ONSEMI LB11620T-TLM-E

Ordering number : ENA0662A
LB11620T
Monolithic Digital IC
Brushless Motor Driver
http://onsemi.com
Overview
The LB11620T is a direct PWM drive predriver IC that is optimal for three-phase power brushless motors. A motor
driver circuit with the desired output capability (voltage and current) can be implemented by adding discrete transistors
or other power devices to the outputs of this IC. Since the LB11620T is provided in a miniature package, it is also
appropriate for use with miniature motors as well.
Features
• Three-phase bipolar drive
• Direct PWM drive (input of either a control voltage or a variable-duty PWM signal)
• Built-in forward/reverse switching circuit
• Full complement of protection circuits (current limiter, low-voltage, and automatic recovery lock (motor constraint)
protection circuits)
• Selectable Hall sensor signal pulse output
Specifications
Maximum Ratings at Ta = 25°C
Parameter
Symbol
Conditions
Ratings
Unit
Supply voltage 1
VCC max
VCC pin
18
V
Output current
IO max
UL, VL, WL, UH, VH, WH pins
30
mA
Allowable power dissipation
Pd max
*Mounted on a circuit board.
0.8
W
Operating temperature
Topr
-20 to +100
°C
Storage temperature
Tstg
-55 to +150
°C
* Mounted on a circuit board : 114.3mm×76.1mm×1.6mm, glass epoxy board.
Stresses exceeding Maximum Ratings may damage the device. Maximum Ratings are stress ratings only. Functional operation above the Recommended Operating
Conditions is not implied. Extended exposure to stresses above the Recommended Operating Conditions may affect device reliability.
Semiconductor Components Industries, LLC, 2013
May, 2013
O0808 MS / 22807 MS PC 20061227-S00002 No.A0662-1/11
LB11620T
Recommended Operating Ranges at Ta = 25°C
Parameter
Symbol
Conditions
Ratings
Unit
Supply voltage range 1-1
VCC1-1
VCC pin
Supply voltage range 1-2
VCC1-2
VCC pin, with VCC shorted to VREG
8 to 17
Output current
IO
UL, VL, WL, UH, VH, WH pins
5 V constant voltage output current
IREG
HP pin voltage
VHP
0 to 17
V
HP pin output current
IHP
0 to 15
mA
RD pin voltage
VRD
0 to 17
V
RD pin output current
IRD
0 to 15
mA
4.5 to 5.5
V
V
25
mA
-30
mA
Electrical Characteristics at Ta = 25°C, VCC = 12V
Parameter
Symbol
Ratings
Conditions
min
Supply voltage 1
typ
ICC1
Unit
max
12
16
mA
5V constant voltage output (VREG pin)
Output voltage
VREG
5.0
5.3
V
Line regulation
ΔVREG1
VCC = 8 to 17V
4.7
40
100
mV
Load regulation
ΔVREG2
IO = -5 to -20mA
10
30
mV
Temperature coefficient
ΔVREG3
Design target
0
mV/°C
Low-voltage protection circuit (VREG pin)
Operating voltage
VSDL
3.5
3.7
3.9
V
Clear voltage
VSDH
3.95
4.15
4.35
V
Hysteresis
ΔVSD
0.3
0.45
0.6
V
0.2
0.5
V
0.9
1.2
V
10
μA
Output Block
Output voltage 1-1
VOUT1-1
Low level IO = 400μA
Output voltage 1-2
VOUT1-2
Low level IO = 10mA
Output voltage 2
VOUT2
High level IO = -20mA
Output leakage current
IOleak
VCC-1.1
VCC-0.9
V
Hall Amplifier Block
Input bias current
IHB (HA)
Common-mode input voltage range 1
VICM1
Common-mode input voltage range 2
VICM2
-2
When a Hall effect sensor is used
For single-sided input bias
μA
-0.5
0.5
VCC-2.0
V
0
VCC
V
(Hall IC application)
Hall input sensitivity
80
mVp-p
Hysteresis
ΔVIN (HA)
15
24
40
mV
Input voltage low → high
VSLH (HA)
5
12
20
mV
Input voltage high → low
VSHL (HA)
-20
-12
-5
mV
PWM Oscillator (PWM pin)
High-level output voltage
VOH (PWM)
2.75
3.0
3.25
V
Low-level output voltage
VOL (PWM)
1.2
1.35
1.5
V
External capacitor charge current
ICHG
VPWM = 2.1V
-120
-90
-65
μA
Oscillator frequency
f (PWM)
C = 2000pF
Amplitude
V (PWM)
1.4
1.6
1.9
Vp-p
22
kHz
Continued on next page
No.A0662-2/11
LB11620T
Continued from preceding page.
