SANYO LV8220FN

Ordering number : EN7811A
LV8220FN
Bi-CMOS IC
CD/MD System Motor Driver
Overview
The LV8220FN is a system motor driver IC that implements all the motor driver circuits needed for CD and MD
products. Since the LV8220FN provides a three-phase PWM spindle driver, a three-phase sled driver, and focus and
tracking drivers (as two PWM H-bridge driver channels), it can contribute to further miniaturization, thinner from factors,
and lower power in end products. The adoption of the direct PWM sensorless drive method for the spindle driver and the
sled driver makes it possible to implement high efficiency motor drive with few external parts.
Features
• Direct PWM drive (low side control)
• Three-phase full-wave sensorless motor driver (spindle and sled blocks)
• Soft switching drive (spindle block)
• Reverse torque braking
• MOS output transistors
• Standby mode power saving function
• FG output
Specifications
Absolute Maximum Ratings at Ta = 25°C
Parameter
Symbol
Conditions
Ratings
Unit
Power supply voltage 1
VCC max
6.0
V
Power supply voltage 2
VG max
9.6
V
Output block power supply voltage
VS max
6.0
V
Output current
IO max
0.8
A
0.35
W
1.1
W
Power dissipation 1
Pd max1
Independent IC
Power dissipation 2
Pd max2
Mounted on a specified board
Operating temperature
Topr
-20 to +85
°C
Storage temperature
Tstg
-55 to +150
°C
* Mounted on a specified board: 50mm×50mm×0.8mm, glass epoxy
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.
50907 TI IM B8-6675 No.7811-1/15
LV8220FN
Recommended Operating Conditions at Ta = 25°C
Parameter
Symbol
Conditions
Ratings
Unit
Power supply voltage 1
VCC
1.9 to 4.0
V
Power supply voltage 2
VG
5.0 to 9.0
V
Output block power supply voltage
VS
0 to 5.5
V
VS ≤ VG-3.5(V)
Electrical Characteristics at Ta = 25°C, VCC = 2.3V
Parameter
Symbol
Ratings
Conditions
min
typ
unit
max
Power supply current 1
ICC1
S/S pin H, SEL1 pin H
1.3
2.0
mA
Power supply current 2
ICC2
S/S pin H, SEL1 pin L
1.0
1.5
mA
Power supply current 3
ICC3
S/S pin L (standby mode)
20
µA
Power supply current 4
IG1
S/S pin H, SEL1 pin L
Power supply current 5
IG2
S/S pin L (standby mode)
80
150
µA
20
µA
CLK Pin
High level input voltage range
VCLKH
VCC-0.5
VCC
V
Low level input voltage range
VCLKL
0
0.5
V
3.5
4.5
V
VG2 Pin
Output voltage
VREG
VG1=6.3(V)
Actuator block (focus and tracking)
Actuator input pin
High level input voltage range
VAIH
VCC-0.5
VCC
V
Low level input voltage range
VAIL
0
0.5
V
Output block ON resistance
SOURCE1
Ron(H1)
IO=0.5A, VS=2.3V, VG=6.3V
forward TR
0.4
0.6
Ω
SOURCE2
Ron(H2)
IO=0.5A, VS=2.3V, VG=6.3V
reverse TR
0.4
0.6
Ω
Ron(L)
IO=0.5A, VS=2.3V, VG=6.3V
0.4
0.6
Ω
IO=0.5A, sum of upper and lower outputs
0.8
1.2
Ω
SINK
SOURCE+SINK
Ron(H+L)
Output transmission delay time
TRISE
* Design target
0.1
µs
(H-bridge)
TFALL
* Design target
0.1
µs
Minimum input pulse width
tmin
Ch1, ch2 output pulse width is 2/3 tmin or more
* Design target
200
ns
Sled block
Output block ON resistance
SOURCE1
Ron(H1)
IO=0.5A, VS=2.3V, VG=6.3V
forward TR
0.4
0.6
Ω
SOURCE2
Ron(H2)
IO=0.5A, VS=2.3V, VG=6.3V
reverse TR
0.4
0.6
Ω
Ron(L)
IO=0.5A, VS=2.3V, VG=6.3V
0.4
0.6
Ω
IO=0.5A, sum of upper and lower outputs
0.8
1.2
Ω
SINK
SOURCE+SINK
Ron(H+L)
Decoder Input Pin (S1 to S3)
High level input voltage range
VSLIH
VCC-0.5
VCC
V
Low level input voltage range
VSLIL
0
0.5
V
Input offset voltage
VSLOFS
-5
+5
mV
Common-mode input voltage range
VSLCM
0
VCC
V
High level output voltage
VSLFGH
IO=-0.5mA
VCC-0.5
VCC
V
Low level output voltage
VSLFGL
IO=0.5mA
0.5
V
Position detection comparator
VCO Pin
VCO high level voltage
VSLVCOH
0.85
1.05
1.25
V
VCO low level voltage
VSLVCOL
0.40
0.60
0.80
V
* Design target value and no measurement is performed.
