : 62.5kHz (RCHOP = 20k)
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LV8741V
ORDERING INFORMATION
Device
LV8741V-TLM-E
Package
SSOP44K (275mil)
(Pb-Free)
Shipping (Qty / Packing)
2000 / Tape & Reel
† For information on tape and reel specifications, including part orientation and tape sizes, please refer to our Tape and Reel
Packaging Specifications Brochure, BRD8011/D. http://www.onsemi.com/pub_link/Collateral/BRD8011-D.PDF
ON Semiconductor and the ON logo are registered trademarks of Semiconductor Components Industries, LLC (SCILLC) or its subsidiaries in the United States
and/or other countries. SCILLC owns the rights to a number of patents, trademarks, copyrights, trade secrets, and other intellectual property. A listing of
SCILLC’s product/patent coverage may be accessed at www.onsemi.com/site/pdf/Patent-Marking.pdf . SCILLC reserves the right to make changes without
further notice to any products herein. SCILLC makes no warranty, representation or guarantee regarding the suitability of its products for any particular purpose,
nor does SCILLC assume any liability arising out of the application or use of any product or circuit, and specifically disclaims any and all liability, including
without limitation special, consequential or incidental damages. “Typical” parameters which may be provided in SCILLC data sheets and/or specifications can
and do vary in different applications and actual performance may vary over time. All operating parameters, including “Typicals” must be validated for each
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not designed, intended, or authorized for use as components in systems intended for surgical implant into the body, or other applications intended to support or
sustain life, or for any other application in which the failure of the SCILLC product could create a situation where personal injury or death may occur. Should
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directly or indirectly, any claim of personal injury or death associated with such unintended or unauthorized use, even if such claim alleges that SCILLC was
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