Parameter
Symbol
Ratings
Conditions
min
typ
Unit
max
EI+ pin
-1
1
μA
0
VREG-1.7
V
Input bias current
IB (CTL)
Common-mode input voltage range
VICM
Input voltage 1
VCTL1
Output duty 100%
3.0
V
Input voltage 2
VCTL2
Output duty 0%
1.35
V
Input voltage 1L
VCTL1L
Design target value.
2.82
V
1.29
V
3.18
V
1.44
V
When VREG = 4.7V, 100%
Input voltage 2L
VCTL2L
Design target value.
When VREG = 4.7V, 0%
Input voltage 1H
VCTL1H
Design target value.
When VREG = 5.3V, 100%
Input voltage 2H
VCTL2H
Design target value.
When VREG = 5.3V, 0%
HP pin
Output saturation voltage
VHPL
IO = 10mA
Output leakage current
IHPleak
VO = 18V
0.2
0.5
V
10
μA
CSD oscillator (CSD pin)
High-level output voltage
VOH (CSD)
2.7
3.0
3.3
V
Low-level output voltage
VOL (CSD)
0.7
1.0
1.3
V
External capacitor charge current
ICHG1
VCSD = 2V
-3.15
-2.5
-1.85
μA
External capacitor discharge current
ICHG2
VCSD = 2V
0.1
0.14
0.18
Charge/discharge current ratio
RCSD
Charge current /discharge current
15
18
21
Low-level output voltage
VRDL
IO = 10mA
0.2
0.5
V
Output leakage current
IL (RD)
VO = 18V
10
μA
VRF
RF-GND
0.275
V
μA
Times
RD pin
Current limiter circuit (RF pin)
Limiter voltage
0.225
0.25
PWMIN pin
Input frequency
f (PI)
50
kHz
High-level input voltage
VIH (PI)
2.0
VREG
V
Low-level input voltage
VIL (PI)
0
1.0
V
Input open voltage
VIO (PI)
VREG-0.5
VREG
V
Hysteresis
VIS (PI)
High-level input current
IIH (PI)
VPWMIN = VREG
Low-level input current
IIL (PI)
VPWMIN = 0V
0.2
0.25
0.4
V
-10
0
10
μA
-130
-90
μA
F/R pin
High-level input voltage
VIH (FR)
2.0
VREG
V
Low-level input voltage
VIL (FR)
0
1.0
V
Input open voltage
VIO (FR)
VREG-0.5
Hysteresis
VIS (FR)
0.2
High-level input current
IIH (FR)
Low-level input current
IIL (FR)
High-level input voltage
VIH (N1)
2.0
VREG
V
Low-level input voltage
VIL (N1)
0
1.0
V
Input open voltage
VIO (N1)
High-level input current
IIH (N1)
VN1 = VREG
Low-level input current
IIL (N1)
VN1 = 0V
VREG
V
0.25
0.4
V
-10
0
10
μA
-130
-90
μA
N1 pin
VREG-0.5
-10
0
-130
-100
VREG
V
10
μA
μA
No.A0662-3/11
LB11620T
Package Dimensions
unit : mm (typ)
3260A
Pd max – Ta
Allowable power dissipation, Pd max – W
1.2
6.5
0.5
6.4
13
4.4
24
12
1
0.5
0.15
0.22
(1.0)
1.2max
(0.5)
0.8
Specified circuit board : 114.3×76.1×1.6mm3
glass epoxy board
Mounted on a circuit board
0.4
0.32
0.08
0
– 20
0
20
40
60
80
100
120
Ambient temperature, Ta – °C
SANYO : TSSOP24(225mil)
Pin Assignment
VCC
VREG
EI+
N1
HP
F/R
24
23
22
21
20
19
RD
PWM
IN3+
IN3-
17
16
15
14
13
PWMIN CSD
18
LB11620T
1
2
3
4
5
6
7
8
9
10
11
12
GND
RF
WH
WL
VH
VL
UH
UL
IN1-
IN1+
IN2-
IN2+
• Three-Phase Logic Truth Table (IN = “H” indicates the state where IN+ > IN-)
F/R = “L”
F/R=“H”
Output
IN1
IN2
IN3
IN1
IN2
IN3
PWM
1
H
L
H
L
H
L
VH
UL
2
H
L
L
L
H
H
WH
UL
3
H
H
L
L
L
H
WH
VL
4
L
H
L
H
L
H
UH
VL
5
L
H
H
H
L
L
UH
WL
6
L
L
H
H
H
L
VH
WL
• PWMIN pin
Input state
State
High or open
Output off
Low
Output on
If the PWM pin is not used, the input must be held at the low level.
