SANYO LB11693JH

Ordering number : ENA0606
LB11693JH
Monolithic Digital IC
24V Fan Motor Driver IC
Overview
The LB11693JH is a three-phase brushless motor driver IC that uses a direct PWM drive technique to achieve highly
efficient drive. It is optimal for driving fuel pump motors and other miniature motors.
Functions
• Soft phase switching + Direct PWM drive
• PWM control based on both a DC voltage input (the CTL voltage) and a pulse input
• Provides a 5V regulator output
• One Hall-effect sensor FG output
• Built-in integrating amplifier
• Automatic recovery constraint protection circuit (on/off = 1/14), RD output
• Built-in current limiter circuit
• Built-in LVSD circuit
• Built-in thermal protection circuit
Specifications
Absolute Maximum Ratings at Ta = 25°C
Parameter
Supply voltage range
Symbol
Conditions
VCC max
Ratings
Unit
30
V
T ≤ 500ms
1.8
A
Allowable power dissipation 1
Pd max1
Independent IC
0.9
W
Allowable power dissipation 2
Pd max2
Mounted on a specified board*
2.1
W
Output current
IO max
Operating temperature
Topr
-40 to +85
°C
Storage temperature
Tstg
-55 to +150
°C
* Mounted on a specified board: 114.3mm×76.1mm×1.6mm, glass epoxy
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.
D1306 MS IM 20060404-S00004 No.A0606-1/12
LB11693JH
Allowable Operating Ranges at Ta = 25°C
Parameter
Symbol
Conditions
Ratings
Unit
Supply voltage range
VCC
9.5 to 28
V
Constant voltage output current
IREG
0 to -30
mA
RD output current
IRD
0 to 10
mA
FG output current
IFG
0 to 10
mA
Electrical Characteristics at Ta = 25°C, VCC = VM = 24V
Ratings
Parameter
Symbol
Conditions
unit
min
Current drain 1
ICC1
Current drain 2
ICC2
typ
max
10
13.5
mA
When STOP
4.0
5.5
mA
[Output Block]
Output saturation voltage 1
VOsat1
IO = 0.7A,VO(SINK)+VO(SOURCE)
1.5
2.05
V
Output saturation voltage 2
VOsat2
IO = 1.5A,VO(SINK)+VO(SOURCE)
2.2
2.9
V
Output leakage current
IOleak
100
µA
High side diode forward voltage 1
VD1
ID = 0.7A
1.25
1.65
V
High side diode forward voltage 2
VD2
ID = 1.5A
1.9
2.5
V
Output voltage
VREG
IO = -5mA
5.0
5.3
V
Line regulation
∆VREG1
VCC = 9.5 to 28V
30
100
mV
Load regulation
∆VREG2
IO = -5 to -20mA
20
100
mV
[5V Constant Voltage Output]
4.7
[Hall Amplifier]
10
µA
Hall sensor input sensitivity
VHIN
Sine wave input
50
350
mVp-p
Common-mode input voltage range
VICM
Differential input 50mVp-p
1.5
VREG-1.0
Input offset voltage
VIOH
Design target value*
-20
+20
mV
3.0
3.25
V
Input bias current
IB(HA)
2
V
[CSD Pin]
High-level output voltage
VOH(CSD)
2.75
Low-level output voltage
VOL(CSD)
0.85
1.0
1.15
V
External capacitor charge current
ICSD1
-3.3
-2.4
-1.4
µA
External capacitor discharge current
ICSD2
0.09
0.17
0.23
µA
Charge/discharge current ratio
RCSD
Charge current/discharge current
14
Times
[Undervoltage Protection Circuit (LVS Pin)]
Operating voltage
VSDL
3.6
3.8
Release voltage
VSDH
4.1
4.3
4.5
V
Hysteresis
∆VSD
0.35
0.5
0.65
V
0.45
0.5
0.55
V
150
170
°C
40
°C
4.0
V
[Current Limiter Circuit]
Limiter voltage
VRF
VCC-VM
[Thermal Shutdown Operation]
Thermal shutdown operating
TSD
temperature
Hysteresis
Design target value*
(junction temperature)
∆TSD
Design target value*
(junction temperature)
[CTL Amplifier]
Input offset voltage
Input bias current
Common-mode input voltage range
VIO(CTL)
-10
10
mV
IB(CTL)
-1
1
µA
VICM
0
VREG-1.7
V
1.05
V
High-level output voltage
VOH(CTL)
ITOC = -0.2mA
Low-level output voltage
VOL(CTL)
ITOC = 0.2mA
G(CTL)
f(CTL) = 1kHz
Open-loop gain
*: Design target value and no measurement was made.
