SANYO LB11691H

Ordering number : EN8314
LB11691H
Monolithic digital IC
Pre-Driver IC for Brushless
Motor Drive in Electric Bicycles
Overview
The LB11691H are three-phase bipolar PWM drive pre-driver ICs that allow the output circuits to be implemented using
only n-channel FETs. These ICs can implement, at low cost, high-efficiency drive circuits in applications that use motors
that require high drive currents. These ICs include a built-in Hall sensor signal F/V conversion circuit and can provide a
voltage that is proportional to motor speed for use, for example, in speedometers for electric bicycles. These ICs also
support use in applications that holds the speed controlled at a constant rate as the load varies.
Features
• Three-phase bipolar PWM drive (high and low side n-channel FET drive)
• Maximum supply voltage : 45V
• Gate drive voltage : about 10V (high and low side n-channel FETs)
• Hall sensor signal F/V conversion circuit (one-shot multivibrator output)
• Synthesized three-phase Hall sensor signal output
• Built-in current limiter and undervoltage protection circuits
Specifications
Absolute Maximum Ratings at Ta = 25°C
Parameter
Symbol
Supply voltage 1
VCC max
Supply voltage 2
Conditions
Ratings
Unit
VCC pin
45
V
VB max
VB pin
60
V
Output current 1-1
IO max1
UL, VL, and WL pins
50
mA
Output current 2-1
IO max2-1
UH, VH, and WH pins sink current
30
mA
Output current 2-2
IO max2-2
UH, VH, and WH pins source current
40
mA
RF pin application voltage
VRF max
4
V
LVS pin application voltage
VLVS max
60
V
Continued on next page.
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.
80807 MS PC B8-9097 No.8314-1/21
LB11691H
Continued from preceding page.
Parameter
Symbol
IN pin application voltage
Conditions
Ratings
V
VRES max
V5+0.3
V
TOC pin application voltage
VTOC max
V5+0.3
V
HSEL pin application voltage
VHSEL max
V5+0.3
V
F/R pin application voltage
VFR max
V5+0.3
V
EI+ pin application voltage
VEI+ max
V5+0.3
V
EI- pin application voltage
VEI- max
V5+0.3
V
RC pin application voltage
VRC max
V5+0.3
V
FV pin application voltage
VFV max
V5+0.3
V
HP pin application voltage
VHP max
45
V
VFAIL max
45
V
W
FAIL pin application voltage
IN1, IN2, and IN3 pins
Unit
V5+0.3
RES pin application voltage
VIN max
Allowable power dissipation 1
Pd max1
Independent IC
0.9
Allowable power dissipation 2
Pd max2
Mounted on a board. *
2.1
W
Operating temperature
Topr
-20 to +100
°C
Storage temperature
Tstg
-55 to +150
°C
3
* Mounted on a substrate : 114.3×76.1×1.6mm , glass epoxy board.
Allowable Operating Conditions at Ta = 25°C
Parameter
Symbol
Supply voltage range 1
VCC
Supply voltage range 2
VB
Conditions
Ratings
Unit
VCC pin
15 to 42
V
VB pin
VCC+13
V
Output current 1-1
IOUT1-1
UL, VL, and WL pins sink current
Output current 1-2
IOUT1-2
UL, VL, and WL pins source current
Output current 2-1
IOUT2-1
UH, VH, and WH pins sink current
Output current 2-2
IOUT2-2
UH, VH, and WH pins source current
12V constant-voltage output current
I12REG
5V constant-voltage output current
I5REG
45
mA
-45
mA
25
mA
-35
mA
-30
mA
-30
mA
HP pin application voltage
VHP
0 to 42
V
HP pin output current
IHP
0 to 5
mA
FAIL pin application voltage
VFAIL
0 to 42
V
FAIL pin output current
IFAIL
0 to 5
mA
Electrical Characteristics Ta = 25°C, VCC = 36V
Parameter
Symbol
Ratings
Conditions
min
Source current
ICC
typ
Unit
max
19
24
mA
5.0
5.3
V
mV
5V constant-voltage output (V5 pin)
Output voltage
V5REG
IO = -5mA
4.7
Voltage fluctuation
ΔV5REG1
VCC = 15 to 42V
40
100
Load fluctuation
ΔV5REG2
IO = -5 to -30mA
10
30
Temperature coefficient
ΔV5REG3
Design target value *
0
mV
mV/°C
12 V constant-voltage output (V12 pin)
Output voltage
12.0
12.8
V
Voltage fluctuation
ΔV12REG1
V12REG
IO = -5mA
VCC = 15 to 42V
11.2
120
240
mV
Load fluctuation
ΔV12REG2
IO = -5 to -30mA
10
30
Temperature coefficient
ΔV12REG3
Design target value *
0
mV
mV/°C
Output Block/Conditions : UOUT = VOUT = WOUT = 18V, VB = 48V applied
Output H-level voltage 1
VOH1
UL, VL, and WL pins IOH = -10mA
Output L-level voltage 1
VOL1
UL, VL, and WL pins IOL = 10mA
Output H-level voltage 2
VOH2
UH, VH, and WH pins IOH = -5mA
Output L-level voltage 2
VOL2
UH, VH, and WH pins IOH = 5mA
V12-1.2
V12-0.8
46.8
47.2
0.8
18.2
V
1.2
V
18.6
V
V
* : Design target values and not tested.
