SANYO LB11980H

Ordering number : EN8798
Monolithic Digital IC
LB11980H
For VCR Capstan
Three-Phase Brushless Motor Driver
Overview
LB11980H is a 3-phase brushless motor driver optimal for driving the VCR capstan motors.
Features
• 3-Phase full-wave current-linear drive system.
• Torque ripple correction circuit built-in.(correction factor variable)
• Current limiter circuit built in.
• Output stage upper/lower over-saturation prevention circuit built in. (No external capacitor required)
• FG amplifier built in.
• Thermal shutdown circuit built in.
Absolute Maximum Ratings at Ta = 25°C
Parameter
Maximum supply voltage
Symbol
Conditions
Ratings
VCC max
Unit
7
V
VS max
25
V
Maximum output current
IO max
1.3
A
Allowable power dissipation
Pd max
1.81
W
Mounted on a specified board *
0.77
W
Operating temperature
Topr
Independent IC
-20 to +75
°C
Storage temperature
Tstg
-55 to +150
°C
* Mounted on a specified board: 114mm×71.1mm×1.6mm, glass epoxy board
Allowable Operating Range at Ta = 25°C
Parameter
Supply voltage
Symbol
Conditions
VS
GSENSE input range
VHALL
VGSENSE
Unit
5 to 24
VCC
Hall input amplitude
Ratings
Between hall inputs
With respect to the control system ground
V
4.5 to 5.5
V
±30 to ±80
mVo-p
-0.20 to +0.20
V
Any and all SANYO Semiconductor products described or contained herein do not have specifications
that can handle applications that require extremely high levels of reliability, such as life-support systems,
aircraft's control systems, or other applications whose failure can be reasonably expected to result in
serious physical and/or material damage. Consult with your SANYO Semiconductor representative
nearest you before using any SANYO Semiconductor products described or contained herein in such
applications.
SANYO Semiconductor 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
products described or contained herein.
D2706 MS IM B8-5775 No.8798-1/11
LB11980H
Electrical Characteristics at Ta = 25°C, VCC = 5V, VS = 15V
Ratings
Parameter
VCC supply current
Symbol
Conditions
min
typ
Unit
max
RL = ∞, VCTL = 0, VLIM = 0V (Quiescent)
12
18
mA
VOsat1
IO = 500mA, Rf = 0.5Ω, sink+source
VCTL = VLIM = 5V (With saturation prevention)
2.1
2.6
V
VOsat2
IO = 1.0A, Rf = 0.5Ω, sink+source
VCTL = VLIM = 5V (With saturation prevention)
2.6
3.5
V
1.0
mA
ICC
Output
Output saturation voltage
Output leakage current
IOleak
FR
FR pin input threshold voltage
VFSR
FR pin input input bias current
Ib (FSR)
VFR = 3V
1.0
1.25
2
V
100
150
200
µA
Control
CTL pin input Input bias current
CTL pin input motor current
Ib (CTL)
VCTL = 5V
Imctl
VCTL = 0V
1.5
3
µA
5
mA
CTL pin control start voltage
VCTL (ST)
Rf = 0.5Ω, VLIM = 5V, IO ≥ 10mA
Hall input logic fixed (U, V, W = H, H, L)
2.25
2.50
2.75
V
CTL pin control Gm
Gm (CTL)
Rf = 0.5Ω, ∆IO = 200mA
Hall input logic fixed (U, V, W = H, H, L)
0.86
1.06
1.26
A/V
1.5
3
µA
5
mA
Current limit
LIM pin input current
Ilim
VLIM = 3V
LIM pin motor current
Imlim
VLIM = 0V
LIM current limit offset voltage
Voff (LIM)
LIM pin control Gm
Gm (lim)
Rf = 0.5Ω, VCTL = 5V, IO ≥ 10mA
Hall input logic fixed (U, V, W = H, H, L)
Rf = 0.5Ω, VCTL = 5V
1.0
1.25
1.5
V
0.59
0.71
0.83
A/V
+6
mV
3.0
µA
3.3
V
Hall input logic fixed (U, V, W = H, H, L)
Hall amplifier
Hall amplifier input offset voltage