Continued on next page.
No.7811-2/15
LV8220FN
Continued from precceding page.
Parameter
Symbol
Ratings
Conditions
min
typ
unit
max
PWM Pin
High level input voltage range
VSLPWMH
VCC-0.5
Low level input voltage range
VSLPWML
0
PWM input frequency
VCC
fSLIN
V
0.5
V
190
kHz
SEL Pin
High level input voltage range
VSLH
VCC-0.5
VCC
V
Low level input voltage range
VSLL
0
0.5
V
Spindle motor driver block
Output block ON resistance
SOURCE1
Ron(H1)
IO=0.5A, VS=2.3V, VG=6.3V
forward TR
0.4
0.6
Ω
SOURCE2
Ron(H2)
IO=0.5A, VS=2.3V, VG=6.3V
reverse TR
0.4
0.6
Ω
Ron(L)
IO=0.5A, VS=2.3V, VG=6.3V
0.4
0.6
Ω
IO=0.5A, sum of upper and lower outputs
0.8
1.2
Ω
+5
mV
SINK
SOURCE+SINK
Ron(H+L)
Position detection comparator
Input offset voltage
VSOFS
-5
VCO Pin
VCO high level voltage
VSPVCOH
0.85
1.05
1.25
V
VCO low level voltage
VSPVCOL
0.40
0.60
0.80
V
S/S Pin
High level input voltage range
VSSH
Start
VCC-0.5
VCC
V
Low level input voltage range
VSSL
Stop
0
0.5
V
VCC-0.5
VCC
V
0
0.5
V
BREAK Pin
High level input voltage range
VSPBRH
Brake OFF
Low level input voltage range
VSPBRL
Brake ON
PWM Pin
High level input voltage range
VSPPWMH
VCC-0.5
VCC
V
Low level input voltage range
VSPPWML
0
0.5
V
190
kHz
VCC
V
0.5
V
PWM input frequency
fSPIN
FG Output Pin
High level output voltage
VSPFGH
IO=-0.5mA
Low level output voltage
VSPFGL
IO=0.5mA
VCC-0.5
Package Dimensions
unit : mm (typ)
3272
Top View
Bottom View
0.2
7.2
7.0
36
25
5.0
5.0
0.3
7.0
7.2
48
0.4
24
37
13
1
12
0.5
Side View
4 - Do Not Connect
0.2
(0.8)
0.85MAX
(0.75)
0.4
0.3
SANYO : VQFN48(7X7)
No.7811-3/15
LV8220FN
Pd max - Ta
Allowable power dissipation, Pd max - W
1.5
Mounted on a specified board:
50mm×50mm×0.8mm,
Mounted on a thermal resistance
glass epoxy
evaluation board
1.1
1.0
0.57
0.5
Independent IC
0.35
0.18
0
-20
0
20
40
60
80
100
Ambient temperature, Ta - °C
ILV00177
Logic I/O Truth Tables
Focus and Tracking Blocks
S/S
IN1, 2F
IN1, 2R
OUT1, 2F
OUT1, 2R
H
L
H
H
L
L
L
L
H
H
L
L
H
L
H
H
H
H
L
L
L
×
×
Z
Z
Sled Motor Stepping block
SEL
S/S
S1
S2
S3
SUO
SVO
SWO
L
H
L
L
L
H
L
Z
L
H
H
L
L
H
Z
L
L
H
L
H
L
Z
H
L
L
H
H
H
L
L
H
Z
L
H
L
L
H
L
Z
H
L
H
H
L
H
Z
L
H
L
H
L
H
H
Z
Z
Z
L
H
H
H
H
Z
Z
Z
H
H
×
×
×
×
L
×
×
×
Commutation output determined by sensorless logic
Z
Z
Z
Z: open
BRK Pin
S2
OUT
SPBR
OUT
H
Acceleration
H
Acceleration
L
Deceleration
L
Deceleration
PWM Pin
SLPWM
SINKOUT
SPPWM
SINKOUT
H
ON
H
ON
L
OFF
L
OFF
S/S Pin
S/S
H-bridge
Sled
Spindle
Remarks
H
Operating
Operating
Operating
Operating mode
L
Stopped
Stopped
Stopped
Power saving mode
No.7811-4/15
LV8220FN
36
35
34
33
32
31
30
29
28
27
26
SPGND
SPVS
SPCIN
SPFIL
SPVCO
VG2
GND
SLMAX
SLVCO
SLPD
SLVS
Pin Assignment
37 SPFG
25
SLGND
SLFG 24
SUO 23
38 UOUT
SLCOM 22
39 SPCOM
40 VOUT
SVO 21
41 WOUT
SWO 20
42 SPPWM
SLPWM 19
LV8220FN
VS1 18
43 VS2
44 OUT2F
OUT1F 17
45 OUT2R
OUT1R 16
46 PGND2
PGND1 15
IN1R 14
SPPD
SPMAX
IN2F
IN2R
VG1
VCC
CLK
S1
S2
S3
GND
47 SPBR
SEL
1
2
3
4
5
6
7
8
9
10
11
12
48 S/S
IN1F 13
Top view
Pin Functions
Pin
Pin
No.