Continued on next page.
No.8314-2/21
LB11691H
Continued from preceding page.
Parameter
Symbol
Ratings
Conditions
min
typ
Unit
max
Charge pump output (VB pin)
Output voltage
VBOUT
46.0
48.0
VCC-1.9
VCC-1.4
50.5
V
CP1 pin
Output H-level voltage
VOH (CP1)
ICP1 = -2mA
Output L-level voltage
VOL (CP1)
ICP1 = 2mA
1.5
V
2.0
V
Integrating amplifier
Input offset voltage
Input bias current
VIO (CONT)
-10
10
mV
IB (CONT)
-1
1
μA
VICM
0
V5-1.7
V
Common-phase input voltage range
Output H-level voltage
VOH (CONT)
ITOC = -0.2mA
Output L-level voltage
VOL (CONT)
ITOC = 0.2mA
Open loop gain
f (CONT) = 1kHz
V5-1.1
V5-0.8
0.8
45
51
V
1.1
V
dB
PWM oscillator (PWM pin)
Output H-level voltage
VOH (PWM)
2.75
3.0
3.25
V
Output L-level voltage
VOL (PWM)
1.0
1.2
1.3
V
-35
-25
-19
μA
29
36
44
kHz
1.6
1.8
2.1
Vp-p
External C charge current
ICHG
Oscillation frequency
f (PWM)
Amplitude
V (PWM)
VPWM = 2.1V
C = 270pF
TOC pin
Input voltage 1
VTOC1
Output duty 100%
2.72
3.0
3.30
V
Input voltage 2
VTOC2
Output duty 0%
0.99
1.2
1.34
V
Input voltage 1L
VTOC1L
Design target value*, 100% at V5 = 4.7V
2.72
2.80
2.90
V
Input voltage 2L
VTOC2L
Design target value*, 0% at V5 = 4.7V
0.99
1.08
1.17
V
Input voltage 1H
VTOC1H
Design target value*, 100% at V5 = 5.3V
3.08
3.20
3.30
V
Input voltage 2H
VTOC2H
Design target value*, 0% at V5 = 5.3V
1.11
1.22
1.34
V
85
100
115
mV
Current limiting circuit (RF pin)
Limiter voltage
VRF
Low-voltage protective circuit (LVS pin)
Operating voltage
VSDL
3.65
3.85
4.05
V
Cancellation voltage
VSDH
4.15
4.35
4.55
V
Hysteresis width
ΔVSD
0.35
0.5
0.65
V
150
170
°C
40
°C
Heat shielding operation (overheat protection circuit)
Heat shielding operation
TSD
temperature
Hysteresis width
Design target value*
(junction temperature)
ΔTSD
Design target value*
(junction temperature)
CSD circuit (CSD pin)
Output H-level voltage
VOH (CSD)
Output L-level voltage
VOL (CSD)
3.2
3.6
4.0
V
0.9
1.1
1.3
V
External C charge current
ICHG1
VCSD = 2.35V
-14
-10
-6
μA
External C discharge current
ICHG2
VCSD = 2.35V
7
11
15
μA
Oscillation frequency
f (CSD)
C = 0.01μF
Amplitude
V (CSD)
2.2
2.5
2.75
Vp-p
Reset operating voltage
VRESL
1.17
1.27
1.37
V
Reset canceling voltage
VRESH
1.37
1.5
1.63
V
Hysteresis width
ΔVRES
0.20
0.23
0.26
V
0.15
0.5
V
10
μA
180
Hz
Reset circuit (RES pin)
HP pin
Output saturation voltage
Output leak current
VHPL
IHP leak
IO = 3mA
VHP = 42V
* : Design target values and not tested.
Continued on next page.
No.8314-3/21
LB11691H
Continued from preceding page.