VREG-1.2
VREG-0.8
0.8
45
51
V
dB
Continued on next page.
No.A0606-2/12
LB11693JH
Continued from preceding page.
Ratings
Parameter
Symbol
Conditions
unit
min
typ
max
[PWM Oscillator Circuit]
High-level output voltage
VOH(PWM)
2.75
Low-level output voltage
VOL(PWM)
1.1
1.3
1.4
V
V(PWM)
1.5
1.7
2.0
Vp-p
Amplitude
3.0
3.25
V
VPWM = 2.1V
-125
-90
-70
µA
f(PWM)
C = 2200pF
15.5
19.5
27.0
kHz
Input voltage 1
VTOC1
Output duty: 100%
2.72
3.0
3.30
V
Input voltage 2
VTOC2
Output duty: 0%
1.07
1.3
1.45
V
Input voltage 1L
VTOC1L
Design target value*. 100% when VREG = 4.7V
2.72
2.80
2.90
V
Input voltage 2L
VTOC2L
Design target value*. 0% when VREG = 4.7V
1.07
1.17
1.27
V
Input voltage 1H
VTOC1H
Design target value*. 100% when VREG = 5.3V
3.08
3.20
3.30
V
Input voltage 2H
VTOC2H
Design target value*. 0% when VREG = 5.3V
1.21
1.33
1.45
V
0.1
0.3
V
10
µA
0.3
V
10
µA
External capacitor charge current
Oscillator frequency
ICHG
[TOC Pin]
[RD Pin]
Low-level output voltage
Output leakage current
VOL(RD)
IRD = 5mA
IL(RD)
VRD = 28V
[FG Pin]
Low-level output voltage
Output leakage current
VOL(FG)
IFG = 5mA
IL(FG)
VFG = 28V
0.1
[FGFIL Pin]
Charge current
IFGFIL1
-7
-5
-3
µA
Discharge current
IFGFIL2
3
5
7
µA
[FG Amplifier Schmitt Block (IN1)]
Amplifier gain
Hysteresis
G(FG)
VIS(FG)
Design target value*.
7
Times
Design target value*. Input equivalent
8
mV
[S/S Pin]
High-level input voltage
VIH(SS)
2.0
VREG
V
Low-level input voltage
VIL(SS)
0
1.0
V
Input open voltage
VIO(SS)
2.6
2.9
3.2
V
Hysteresis
VIS(SS)
0.16
0.25
0.34
V
High-level input current
IIH(SS)
VS/S = VREG
100
130
µA
Low-level input current
IIL(SS)
VS/S = 0V
-170
µA
-130
[PWMIN Pin]
Input frequency range
f(PI)
50
kHz
High-level input voltage range
VIH(PI)
2.0
VREG
V
Low-level input voltage range
VIL(PI)
0
1.0
V
Input open voltage
VIO(PI)
2.6
2.9
3.2
V
Hysteresis
VIS(PI)
0.16
0.25
0.34
V
High-level input current
IIH(PI)
VPWMIN = VREG
100
130
µA
Low-level input current
IIL(PI)
VPWMIN = 0V
-170
µA
-130
[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
VREG
V
Hysteresis
VIS(FR)
High-level input current
IIH(FR)
VF/R = VREG
Low-level input current
IIL(FR)
VF/R = 0V
0.16
0.25
0.34
V
-10
0
10
µA
-165
-115
µA
*: Design target value and no measurement was made.