VOFF
-6
(HALL)
Hall amplifier input bias current
Hall amplifier common-mode
Ib (HALL)
1.0
VCM (HALL)
1.3
input voltage
TRC
Torque ripple correction ratio
TRC
For the high and low peaks in the Rf waveform when
13
%
IO = 200mA
(Rf = 0.5Ω, ADJ-OPEN) Note.2
ADJ pin voltage
VADJ
2.37
2.50
2.63
V
FG Amplifier
FG amplifier input offset voltage
VOFF (FG)
FG amplifier input bias current
Ib (FG)
FG amplifier output saturation
VOsat (FG)
-8
+8
-100
Sink side; With internal pull-up resistance load
mV
nA
0.5
0.6
V
44.5
47.5
dB
4.0
V
51.0
%
0.2
V
60
mV
voltage
FG amplifier voltage gain
VG (FG)
FG amplifier common-mode input
VCM (FG)
For open loop at f = 10kHz
41.5
0.5
voltage
Schmitt amplifier
Duty ratio
DUTY
Under specified conditions (RF = 39kΩ) Note 3
Upper side output saturation voltage
Vsatu (SH)
IO = -20µA
Lower side output saturation voltage
Vsatd (SH)
IO = 100µA
Hysteresis width
Vhys
FGS output pin pull-up resistance
RFGout
49.0
50
4.8
32
V
46
4.7
kΩ
Saturation
Saturation prevention circuit
lower set voltage
VO sat
(DET)
Voltage between each OUT and Rf with
T-TSD
(Design target) Note.1
0.175
0.25
0.325
V
IO = 10mA, Rf = 0.5Ω, VCTL = VLIM = 5V
TSD
TSD operating temperature
180
°C
Note 1. No measurements are made on the parameters with Note (Design target).
No.8798-2/11
LB11980H
Note 2. The torque ripple compensation ratio is determined as follows from the Rf voltage waveform.
Vp
Vb
III
II
I
IV
V
VI
Each hall logic setting
GND level
2* (Vp - Vb)
Correnction ratio =
100* (%)
Vp + Vb
Note 3. Apply the sine wave of 1kHz, 20mVP-P under conditions with a sample circuit installed externally as shown
above.
Package Dimensions
unit : mm (typ)
3233B
HEAT SPREADER
15.2
(6.2)
0.65
7.9
10.5
15
(4.9)
28
1
14
0.8
0.25
2.0
0.1
(2.25)
0.3
2.7
SANYO : HSOP28H(375mil)
Pd max - Ta
2.0
Allowable power dissipation, Pd max - W
2.45max
(0.8)
Mounted on a specified board
(114mm×71.1mm×1.6mm
glass epoxy)
1.81
1.8
1.6
1.4
1.2
1.0 0.77
1.09
Independent IC
0.8
0.6
0.46
0.4
0.2
0
-20
0
20 25
40
60
Ambient temperature, Ta - °C
75 80
100
ILB01492
No.8798-3/11
LB11980H
Pin Assignment
WOUT
1
28
VOUT
NC
2
27
UOUT
NC
3
26
NC
RF
4
25
NC
GSENSE
5
24
RF
FR
6
23
ADJ
GND
7
22
VS
FRAME GND
FRAME GND
LB11980H
FGIN-
8
21
VCC
FGIN+
9
20
HW-
FGOUT
10
19
HW+
FGS
11
18
HV-
CTL
12
17
HV+
LIM
13
16
HU-
FC
14
15
HU+
Top view
No.8798-4/11
LB11980H
Block Diagram
12
Output stage
FC
VS
VIN-
WIN+
Combined output
V
( linear matrix)
VIN+
Hall input combination block
U
UIN-
logarithmic compression block
UIN+
U
U-OUT
V
V-OUT
W
W-OUT
Logarithmic
inverse
transformation
Rf (PWR)
W
Upper saturation
prevention control
WIN-
gm
Rf (SENSE)
gm
Differential distribution and
torque ripple correction block
Drive distribution circuit &
lower saturation
prevention control
ADJ
Control amplifier
CTL
Feedback amplifier
Approx.1/2VCC
LIMREF
GSENSE
LIM
FR
Forward/
reverse
selection
FG amplifier
TSD
FGIN+
FGIN-
FGOUT
GND
FGS
VCC
Reference
voltage
Bandgap 1.25V
No.8798-5/11
LB11980H
Truth Table and Control Function
Hall input
Source → Sink
V→W
1
W→V
U→W
2
U→V
W→V
W→U
H
L
L
V→U
H
L
H
H
L
U→V
L
L
L
U→W
6
H
L
V→W
5
W
H
V→U
4
V
H
W→U
3
U
H
H
L
FR
H
L
H
L
H
L
H
L
H
L
H
L
Note: “H” in the FR column represents a voltage of 2.75V or more. “L” represents a voltage of 2.25V or less.