Parameter
Symbol
Ratings
Conditions
min
Unit
typ
max
FAIL pin
Output saturation voltage
VFLL
Output leak current
IO = 3mA
IFL leak
0.15
VFAIL = 42V
0.5
V
10
μA
RC pin
Output H-level voltage
VOH (RC)
3.22
3.5
3.78
V
Output L-level voltage
VOL (RC)
0.72
0.8
0.88
V
Clamp voltage
VCLP (RC)
1.5
V
FV pin
Charge current
ICHG1
VFV = 2.5V
Discharge current
ICHG2
VFV = 1V
-420
-300
-230
μA
1.3
2.5
5.0
mA
IN1, IN2, and IN3 pins
H-level input voltage
VIH (IN)
4.0
V5
V
L-level input voltage
VIL (IN)
0
2.5
V
Input open voltage
VIO (IN)
V5-0.5
V5
V
Hysteresis width
VIS (IN)
H-level input current
IIH (IN)
VIN = V5
L-level input current
IIL (IN)
VIN = 0V
0.55
0.9
1.25
V
-10
0
10
μA
μA
-500
F/R pin
H-level input voltage
VIH (FR)
2.0
V5
V
L-level input voltage
VIL (FR)
0
1.0
V
Input open voltage
VIO (FR)
2.6
2.9
3.2
V
Hysteresis width
VIS (FR)
0.16
0.25
0.34
V
H-level input current
IIH (FR)
VF/R = V5
100
130
μA
L-level input current
IIL (FR)
VF/R = 0V
-170
μA
-130
HSEL pin
H-level input voltage
VIH (HSL)
2.0
L-level input voltage
VIL (HSL)
0
Input open voltage
VIO (HSL)
2.6
H-level input current
IIH (HSL)
VHSEL = V5
L-level input current
IIL (HSL)
VHSEL = 0V
-170
V5
V
1.0
V
2.9
3.2
V
100
130
μA
μA
-130
Package Dimensions
unit : mm (typ)
3235A
Pd max -- Ta
0.65
17.8
(6.2)
2.7
1
0.25
0.8
2.0
0.3
(2.25)
(0.5)
10.5
7.9
(4.9)
36
Allowable power dissipation, Pd max – W
2.4
2.1W
2.0
1.6
1.2
0.9W
Independent IC
0.84
0.8
0.4
0
– 20
2.45max
Mounted on a board : 114.3×76.1×1.6mm3
glass epoxy
0.36
0
20
40
60
80
100
120
0.1
Ambient temperature, Ta – °C
SANYO : HSOP36(375mil)
No.8314-4/21
LB11691H
Three-phase logic truth table
(1)120° (HSEL = “L”)
F/R = “L”
F/R = “H”
IN1
IN2
IN3
IN1
IN2
IN3
Upper side gate
Lower side gate
HP
H
L
H
L
H
L
VH
UL
H
1
2
H
L
L
L
H
H
WH
UL
L
3
H
H
L
L
L
H
WH
VL
H
4
L
H
L
H
L
H
UH
VL
L
5
L
H
H
H
L
L
UH
WL
H
6
L
L
H
H
H
L
VH
WL
L
Upper side gate
Lower side gate
HP
H
(2)60° (HSEL = “H”)
F/R = “L”
IN1
F/R = “H”
IN2
IN3
IN1
IN2
IN3
1
H
H
H
L
L
L
VH
UL
2
L
H
H
H
L
L
WH
UL
L
3
L
L
H
H
H
L
WH
VL
H
4
L
L
L
H
H
H
UH
VL
L
5
H
L
L
L
H
H
UH
WL
H
6
H
H
L
L
L
H
VH
WL
L
• The condition with the upper gate = VH and the lower gate = UL corresponds to a state in which the upper FET is
turned ON when the VH pin is connected and the lower FET is turned ON when the UL pin is connected.
• The HP output is an open collector output. Therefore, “H” level corresponds to an open state.
Pin Assignment
WH WOUT WL (NC) RF RFGND GND
36
35
34
33
32
31
30
VB VCC
29
28
V12
V5
27
26
LVS CP1 CP2
25
24
HP FAIL CSD RC
23
22
10
11
12
13
14
RES HSEL F/R (NC) EI+
15
EI-
21
20
19
16
17
18
LB11691H
1
VL
2
3
VOUT VH
4
UL
5
6
UOUT UH
7
8
9
IN1
IN2
IN3
TOC PWM FV
Top view
No.8314-5/21
LB11691H
Pin Functions
Pin No.
Pin Name
1
VL
4
UL
34
WL
2
VOUT
5
UOUT
35
WOUT
3
VH
6
UH
36
WH
7
IN1
8
IN2
Description
Lower Nch power FET gate drive output pins.
Upper Nch power FET source voltage detection pins.
Upper Nch power FET gate drive output pin.
Hall input pins. A capacitor is connected for stabilization between these pins and GND.
9
IN3
10
RES
Reset pin. A resistor is connected between this pin and V5 while a capacitor is connected between this pin and GND.
11
HSEL
Reset pin. Connect the resistance between this pin and V5 and the capacitor between this pin and GND.
12
F/R
Pin for changeover of the phase difference of three-phase Hall input (120° and 60°).
HSEL = “L” 120°, HSEL = “H” 60°
14
EI+
Integrating amplifier non-inverted input pin.
15
EI-
Integrating amplifier inverted input pin.
16
TOC
17
PWM
18
FV
19
RC
PWM waveform comparison pin (integrating amplifier output pin).