No.A0606-3/12
LB11693JH
Package Dimensions
unit : mm (typ)
3251
17.8
(6.2)
Allowable Power Dissipation, Pd max - W
19
1
18
2.0
0.3
0.25
2.45max
(2.25)
0.8
0.65
(4.9)
7.9
10.5
36
(0.5)
Pd max - Ta
2.4
2.1
2.0
1.6
1.2
1.09
Independent IC
0.9
0.8
0.47
0.4
0
-40
0.1
2.7
Mounted on a specified board:
114.3mm×76.1mm×1.6mm glass epoxy
-20
0
20
40
60
Ambient Temperature, Ta -°C
80
100
ILB01760
SANYO : HSOP36R(375mil)
Truth Table
F/R = ”L”
Source→Sink
F/R = “H”
IN1
IN2
IN3
IN1
IN2
IN3
1
OUT2→OUT1
H
L
H
L
H
L
2
OUT3→OUT1
H
L
L
L
H
H
3
OUT3→OUT2
H
H
L
L
L
H
4
OUT1→OUT2
L
H
L
H
L
H
5
OUT1→OUT3
L
H
H
H
L
L
6
OUT2→OUT3
L
L
H
H
H
L
NC
OUT1
F/R
IN3+
IN3-
IN2+
IN2-
IN1+
IN1-
GND1
PWM
NC
TOC
EI-
EI+
S/S
NC
35
34
33
32
31
30
29
28
27
26
25
24
23
22
21
20
19
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
OUT3
NC
GND2
NC
NC
VD
VCC
VM
VREG
LVS
FGFIL
NC
FC
CSD
FG
RD
PWMIN
FRAME
OUT2
36
NC
FRAME
Pin Assignment
Top view
No.A0606-4/12
LB11693JH
Block Diagram
FG
EI-
CTL
TOC
FG
-
EI+
RD
+
RD FC
CSD
LVS
CSD
CIRCUIT
FG
CIRCUIT
VCC
LVSD
RD
VCC
CTL AMP
TSD
PWM
PWM
OSC
VD Rd
CURR
LIM
COMP
PWMIN
VM Rf
OUT1
CONTROL
CIRCUIT
PWMIN
DRIVER
GND1
FILTER
5VREG
VREG
OUT2
VREF
BGP
F/R
S/S
S/S
HALL AMP
& MATRIX
F/R
FGFIL
VREG
IN1
IN2
OUT3
IN3
GND2
Pin Functions
Pin
No.
Symbol
34
OUT1
36
OUT2
2
OUT3
4
GND2
Pin Description
Motor drive output
Equivalent Circuit
VCC
VD
Motor drive output system ground
7
VD
Low side output transistor drive current supply
9
VM
Motor drive output power supply and output current
300Ω
VM
2
7
9
34 36
detection.
Connect a resistor (Rf) between this pin and VCC.
The output current is limited to a value determined
4
by the equation IOUT = VRF/Rf.
8
VCC
Power supply
(Systems other than the motor drive output)
10
VREG
5V regulator output
Connect a capacitor (about 0.1µF) between this pin and
VCC
ground for stabilization.
10
Continued on next page.
No.A0606-5/12
LB11693JH
Continued from preceding page.
Pin
No.
11
Symbol
LVS
Pin Description
Undervoltage protection voltage detection.
Equivalent Circuit
VREG
Connect this pin to VREG if the VREG level is to be
detected.
If the VCC level is to be detected, insert a zener diode in
52kΩ
series to set the detection level.
9.5kΩ
11
12
FGFIL
FG filter.
Normally, this IC will be used with this pin open.
VREG
Connect a capacitor between this pin and ground
if noise on the FG signal becomes a problem.
300Ω
12
14
FC
Control loop frequency characteristics correction.
VREG
Connect a capacitor between this pin and ground.
300Ω
14
15
CSD
Constraint protection circuit operating time setting.
VREG
300Ω
15
16
FG
One hall-effect sensor FG output.
(This is an open-collector output.)