• N1 pin
Input state
HP output
High or open
Three Hall sensor synthesized output
Low
Single Hall sensor output
No.A0662-4/11
LB11620T
Pin Functions
Pin No.
Pin
1
GND
2
RF
Description
Ground
Output current detection. The current detection resistor (Rf) voltage is sensed by the RF pin to implement current
detection.
The maximum output current is set by RF to be IOUT = 0.25/Rf.
7
UH
Outputs (PWM outputs).
5
VH
These are push-pull outputs.
3
WH
8
UL
Outputs
6
VL
These are push-pull outputs.
4
WL
IN1+, IN1-
10, 9
14, 13
IN2+, IN2IN3+, IN3-
15
PWM
12, 11
Hall sensor inputs from each motor phase.
The logic high state indicates that IN+ > IN-.
If inputs are provided by a Hall effect sensor IC, the common-mode input range is expanded by biasing either the + or input.
Functions as both the PWM oscillator frequency setting pin and the initial reset pulse setting pin. Connect a capacitor
between this pin and ground.
16
RD
Lock (motor constrained) detection state output. This output is turned on when the motor is turning and off when the lock
protection function detects that the motor has been stopped. This is an open collector output.
17
CSD
Sets the operating time for the lock protection circuit.
Connect a capacitor between this pin and ground. Connect this pin to ground if the lock protection function is not used.
18
PWMIN
PWM pulse signal input. The output goes to the drive state when this pin is low, and to the off state when this pin is high
or open. To use this pin for control, a CTL amplifier input such that the TOC pin voltage goes to the 100% duty state
must be provided.
19
F/R
Forward/reverse control input
20
HP
Hall signal output (HP output). This provides either a single Hall sensor output or a synthesized 3-sensor output.
21
N1
Hall signal output (HP output) selection
22
EI+
CTL amplifier + (noninverting) input. The PWMIN pin must be held at the low level to use this input for motor control
23
VREG
5V regulator output (Used as the control circuit power supply. A low-voltage protection circuit is built in.)
Connect a capacitor between this pin and ground for stabilization.
24
VCC
Power supply. Connect a capacitor between this pin and ground to prevent noise and other disturbances from affecting
this IC.
No.A0662-5/11
LB11620T
Hall Sensor Signal Input/Output Timing Chart
F/R = " L "
IN1
IN2
IN3
UH
VH
WH
UL
VL
WL
F/R = " H "
IN1
IN2
IN3
UH
VH
WH
UL
VL
WL
Sections shown in gray are PWM output periods.
No.A0662-6/11
CTL
HP
VREG
PWMIN
PWM
EI+
PWM
IN
PWM
OSC
+
-
F/R
F/R
IN1
N1
COMP
VCC
IN1+ IN1-
HP
LOGIC
RD
RD
VREG
LVSD
IN2+ IN2-
IN3+ IN3-
HALL
HYS AMP
HALL LOGIC
CONTROL
LOGIC
CSD
OSC
CSD
+
GND
CURR
LIM
PRI
DRIVER
VREG
RF
WL
WH
VL
VH
UL
UH
VCC
VREG
+
5V
+
VM
LB11620T
Block Diagram and Application Example 1
Bipolar transistor drive (high side PWM)
using a 5V power supply
No.A0662-7/11
HP
VREG
PWMIN
PWM
EI+
PWM
IN
PWM
OSC
+
-
F/R
F/R
IN1
N1
COMP
VCC
IN1+ IN1-
HP
LOGIC
RD
RD
VREG
LVSD
IN2+ IN2-
IN3+ IN3-
HALL
HYS AMP
HALL LOGIC
CONTROL
LOGIC
CSD
OSC
CSD
+
GND
CURR
LIM
PRI
DRIVER
VREG
RF
WH
WL
VH
VL
UH
UL
VCC
VREG
Tr
Tr
Tr
+
VM(12V)
LB11620T
Application Example 2
54 MOS transistor drive (low side PWM)
using a 12V single-voltage power supply
No.A0662-8/11
HP
VREG
PWMIN
PWM
EI+
PWM
IN
PWM
OSC
+
-
F/R
F/R
IN1
N1
COMP
VCC
IN1+ IN1-
HP
LOGIC
RD
RD
VREG
LVSD
IN2+ IN2-
IN3+ IN3-
HALL
HYS AMP
HALL LOGIC
CONTROL
LOGIC
CSD
OSC
CSD
+
GND
CURR
LIM
PRI
DRIVER
VREG
RF
WH
WL
VH
VL
UH
UL
VCC
VREG
+
VCC(12V)
+
VM(24V)
LB11620T
Application Example 3
MOS transistor drive (low side PWM)
using a VCC = 12V, VM = 24V power supply system
No.A0662-9/11
HP
VREG
PWMIN
PWM
EI+
PWM
IN
PWM
OSC
+
-
F/R
F/R
IN1
N1
COMP
VCC
IN1+ IN1-
HP
LOGIC
RD
RD
VREG
LVSD
IN2+ IN2-
IN3+ IN3-
HALL
HYS AMP
HALL LOGIC
CONTROL
LOGIC
CSD
OSC
CSD
+
GND
CURR
LIM
PRI
DRIVER
VREG
RF
WH
WL
VH
VL
UH
UL
VCC
VREG
+
VM(24V)
LB11620T
Application Example 4
MOS transistor drive (low side PWM)
using a 24V single-voltage power supply
No.A0662-10/11
LB11620T
LB11620T Functional Description
1. Output Drive Circuit