PWM oscillation frequency set pin. Connect a capacitor between this pin and GND.
Hall signal one-shot multi-pulse output.
One-shot multi-pulse width set pin. A resistor is connected between this pin and V5 while a capacitor is connected between this
pin and GND.
20
CSD
Pin to set the operation time of the lock protection circuit. Connect the capacitor between this pin and GND.
21
FAIL
Open collector output, with the output being “L” in following cases :
Abnormal Hall input, activation of the low-voltage protection circuit, activation of the lock protection circuit, and activation of the
overheat protection circuit.
22
HP
Hall signal three-phase composite output pin (open collector output).
23
CP2
Charge pump capacitor output pin. A capacitor is connected between CP1 and CP2.
24
CP1
25
LVS
Low-voltage protective voltage detection pin. A Zener diode is connected in series to set the detection voltage when the supply
voltage of 5V or more is to be detected.
26
V5
5V power pin (control circuit power supply). A capacitor is connected between this pin and GND.
27
V12
12V power pin (UL, VL, and WL output power supply). A capacitor is connected between this pin and GND.
28
VCC
Power pin. A capacitor is connected for stabilization between this pin and GND.
29
VB
30
GND
31
RFGND
32
RF
-
FRAME
Charge pump output pins (UH, VH, and WH output power supply). A capacitor is connected between this pin and VCC.
GND pin.
GND sensing pin, which is connected to the GND side of low-resistance RF connected to the RF pin.
Output current detection pin. Low-resistance RF is connected between RF and GND.
The output current is limited to the value set with IOUT = 0.1/RF. (Current limiting circuit)
This pin is connected internally with the metal in the bottom of IC.
Use both of them in the electrically open state.
13
NC
These can be used as wiring because they are not connected with the internal parts.
33
No.8314-6/21
LB11691H
Pin Description
Pin No.
Pin Name
Description
1
VL
Output pin
4
UL
(Gate driving output pin of lower Nch power FET)
34
WL
For duty control
Equivalent Circuit
V12
1
4 34
50kΩ
2
VOUT
Voltage detection pin
5
UOUT
(Source voltage detection pin of upper Nch power
35
WOUT
FET)
VB
3
6 36
2
5 35
50kΩ
3
VH
Output pin
(Gate driving output pin of lower Nch power FET)
6
UH
36
WH
7
IN1
Hall input pin
8
IN2
“H” in the open condition.
9
IN3
Connect a capacitor to GND for stabilization.
V5
8kΩ
10kΩ
2kΩ
7
10
RES
Reset pin
8
9
V5
300Ω
10
LVSD
11
HSEL
Pin to change over the phase difference of
three-phase Hall input
HSEL = “L” 120°
V5
30kΩ
HSEL = “H” 60°
5kΩ
11
40kΩ
Continued on next page.
No.8314-7/21
LB11691H
Continued from preceding page.
Pin No.
12
Pin Name
F/R
Description
Forward/backward input pin
Equivalent Circuit
V5
30kΩ
5kΩ
12
40kΩ
14
EI+
Integrating amplifier non-inverted input pin
15
EI-
Integrating amplifier inverted input pin
V5
14
300Ω
300Ω
15
RES
16
TOC
Integrating amplifier output pin
V5
(PWM waveform comparison pin)
16
300Ω
40kΩ
17
PWM
Pin to set the PWM oscillation frequency.
Connect a capacitor between this pin and GND.
V5
300Ω
17
7.5kΩ
18
FV
Hall signal one-shot multi-pulse output pin
V5
18
300Ω
Continued on next page.
No.8314-8/21
LB11691H
Continued from preceding page.
Pin No.
19
Pin Name
RC
Description
Equivalent Circuit
One-shot multi-pulse width setting pin
V5
Connect a resistor between this pin and V5 and a
capacitor between this pin and GND.
300Ω
20
CSD
Pin to set the PWM oscillation frequency.
Connect a capacitor between this pin and GND.
19
V5
300Ω
21
FAIL
Open collector output, with the output being “L” in
following cases :
20
V5
Abnormal Hall input, activation of the low-voltage
21
protection circuit, activation of the lock protection
circuit, and activation of the overheat protection circuit
22
HP
Hall signal three-phase composite output pin
V5
(Open collector output)
22
23
CP2
Charge pump capacitor connection pin
VCC
Connect a capacitor between CP1 and CP2.
50Ω
VB
24
CP1
300Ω
23
VCC
24
300Ω
Continued on next page.
No.8314-9/21
LB11691H
Continued from preceding page.
Pin No.
25
Pin Name
LVS
Description
Low-voltage protective voltage detection pin
When the 5V or more supply voltage is to be detected,
Equivalent Circuit
V5
connect Zener diode in series and set the detection
voltage.