VREG
16
Continued on next page.
No.A0606-6/12
LB11693JH
Continued from preceding page.
Pin
No.
17
Symbol
RD
Pin Description
Equivalent Circuit
Motor constrained state detection output
VREG
(This is an open-collector output.)
When the motor is constrained: high, when the motor is
17
turning: low.
18
PWM
IN
PWM pulse input.
VREG
When low the output will be on and when high the
outputs will be off. If this pin is used to control this IC,
30kΩ
connect EI- to ground and connect EI+ to TOC.
5kΩ
40kΩ
18
S/S
Start/stop control. Low: start, high or open: stop.
VREG
30kΩ
20
5kΩ
40kΩ
20
21
EI+
CTL amplifier noninverting input
22
EI-
CTL amplifier inverting input
VREG
300Ω
300Ω
21
TOC
PWM waveform comparator (CTL amplifier output)
VREG
23
40kΩ
23
22
PWM comparator
Continued on next page.
No.A0606-7/12
LB11693JH
Continued from preceding page.
Pin
No.
25
Symbol
PWM
Pin Description
PWM oscillator frequency setting.
Connect a capacitor between this pin and ground.
Equivalent Circuit
VREG
A frequency of about 20kHz can be set by using
a 2200pF capacitor.
2kΩ
200Ω
26
GND1
25
Ground
(For circuits other than the motor drive output system)
28
IN1+
Hall effect sensor inputs
27
IN1-
High when IN+ > IN-, low for the reverse state.
30
IN2+
Signal inputs with an amplitude (differential) of at least
29
IN2-
50mVp-p are desirable for the Hall inputs.
32
IN3+
If noise is a problem, connect capacitors between
31
IN3-
the IN+ and IN- inputs.
VREG
300Ω
300Ω
27 29 31
33
F/R
Forward/reverse control
VREG
40kΩ
Low: forward, high or open: reverse.
28 30 32
3.5kΩ
33
1,3
NC
5,6
No connection.
The NC pins may be used for wiring connections.
13,19
24,35
FRAME
Frame connection
The FRAME pin is connected internally to the IC surface
metal parts. Both must be used in the electrically open
state.
No.A0606-8/12
LB11693JH
LB11693JH Overview
1. Output Drive Circuit
The LB11693JH reduces motor vibration and noise by switching the output current smoothly when switching phases.
Since the Hall input waveform is used for the change in (slope of) the output current during phase switching, if the
slope of the Hall input waveform is too steep, the change in the output current during phase switching will also be too
steep and the effectiveness of this technique at lowering vibration and noise effect will be reduced. Thus the slope of
the Hall input waveform requires attention during application design.
Low side output transistor PWM switching is used for motor speed control. The drive output is adjusted by changing
the duty. The diodes between the outputs and VM used for the regenerative current when the PWM signal is in the
off state are built in.
If the slope (amplitude) of the Hall input waveform is large, and if used with a high current, the parasitic diodes
between the outputs and ground will operate due to the low side kickback during phase switching. If problems such
as disruption of the waveforms occur, connect either rectifying diodes or Schottky diodes between the outputs and
ground.
2. Power Supply Stabilization
Since the LB11693JH uses a control method based on PWM switching, the power supply lines are susceptible to
disruption. Electrolytic capacitors with an adequate capacitance for stabilization must be connected between VCC
and ground. If diodes are inserted in the power supply lines to prevent destruction of the equipment if the power
supply is connected in reverse, the power supply lines will be particularly susceptible to disruption. In this case, even
larger capacitors must be used. The connected electrolytic capacitors must be located as close as possible to the IC
pins (VCC, VM, and GND2). If the electrolytic capacitors cannot be attached close to the pins due to problems with
the heat sink or other issues, ceramic capacitors of about 0.1µF must be attached close to the pins.
3. VREG Pin
At the same time as being the 5V regulator output, the VREG pin is also the power supply for the IC internal control
circuits. Therefore, a capacitor of at least 0.1µF must be connected between the VREG pin and ground to stabilize the
control circuit power supply. The ground side of the connected capacitor must be connected to the GND1 pin with as
short a line as possible.