(At VCC = 5V)
Note: “H” under the Hall Input columns represents a state in which “+” has a potential which is higher by 0.01V or
more than that of the “-” phase inputs. Conversely “L” represents a state in which “+” has a potential which is
lower by 0.01V or more than that of the “-” phase inputs.
Note: Since a 180° energized system is used as a drive system, other phases than the sink and source are not OFF.
[Control Function & Current Limiter Function]
Control characteristics VLIM = 5V
Current limiter characteristics VCTL = 5V
1OUT
1OUT
Gm = 1.06A/Vtyp
2.50Vtyp
Slope = 0.71A/Vtyp
VLIM
VCTL
0
1
2
3
4
5
0
1
2
3
4
1.25Vtyp
No.8798-6/11
LB11980H
Pin Functions
Pin name
Pin no
FR
6
GND
7
Functions
Forward/reverse select pin.
This pin voltage determines forward/reverse. (Vth = 1.25V TYP at VCC = 5V)
GND for others than the output transistor.
Minimum potential of output transistor is at Rf pin.
FGIN (-)
8
Input pin for the FG amplifier to be used with inverted input.
A feedback resistor is connected between this pin and FG OUT.
FGIN (+)
9
Non-inverted input pin for the FG amplifier to be used as differential input.
No bias is applied internally.
FG-OUT
10
FG amplifier output pin.
Resistive load provided internally.
CTL
12
Speed control pin. Control is performed by means of constant current drive which is applied by current feedback from Rf.
Gm = 1.06A/VTYP at Rf = 0.5Ω
LIM
13
Current limiter function control pin.
This pin voltage is capable of varying the output current linearly.
Slope = 0.71A/VTYP at Rf = 0.5Ω
FC
14
UIN+, UINVIN+, VIN-
15, 16
U-phase Hall device input pin; logic “H” presents IN+>IN-
Speed control loop’s frequency characteristics correction pin.
17, 18
V-phase Hall device input pin; logic “H” presents IN+>IN-
WIN+, WIN-
19, 20
W-phase Hall device input pin; logic “H” presents IN+>IN-
VCC
21
Power supply pin for supplying power to all circuits expect output section in IC; this voltage must be stabilized so as to
eliminate ripple and noise.
VS
22
ADJ
23
Power supply pin for supplying power to output section in IC.
Pin to be used to adjust the torque ripple correction factor externally.
When adjusting the correction factor, apply voltage externally to the ADJ pin through a low impedance.
Increasing the applied voltage decreases the correction factor; lowering the applied voltage increases the correction
factor.
The rate of change, when left open, ranges approximately from 0 to 2 times.
(Approximately VCC/2 is set internally and the input impedance is approximately 5kΩ.)