46kΩ
25
18kΩ
26
V5
Stabilization power supply output pin
(5V output)
VCC
Connect a capacitor (about 0.1μF) between this pin
50Ω
and GND for stabilization
26
38kΩ
12.5kΩ
27
V12
Stabilization power supply output pin
(12V output)
VCC
Connect a capacitor (about 0.1μF) between this pin
50Ω
and GND for stabilization.
27
110kΩ
12.5kΩ
28
VCC
Power pin
Connect a capacitor (about 0.1μF) between this pin
and GND for stabilization
29
VB
Charge pump output pin
(UH, VH, and WH output power supply)
Connect a capacitor between this pin and VCC.
30
GND
GND pin
31
RF GND
Connected to GND of external Rf resistor.
V5
31
Continued on next page.
No.8314-10/21
LB11691H
Continued from preceding page.
Pin No.
32
Pin Name
RF
Description
Output current detection pin.
Connect the low resistance Rf between this pin and
Equivalent Circuit
V5
GND.
Set with the output maximum current
IOUT = 0.1/Rf.
32
FRAME
-
This pin is connected internally with the metal in the
bottom of IC. Use both of them in the electrically open
state.
13
33
NC
These can be used as wiring because they are not
connected with the internal parts.
No.8314-11/21
LB11691H
Description of LB11691H
1. Output drive circuit
This IC is designed on the prerequisite that NchFET is used for both upper and lower outputs. To minimize power loss
at the output, the direct PWM drive method is used. Output Tr is normally saturated at ON and the motor drive power is
adjusted by changing the ON-duty of the output. PWM switching of the output is made on the lower output side to
which UL, VL, and WL pins are connected. Diode built into the upper output FET on the non-PWM side should be
selected with care because the reverse recovery time is important (the through current flows in an instant when the
PWM side Tr is turned ON if the diode with the short reverse recovery time is not used).
Near each three-phase output FET, provide a capacitor to prevent
For oscillation prevention
high-frequency oscillation (about 0.1μF) because of substrate pattern
To VCC
routing.
UH pin
If the switching speed of FET is so high as to cause a problem, insert
a series resistor to the gate to adjust the speed. Through current may
UOUT pin
To motor coil
flow if the ON speed of lower FET on the PWM side is too fast.
However, insertion of excessively large resistor in the gate may make
UL pin
the gate waveform dull and the gate voltage may be deficient when
To RF
the PWM on-duty is small, resulting in heat generation or damage of
Means against
the lower FET. The same phenomena occur if the FET gate capacity
through current
is large even when the resistor has not been inserted. In this case, it is
necessary to limit the minimum duty to be used by taking into account ASO of the switching element to be used.
Depending on FET to be used, the through current may flow when the PWM on-duty is small. As a countermeasure, a
capacitor may be inserted between the gate and source of upper FET. Note that insertion of a capacitor with excessively
high capacitance may delay switching too much, resulting in heat generation in the upper FET.
2. Current limiting circuit
The current limiting circuit limits the current to the value determined by I = VRF/Rf (VRF = 0.1Vtyp, Rf : current
detection resistance) (that is, the peak current is limited). Current is limited by decreasing on-duty of the output.
Connection of RF and RFGND pins to both ends near the current detection
3kΩ
resistor ensures operation with the correct current limiting value.
RF pin
When the current detection resistor with extremely small resistance is to be
Current
1kΩ
detectiom
used, the pattern design must be such as to ensure the equal wiring resistance
resistor
RFGND pin
component by substrate pattern for all phases as much as possible. If the
wiring resistance component varies among phases, the current limit value
fluctuates each time the shift is changed, resulting in vibration or noise in the
motor.
RF pin
The reference voltage has been set to 0.1Vtyp to minimize the power of
Current
current detection resistor. In certain applications, enter the voltage divided by
detectiom
resistor
the resistor into RF pin when the current detection resistance is to be increased. RFGND pin
For the resistance ratio shown in the figure right, the detection current value
may be increased by about four times.
The current limiting circuit has a filter circuit so that erroneous current limiting is not made when the circuit detects the
reverse recovery current of the output diode because of PWM operation. In the normal application, the internal filter
circuit is allowed. If erroneous limiting occurs (if the reverse recovery current of diode flows for 1μS or more), it is
necessary to add the external filter circuit (R and C low-path filter). Note also that excessive delay may cause delay in
detection of current limiting.
3. PWM oscillation circuit
The PWM frequency is determined from a capacitor capacity C (F) to be connected to the PWM pin :
fPWM ≈ 1/ (102000×C)
Connection of a 270pF capacitor causes oscillation of about 36kHz. Excessively low PWM frequency causes a
switching sound from the motor while excessively high PWM frequency causes increase in the power loss at output.
Therefore, the PWM frequency of about 20k to 50kHz would be acceptable. Wire GND of a capacitor to be connected
as much near as possible to the GND pin of IC to prevent effects of output noise.