4. FC Pin
The capacitor connected to the FC pin is required to correct the control loop's frequency characteristics.
(It should be about 0.1µF.)
5. VD Pin
The VD pin supplies the low side output transistor drive current (a maximum of about 0.1A).
The IC internal power consumption is suppressed by connecting a resistor between the VCC and VD pins and
dividing power consumption due to the low side output transistor drive current with that resistor. Although the IC
internal power consumption due to the drive current can be reduced by lowering the VD pin voltage, a voltage of at
least 4V must be assured at the VD pin. Use a resistor in the range from about 50Ω (0.5W) to about 100Ω (1W)
between the VCC and VD pins when the LB11693JH is used with VCC = 24V.
6. Hall Effect Sensor Input Signals
Signal inputs with an amplitude (differential) of at least 50mVp-p are required for the Hall inputs. If the output
waveforms are disrupted by noise, capacitors must be connected between the Hall input pins (the + and - sides).
7. Current Limiter Circuit
The current limiter circuit limits the peak value of the output current to a current determined by the equation I =
VRF/Rf (where VRF = 0.5V (typical), Rf = current detection resistor value). When the limiter operates, it suppresses
the current by PWM control of the low side output transistor at the PWM frequency determined by the external
capacitor connected to the PWM pin, in particular, by reducing the on duty.
No.A0606-9/12
LB11693JH
8. Forward/Reverse Switching
The LB11693JH was designed assuming that forward/reverse switching would not be performed while the motor is
operating. We recommend that the F/R pin be held fixed at either the low (forward) or high (reverse) level when the
motor is turning. Although it will be pulled up to the high level by an internal pull-up resistor (about 40kΩ) when left
open, this must be strengthened by an external resistor if fluctuations are large.
If the direction is switched while the motor is turning, large currents will flow due to the braking operation. The
LB11693JH's current limiter circuit, however, cannot limit this braking current. Therefore, forward/reverse switching
during motor rotation is only possible if the braking current is limited to a value under IO max (1.8A) by the motor
coil resistance or other circuit or phenomenon. Furthermore, since through current will flow in the high and low side
transistors at the instant the switch occurs with switching that only uses the F/R pin, applications must provide a rive
off period for switching directions. A drive off period must be provided by either setting the IC to the stopped state
with the S/S pin or setting the PWM signal to the 0% duty state with the TOC and PWMIN pins, and the F/R pin
must only be switched during that period to prevent through current.
9. Power Saving Circuit
This IC can be set to a power saving state in which current consumption is reduced by setting it to the stopped state
with the S/S pin. The bias current to most of the circuits in the IC is cut off in this power saving state. Note, however,
that the 5V regulator output is still provided in the power saving state.
10. Notes on the PWM Frequency
The PWM frequency is determined by the capacitance (F) of the capacitor connected to the PWM pin.
fPWM≈1/ (23400×C)
A frequency in the range 15 to 25kHz is desirable for the PWM frequency. The ground side of the connected
capacitor must be connected to the GND1 pin by as short a line as possible.
11. Control Methods
The output duty can be controlled by either of the following methods.
• Comparison of the TOC pin voltage with the PWM oscillator waveform
This method determines the low side output transistor duty according to the result of comparing the TOC pin
voltage with the PWM oscillator waveform. The PWM duty will be 0% when the TOC pin voltage is under about
1.3V and will be 100% when that voltage is over about 3.0V.
Since the TOC pin is the output of the CTL amplifier, a control voltage cannot be directly input to the TOC pin.
Accordingly, the CTL amplifier is normally used as a full feedback amplifier (by connecting the EI- pin to the
TOC pin) and inputting a DC voltage to the EI pin (here the TOC voltage will be equal to the EI+ pin voltage).
When the EI+ pin voltage increases, the output duty will increase as well. Since the motor will be driven if the EI+
pin is in the open state, a pull-down resistor should be connected to the EI+ pin in applications where this is not
desirable.