The LB11620T adopts direct PWM drive to minimize power loss in the outputs. The output transistors are always
saturated when on, and the motor drive power is adjusted by changing the on duty of the output. The output PWM
switching is performed on the UH, VH, and WH outputs. Since the UL to WL and UH to WH outputs have the same
output form, applications can select either low side PWM or high side PWM drive by changing the way the external
output transistors are connected. Since the reverse recovery time of the diodes connected to the non-PWM side of the
outputs is a problem, these devices must be selected with care. (This is because through currents will flow at the instant
the PWM side transistors turn on if diodes with a short reverse recovery time are not used.)
2. Current Limiter Circuit
The current limiter circuit limits the output current peak value to a level
determined by the equation I = VFR/Rf (VRF = 0.25V typical, Rf: current
detection resistor). This circuit suppresses the output current by reducing To the RF pin
Current detection
the output on duty.
resistor
The current limiter circuit includes an internal filter circuit to prevent
incorrect current limiter circuit operation due to detecting the output diode
reverse recovery current due to PWM operation. Although there should be no problems with the internal filter circuit in
normal applications, applications should add an external filter circuit (such as an RC low-pass filter) if incorrect
operation occurs (if the diode reverse recovery current flows for longer than 1μs).
3. Notes on the PWM Frequency
The PWM frequency is determined by the capacitor C (F) connected to the PWM pin.
fPWM ≈ 1/(22500 × C)
If a 2000pF capacitor is used, the circuit will oscillate at about 22kHz. If the PWM frequency is too low, switching
noise will be audible from the motor, and if it is too high, the output power loss will increase. Thus a frequency in the
range 15k to 50kHz must be used. The capacitor's ground terminal must be placed as close as possible to the IC’s
ground pin to minimize the influence of output noise and other noise sources.
4. Control Methods
The output duty can be controlled by either of the following methods
⋅ Control based on comparing the EI+ pin voltage to the PWM oscillator waveform
The low side output transistor duty is determined according to the result of comparing the EI+ pin voltage to the PWM
oscillator waveform. When the EI+ pin voltage is 1.35V or lower, the duty will be 0%, and when it is 3.0V or higher,
the duty will be 100%.
When EI+ pin voltage control is used, a low-level input must be applied to the PWMIN pin or that pin connected to
ground.
⋅ Pulse Control Using the PWMIN Pin
A pulse signal can be input to the PWMIN pin, and the output can be controlled based on the duty of that signal.
Note that the output is on when a low level is input to the PWMIN pin, and off when a high level is input. When the
PWMIN pin is open it goes to the high level and the output is turned off. If
To the
inverted input logic is required, this can be implemented with an external
PWMIN pin
transistor (npn).
When controlling motor operation from the PWMIN pin, the EI+ pin must be
connected to the VREG pin.
Note that since the PWM oscillator is also used as the clock for internal circuits,
Pulse input
a capacitor (about 2000pF) must be connected to the PWM pin even if the
PWMIN pin is used for motor control.
No.A0662-11/11
LB11620T
5. Hall Input Signals
A signal input with an amplitude in excess of the hysteresis (80mV maximum) is required for the Hall inputs.
Considering the possibility of noise and phase displacement, an even larger amplitude is desirable.
If disruptions to the output waveforms (during phase switching) or to the HP output (Hall signal output) occur due to
noise, this must be prevented by inserting capacitors across the inputs. The constraint protection circuit uses the Hall
inputs to discriminate the motor constraint state. Although the circuit is designed to tolerate a certain amount of noise,
care is required when using the constraint protection circuit.