No.8314-12/21
LB11691H
4. Control method
The output duty is determined from comparison between the PWM oscillation waveform and TOC pin voltage. The
duty becomes 0% when the TOC pin voltage is about 1.2V or less and 100% when the pin voltage is about 3.0V or
more.
Normally, the integrating amplifier is used as a full return amplifier (EI- pin
Control voltage
TOC
and TOC pin connected) and the control voltage is entered to EI+ pin. (The
output duty increases with increasing EI+ pin voltage.) At resetting with the
RES pin, the EI+ pin is lowered approximately to the GND voltage by IC
EIinternal TR (for capacitor discharge). Therefore, always enter the voltage via
+
EI+
resistor, instead of direct connection of the low-impedance power. Also
connect a pull-down resistor between the EI+ pin and GND to prevent the
motor from being driven when the control voltage is open. When the control
voltage contains noise or in order to suppress sudden fluctuation of the control
To FV pin
voltage, connect a capacitor between the EI+ pin and GND to remove the
noise. The operating voltage range of control input can be widened by
TOC
entering the voltage divided by the resistor into the EI+ pin, as shown in the
figure right.
To perform control while keeping the rotation speed constant to a certain
EIControl voltage
degree under load fluctuation, the speed control circuit with FV pin output
+
EI+
may be formed as shown in the right. Select a 25kΩ or more resistance to be
inserted between FV and EI- pins. Select the return capacitor capacity so that
the TOC pin voltage is sufficiently stable at low speed.
5. Charge pump circuit
The voltage is raised by the charge pump circuit, generating the gate voltage of upper output FET. The voltage is raised
by a capacitor CP connected between CP1 and CP2 pins, accumulating the charge in the capacitor CB between VB and
VCC pins. The capacitance value of CP and CB must always have the following relationship :
CB ≥ 4 × CP
CP capacitor charge and discharge are made on the basis of PWM cycle. Though the VB power supply current capacity
increases with increasing capacity of the CP capacitor, excessively large capacity may cause faulty charge/discharge
operation. The VB voltage becomes more stable when the CB capacitor capacity is larger, but excessively large
capacity causes longer time of VB voltage generation at a time of power ON. Set the capacity of CP and CB by
referring to the table below.
When the VCC voltage decreases below 20V, the current capacity of VB power supply deteriorates suddenly, causing
drop of VB voltage. Therefore, due care must be taken when designing.
VCC voltage
24V
36V
CP
0.1μF
6800pF
CB
1μF
0.47μF
6. Hall input signal
Connect the Hall IC output to the Hall input. As an about 10kΩ pull-up
12V
resistor is incorporated for the 5V regulator, it is normally not necessary to Hall IC
5V LB11690
connect the pull-up resistor externally. If the Hall IC with built-in pull-up
resistor is used, it is enough to use the Hall IC power supply with 5V. If the
IN
Hall IC power supply is to be used with 12V, it is necessary to add the
pull-down resistor or voltage clamp Zener diode to prevent application of
voltage of 5V or more to the Hall input.
The input is a comparator input with about 0.9V hysteresis width. If the
noise presents problem, connect a noise removing capacitor between the
input and GND.
When three inputs of Hall input signal are in the same input condition, both upper and lower outputs are turned OFF.
No.8314-13/21
LB11691H
7. Low-voltage protective circuit
The low-voltage protective circuit performs detection using the voltage applied to the LVS pin and turns OFF all drive
outputs when the voltage drops below the operating voltage (3.85Vtyp). The circuit has hysteresis to prevent repetition
of ON/OFF near the protected operating voltage. The output is not recovered when the voltage does not rise by about
0.5V above the operating voltage. In the protection operation, the RES pin voltage
To detectiom
becomes “L” too.
power supply
The protection operating voltage is based on the 5V system detection level. To raise the
VZ
detection level, connect Zener diode in series to the LVS pin and shift the detection
LVS pin
level (detection voltage = 3.85Vtyp+Vz). The LVS pin inrush current at detection is
about 62μA. If it is necessary to stabilize rise of the Zener diode voltage and to suppress
fluctuation of the Zener voltage, insert a resistor between LVS pin and GND to increase
the diode current. The detection voltage may also be raised, without using Zener diode,
by resistive potential division. When connection as shown in the right is made ;
To detectiom
Detection voltage ≈ ((3.85 ÷ R2) + 62μA) × (R1+R2)
power supply
Cancellation voltage ≈ ((4.35 ÷ R2) + 70μA) × (R1+R2)
R1
With R1 = 13kΩ and R2 = 2.2kΩ, the detection voltage becomes about 28V while the
LVS pin
cancellation voltage becomes about 32V. Pay due attention when raising R2 because
the error of detection voltage may increase because of temperature and variance.
R2
When the protective circuit is not to be used, do not open the LVS pin (output OFF
when this is opened) and apply the voltage on an inoperative level.