A low level must be input to the PWMIN pin (or it must be connected to ground) if the TOC pin voltage control
system is used.
• PWMIN pulse input
A 15 to 25kHz frequency pulse signal can be input to the PWMIN pin and the low side output transistor duty can
be controlled based on the duty of that input signal. When the PWMIN pin is low, the output will be on, and when
high, the output will be off. When the PWMIN pin is open, the input will go to the high level and the output will be
off.
If PWMIN pin control is used, the EI- pin must be connected to ground and the EI+ pin must be connected to the
TOC pin.
No.A0606-10/12
LB11693JH
12. Undervoltage Protection Circuit
The undervoltage protection circuit turns off the low side output transistor
To the detected
if the LVS pin voltage falls below the circuit's operating voltage (about 3.8V).
power supply
This operating voltage is the detection level for a 5V system. The detection
level can be increased by connecting a zener diode in series with the LVS pin
To the LVS pin
to apply a level shift to the detection level. The current flowing into the LVS
pin during detection is about 65µA.
To suppress variations in the zener voltage, it is necessary to stabilize the rise of the
zener diode voltage by increasing the current that flows in the zener diode. If this is
necessary, insert a resistor between the LVS pin and ground.
When the LVS pin is open, it will be pulled to the ground level by the built-in pull-down resistor and the output will
be turned off. Thus if the undervoltage protection circuit is not used, a voltage in excess of the release voltage (about
4.3V) must be applied to the LVS pin. Note that the maximum rating for the LVS pin voltage is 30V.
13. Motor Constraint Protection Circuit
When motor motion is constrained, the external capacitor connected to the CSD pin will be alternately charged (up to
about 3.0V) with a constant current of about 2.4µA and discharged with a constant current of about 0.17µA (to about
1.0V). Thus the CSD pin voltage will have a sawtooth waveform. The motor constraint protection circuit turns the
motor (the low side output transistor) on or off repeatedly based on this sawtooth waveform. Motor drive will be on
during the period the CSD pin external capacitor is being charged from about 1.0V to about 3.0V and will be off
when it is being discharged from about 3.0V to about 1.0V. The drive on/off operation protects the IC and the motor
when the motor is physically constrained from moving. If a 0.47µF capacitor is connected to the CSD pin, the IC will
iterate an on/off cycle in which drive is on for about 0.4 seconds and off for about 5.5 seconds.
While the motor is turning, the CSD pin voltage will be held at a certain voltage (that depends on the motor speed) by
(a) a CSD pin external capacitor discharge operation based on about 10µs discharge pulses generated internally in the
IC when the Hall input IN1 switches (that is, on rising and falling edges on the FG output) and (b) a charge operation
on that capacitor by a constant current of about 2.4µA.
Since the Hall input IN1 does not switch when the motor is physically constrained, the discharge pulses are not
generated and the CSD pin external capacitor will be charged to about 3.0V by the constant current of about 2.4µA.
The motor constraint protection circuit operates when the capacitor reaches about 3.0V. The constraint protection
operation will be released when the motor constraint is released.
If the motor speed is extremely low, the CSD pin voltage during that motor rotation will be held at a comparatively
high voltage, and if that voltage reaches about 3.0V, the constraint protection function will operate. Since the
constraint protection function will operate if the Hall input IN1 frequency falls below about 10Hz, caution is required
when using the motor constraint protection circuit with motors that will operate at low speeds.
Connect the CSD pin to ground if the motor constraint protection circuit is not used.
No.A0606-11/12
LB11693JH
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.
SANYO Semiconductor Co., Ltd. strives to supply high-quality high-reliability products. However, any
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
fire, or 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 products (including technical data,services) described
or contained herein are controlled under any of applicable local export control laws and regulations, such
products must not be exported without obtaining 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
mechanical, including photocopying and recording, or any information storage or retrieval system, or
otherwise, without the prior written permission 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 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
property rights or other rights of third parties.
This catalog provides information as of December, 2006. Specifications and information herein are subject
to change without notice.
PS No.A0606-12/12