If all three phases of the Hall input signal system go to the same input state, the outputs are all set to the off state (the UL,
VL, WL, UH, VH, and WH outputs all go to the low level).
If the outputs from a Hall IC are used, fixing one side of the inputs (either the + or – side) at a voltage within the
common-mode input voltage range allows the other input side to be used as an input over the 0V to VCC range.
6. Under-voltage Protection Circuit
The under-voltage protection circuit turns one side of the outputs (UH, VH, and WH) off when the VREG pin voltage
falls below the minimum operation voltage (see the Electrical Characteristics). To prevent this circuit from repeatedly
turning the outputs on and off in the vicinity of the protection operating voltage, this circuit is designed with hysteresis.
Thus the output will not recover until the operating voltage rises 0.5V (typical).
7. Constraint Protection Circuit
When the motor is physically constrained (held stopped), the CSD pin external capacitor is charged (to about 3.0 V) by
a constant current of about 2.25μA and is then discharged (to about 1.0V) by a constant current of about 0.15μA.
This process is repeated, generating a saw-tooth waveform. The constraint protection circuit turns motor drive on and
off repeatedly based on this saw-tooth waveform. (The UH, VH, and WH side outputs are turned on and off.) Motor
drive is on during the period the CSD pin external capacitor is being charged from about 1.0V to about 3.0V, and motor
drive is off during the period the CSD pin external capacitor is being discharged from about 3.0V to about 1.0V.
The IC and the motor are protected by this repeated drive on/off operation when the motor is physically constrained.
The motor drive on and off times are determined by the value of the connected capacitor C (in µF).
TCSD1 (drive on period) ≈ 0.89 × C (seconds)
TCSD2 (drive off period) ≈ 13.3 × C (seconds)
When a 0.47μF capacitor is connected externally to the CSD pin, this iterated operation will have a drive on period of
about 0.4 seconds and a drive off period of about 6.3 seconds.
While the motor is turning, the discharge pulse signal (generated once for each Hall input period) that is created by
combining the Hall inputs internally in the IC discharges the CSD pin external capacitor. Since the CSD pin voltage
does not rise, the constraint protection circuit does not operate.
When the motor is physically constrained, the Hall inputs do not change and the discharge pulses are not generated.
As a result, the CSD pin external capacitor is charged by a constant current of 2.5μA to about 3.0V, at which point the
constraint protection circuit operates. When the constraint on the motor is released, the constraint protection function is
released.
Connect the CSD pin to ground if the constraint protection circuit is not used.
8. Forward/Reverse Direction Switching
This IC is designed so that through currents (due to the output transistor off delay time when switching) do not flow in
the output when switching directions when the motor is turning. However, if the direction is switched when the motor
is turning, current levels in excess of the current limiter value may flow in the output transistors due to the motor coil
resistance and the motor back EMF state when switching. Therefore, designers must consider selecting external output
transistors that are not destroyed by those current levels or only switching directions after the speed has fallen below a
certain speed.
9. Handling Different Power Supply Types
When this IC is operated from an externally supplied 5V power supply (4.5 to 5.5V), short the VCC pin to the VREG
pin and connect them to the external power supply.
When this IC is operated from an externally supplied 12V power supply (8 to 17 V), connect the VCC pin to the power
supply. (The VREG pin will generate a 5V level to function as the control circuit power supply.)
No.A0662-12/11
LB11620T
11. Power Supply Stabilization
Since this IC uses a switching drive technique, the power supply line level can be disturbed easily. Therefore capacitors
with adequate capacitance to stabilize the power supply line must be inserted between VCC and ground.
If diodes are inserted in the power supply lines to prevent destruction if the power supply is connected with reverse
polarity, the power supply lines are even more easily disrupted, and even larger capacitors are required.
If the power supply is turned on and off by a switch, and if there is a significant distance between that switch and the
stabilization capacitor, the supply voltage can be disrupted significantly by the line inductance and surge current into
the capacitor. As a result, the withstand voltage of the device may be exceeded. In application such as this, the surge
current must be suppressed and the voltage rise prevented by not using ceramic capacitors with a low series impedance,
and by using electrolytic capacitors instead.
12. VREG Stabilization
To stabilize the VREG voltage, which is the control circuit power supply, a 0.1μF or larger capacitor must be inserted
between the VREG pin and ground. The ground side of this capacitor must connected to the IC ground pin with a line
that is as short as possible.
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PS No.A0662-13/13