8. RES circuit
Apply initial reset with the RES pin to ensure stable operation at power ON. Initial reset includes the following
operations :
• All drive outputs OFF
• EI+ pin voltage at “L”
• FV pin voltage at “L”
Normally, connect a resistor and capacitor between RES and V5 pins and between
To V5 pin
To control voltage
these pins and GND respectively and set the reset time. Use a 2.7kΩ or more
resistor. Set so that the time constant becomes R × C ≥ 1m (0.1μF or more if this is
10kΩ). If the charge of a capacitor connected to EI+ or FV pin must be completely RES pin
discharged, set the reset time by taking into account the discharge time of these
EI+pin
pins. It is also recommended to set the reset time longer than the time necessary for
stabilization of the VB voltage at power ON.
In addition to initial reset, reset may be applied when the control voltage is low as
Fig.1
shown in Fig. 1 in the right. In this case, all drive outputs can be turned OFF when
the control voltage becomes about 0.67V(1.27V - VBE). The reset cancellation
voltage is about 0.9V (0.67V+0.23V). If only the control voltage is 0% duty (1.2V
To V5 pin
or less), the motor is braked when driven in the reverse direction. This is an
effective application when braking is not necessary during reverse drive. If the
control voltage cannot be decreased to 1V or less, application as shown in Fig. 3
RES pin
may be used.
Heat detection with thermistor may also be considered to prevent thermal
breakdown of output FET. Connect as shown in Fig. 2 in the right and adjust the
external resistance, and the protective operation can be done. Fig. 4 shows a
Thermistor
combination of this application with thermistor and an application shown in Fig. 3. Fig.2
To V5 pin
Control voltage (1V to 4V)
RES
RES
10kΩ
10kΩ
EI+
EI+
47kΩ
47kΩ
Fig.3
Control voltage (1V to 4V)
Fig.4
No.8314-14/21
LB11691H
9. RC and FV circuits
The RC pin is to set the pulse width (“H” time) generated in the FV pin for both edges of HP signal (Hall three-phase
composite signal). Connect a resistor and capacitor between RS and VE pins and between this pin and GND
respectively and set the pulse width. The pulse width TRC can be approximated by the following equation.
TRC (S) ≈ 1.1 × R × C
To V5 pin
Connect the smoothing circuit comprising a resistor and capacitor, as shown in the right,
to the FV pin. Select the 25kΩ or more resistor. The capacitor must have the capacitance
ensuring sufficient smoothing of FV voltage when the motor rotation speed is low.
Assume that the HP signal frequency at the maximum motor speed is fHP (Hz). Set so RC pin
that the following equation is established :
TRC (S) ≤ 1 ÷ (2 × fHP)
In this case, the FV voltage changes from 0 to about 5V according to the motor speed.
FV voltage
The FV voltage can be used as a signal for speed meter indication of analog or level
FV pin
meter IC or speed return.
If FV output is not to be used, connect the RC pin to GND and keep the FV pin open.
10. Power stabilization
This IC is of a switching drive type, causing a state in which the power line is readily displaced. It is therefore necessary
to connect the capacitor with sufficient capacity between the VCC pin and GND for stabilization.
When a diode is to be inserted into the power line to prevent breakdown due to reverse connection of power supply, the
power line tends to be displaced readily. It is therefore necessary to select the larger capacity.
11. Stabilizing the regulator output voltage
Connect the capacitor of 0.1μF or more between V5 pin (5V : control circuit
power supply) or V12 pin (12V : lower drive output circuit power supply) and
GND. Wire the capacitor GND as near to IC GND pin as possible.
Each output can output the current of 30mA or less to the outside of IC. Due care
must be taken however because IC heat generation increases. If this is used in the
Hall IC power supply and presents a problem of heat generation, connect Tr as
shown in the right so that Tr receives heat generation.
VCC
V5 pin or
V12 pin
Hall IC power supply
12. Lock protection circuit
The lock protection circuit is incorporated to protect IC and motor when the motor is locked. When the Hall input
signal is not changed over for a certain period while the motor is being driven, the output on one side (UL, VL, WL) is
turned OFF. The time is set with the capacitor capacitance connected to the CSD pin.
Set time (s) ≈ 30 × C (μF)
Connection of the 0.01μF capacitor ensures the protection period of about 0.3 seconds (the drive is turned OFF when
one cycle of Hall input signal exceeds this set time). Be sure to set the time with sufficient allowance, so that the
protection circuit is not activated at normal motor startup. For the capacitor, use 4700pF or more. To cancel the lock
protection state, take any one of following steps :
• Resetting,
• Maintaining the output duty 0% state by TOC input for the period of tCSD × 2,
• Re-applying the power.
13. Forward/backward operation
For forward/backward changeover during running, the measure is taken to prevent through current at the output
(through current caused by the output Tr OFF delay time at a time of changeover). However, changeover during
running causes the current exceeding the current limit to flow through the output Tr due to the motor coil resistance and
motor counter electro-motive force. It is therefore necessary either to select the external output Tr that does not suffer
breakage by this current or to design changeover with the motor speed reduced to a certain degree.