Rf (PWR)
24
Output current detection pins. Current feedback is provided to the control blocks by connecting Rf between the pins and
Rf (SNS)
4
GND. The operation of the lower over-saturation prevention circuit and torque ripple correction circuit depends on the pin
voltage. In particular, since the oversaturation prevention level is set by the pin voltage, decreasing the Rf value
extermely may cause the lower over-saturation prevention to work less efficiently in the large current region. The PWR
pin and SENSE pin must be connected.
FGS
11
FG Schmidt amp output pin, that is pulled up with 4.7kΩ.
UOUT
VOUT
27
U-phase output pin.
28
V-phase output pin.
WOUT
1
W-phase output pin.
GSENSE
5
(Built-in spark killer diode)
GND sensing pin.
By connecting this pin to GND in the vicinity of the Rf resistor side of the Rf included motor GND wiring, the influence
that the GND common impedance exerts on Rf can be excluded. (Must not be left open.)
No.8798-7/11
LB11980H
Each Input/Output Equivalent Circuit
Pin No.
Pin name
15
UIN (+)
UIN (-)
16
18
VIN (+)
VIN (-)
19
WIN (+)
20
WIN (-)
17
Input/Output equivalent circuit
Each (+) input
Each (-) input
200Ω
100µA
200Ω
28
UOUT
VOUT
1
WOUT
22
VS
24
Rf (POWER)
4
Rf (SENSE)
VS
VCC
150µA
27
Each OUT
Lower oversaturation prevention
circuit block
VCC
30kΩ
10µA
200Ω
200Ω
Rf (SENSE)
Rf (POWER)
VCC
VCC
200Ω
100µA
200Ω
VCC
VCC
1.25V
6kΩ
10kΩ
ADJ
200Ω
500Ω
6kΩ
10kΩ
200µA
FR
VCC
20µA
VCC
20kΩ
FR
ADJ
LIM
5kΩ
200Ω
6
200µA
max
CTL
23
VCC
10kΩ
LIM
10kΩ
CTL
13
5kΩ
12
Continued on next page.
No.8798-8/11
LB11980H
Continued from preceding page.
Pin No.
Pin name
8
FGIN (-)
FGIN (+)
VCC
5µA
9
Input/output equivalent circuit
FGIN (+)
FGIN (-)
300Ω
VCC
VCC
VCC
10kΩ
FC
2kΩ
FGOUT
14
10kΩ
10
FGOUT
300Ω
FGS
VCC
VCC
4.7kΩ
VCC
10kΩ
11
FC
FGS
300Ω
No.8798-9/11
LB11980H
0.5Ω
1 WOUT
VOUT 28
2 NC
UOUT 27
3 NC
NC 26
4 RF
NC 25
5 GSENSE
RF 24
6 FR
0.1µF 0.1µF
0.1µF
Sample Application Circuit
ADJ 23
7 GND
15V
VS 22
FRAME GND
FRAME GND
VCC
1µF
FGS pulse output
8 FGIN-
VCC 21
9 FGIN+
HW- 20
10 FGOUT
HW+ 19
11 FGS
HV- 18
12 CTL
HV+ 17
13 LIM
HU- 16
14 FC
HU+ 15
Torque instruction voltage supply pin
5V
Hall element
2.5V
39kΩ
MR
0.1µF
Current limiter setting voltage supply pin
HSOP28H
Top view
Note) The constant shown in this example is only for reference and does not guarantee the characteristics.
Connect a capacitor between power supply and GND and between Hall inputs as required.
No.8798-10/11
LB11980H
Specifications of any and all SANYO Semiconductor 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.
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and all semiconductor products fail with some probability. It is possible that these probabilistic failures
could give rise to accidents or events that could endanger human lives, that could give rise to smoke or
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so that these kinds of accidents or events cannot occur. Such measures include but are not limited to
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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 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. SANYO Semiconductor believes information herein is accurate and
reliable, but no guarantees are made or implied regarding its use or any infringements of intellectual
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This catalog provides information as of December, 2006. Specifications and information herein are subject
to change without notice.
PS No.8798-11/11