14. FAIL Hall input
The output becomes “L” in following states with the open collector output :
• At abnormal Hall input
• When the low-voltage protection circuit is activated
• When the lock protection circuit is activated
• When the overheat protection circuit is activated
No.8314-15/21
LB11691H
15. HSEL
Phase difference (120° and 60°) can be changed over for the three-phase Hall input.
• HSEL = “L” 120°
• HSEL = “H” 60°
No.8314-16/21
LB11691H
Hall input – each output timing chart (For three-phase Hall input phase difference of 120°)
HSEL = "L"120°, F/R = "L"
Hall input
IN1
IN2
IN3
Pre output
UL
VL
WL
UH
VH
WH
Hall pulse output
HP
FV output
T≈1.1RC
Indicates the PWM output
HSEL = "L"120°, F/R = "H"
Hall input
IN1
IN2
IN3
Pre output
UL
VL
WL
UH
VH
WH
Hall pulse output
HP
FV output
T≈1.1RC
Indicates the PWM output
No.8314-17/21
LB11691H
Hall input – each output timing chart (For three-phase Hall input phase difference of 60°)
HSEL = "H"60°, F/R = "L"
Hall input
IN1
IN2
IN3
Pre output
UL
VL
WL
UH
VH
WH
Hall pulse output
HP
FV output
T≈1.1RC
Indicates the PWM output
HSEL = "H"60°, F/R = "H"
Hall input
IN1
IN2
IN3
Pre output
UL
VL
WL
UH
VH
WH
Hall pulse output
HP
FV output
T≈1.1RC
Indicates the PWM output
No.8314-18/21
Thermistor
V5
Speed
Control
RES
PWM
EI+
EI-
TOC
FAIL
RES
OSC
PWM
+
-
FAIL
FV
SD
OSC
RC
+
-
V12
F/R
F/R
VCC
ONE_SHOT
MULTI
CSD
TSD
LVSD
INVALID HALL
CSD
+
60°
/120°
60°
/120°
LVSD
HP
HP
V5
CP2
IN1
TSD
IN2
HYS COMP
HALL
HALL LOGIC
LOGIC
CONTROL
CHARGE
PUMP
CP1
IN3
5VREG
V5
V5
GND
LIM
CURR
DRIVER
PRE
RF
WL
WOUT
WH
VL
VOUT
VH
UL
UOUT
UH
LVS
VB
VCC
V12
RFGND
12VREG
Zener Diode
+
36V
LB11691H
Sample Application Circuit
No.8314-19/21
Thermistor
V5
Speed
Control
+
RES
PWM
EI+
EI-
TOC
FAIL
RES
PWM
OSC
+
-
FAIL
CSD
SD
OSC
RC
+
-
V12
F/R
F/R
VCC
ONE_SHOT
MULTI
CSD
TSD
LVSD
INVALID HALL
FV
60°
/120°
60°
/120°
LVSD
HP
HP
V5
CP2
IN1
TSD
IN2
HYS COMP
HALL
HALL LOGIC
LOGIC
CONTROL
CHARGE
PUMP
CP1
IN3
5VREG
V5
V5
GND
LIM
CURR
DRIVER
PRE
RF
WL
WOUT
WH
VL
VOUT
VH
UL
UOUT
UH
LVS
VB
VCC
V12
RFGND
12VREG
Zener Diode
+
36V
LB11691H
Sample Application Circuit
Sample Application (Closed Loop Speed Control)
No.8314-20/21
LB11691H
SANYO Semiconductor Co.,Ltd. assumes no responsibility for equipment failures that result from using
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.
products described or contained herein.
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
malfunction could give rise to accidents or events that could endanger human lives, trouble that could give rise
to smoke or fire, or accidents that could cause damage to other property. When designing equipment, adopt
safety measures so that these kinds of accidents or events cannot occur. Such measures include but are not
limited to protective circuits and error prevention circuits for safe design, redundant design, and structural
design.
In the event that any or all SANYO Semiconductor Co.,Ltd. products described or contained herein are
controlled under any of applicable local export control laws and regulations, such products may require the
export license from the authorities concerned in accordance with the above law.
No part of this publication may be reproduced or transmitted in any form or by any means, electronic or
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without the prior written consent of SANYO Semiconductor Co.,Ltd.
Any and all information described or contained herein are subject to change without notice due to
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
for volume production.
Upon using the technical information or products described herein, neither warranty nor license shall be granted
with regard to intellectual property rights or any other rights of SANYO Semiconductor Co.,Ltd. or any third
party. SANYO Semiconductor Co.,Ltd. shall not be liable for any claim or suits with regard to a third party's
intellctual property rights which has resulted from the use of the technical information and products mentioned
above.
This catalog provides information as of August, 2007. Specifications and information herein are subject
to change without notice.
PS No.8314-21/21