Name
13,14
IN1F/R
3,4
IN2F/R
7
CLK
Pin Description
Equivalent Circuit
Actuator H-bridge logic input.
Logic system reference clock input. Provide a
frequence that is 32 times that of the PWM
VCC
frequency.
12
SEL1
Three-phase sled mode switching input. When
high, the block operates in sensorless drive mode,
and when low, the block operates in stepping drive
10kΩ
mode.
19
SLPWM
Sled drive block PWM signal input. When high, the
control output transistor (SINK) is turned on.
42
SPPWM
47
SPBR
100kΩ
Spindle drive block PWM signal input. When high,
the control output transistor (SINK) is turned on.
Spindle drive block brake input. When low, reverse
torque braking is applied.
48
S/S
Start/stop input. When high, all of the spindle, sled,
and actuator blocks operate. When low, the IC
goes to the standby state (power saving mode).
Continued on next page.
No.7811-5/15
LV8220FN
Continued from preceding page.
Pin
Pin
No.
Name
8
S1
Pin Description
Decoder input in sled stepping motor mode.
Functions as the forward/reverse switching input in
Equivalent Circuit
VCC
sensorless mode (SEL1: high, SEL2: low) and in
H-bridge mode (SEL2 high).
9
S2
100kΩ
Decoder input in sled stepping motor mode.
10kΩ
Functions as the BRK (braking) switching input in
sensorless mode (SEL1: high, SEL2: low).
(A high-level input applies braking.)
10
S3
5
VG1
Decoder input in sled stepping motor mode.
Predriver power supply. Used as the power supply
for the source side predrivers, the internal regulator
(VG2), and the sensorless driver position detection
comparator. Insert a capacitor between this pin and
ground.
6
VCC
Small- signal system power supply.
Insert a capacitor between this pin and ground.
18
VS1
H-bridge circuit 1 power supply.
18
Insert a capacitor between this pin and PGND1
(pin 15).
16,17
OUT1F/R
H-bridge circuit 1 output.
16
15
PGND1
26
SLVS
H-bridge circuit 1 ground.
17
15
Sled drive block power supply.
26
Insert a capacitor between this pin and SLGND
(pin 25).
21
23
23
SUO
Sled driver output. Connect this pin to the sled
21
SVO
motor coil.
20
SWO
25
SLGND
22
SLCOM
20
25
Sled drive block ground.
Three-phase sled block position detection
comparator common side input. Connect this pin to
VG
the sled motor center point connection.
6kΩ
39
SPCOM
Spindle block position detection comparator
common side input. Connect this pin to the spindle
motor center point connection.
Continued on next page.
No.7811-6/15
LV8220FN
Continued from preceding page.
Pin
Pin
No.
Name
24
SLFG
Pin Description
Equivalent Circuit
Sled block position detection comparator output.
When a stepping mode is used, this pin outputs a
VCC
comparator signal equivalent to that provided in
systems that use three Hall sensors, and when
sensorless mode is used, the output is equivalent
to a single Hall sensor system FG output. This pin
outputs the low level in H-bridge mode.
37
SPFG
Spindle block FG pulse output.
This pin outputs a signal equivalent to a single Hall
sensor system.
27
SLPD
Sled sensorless block VCO control voltage input.
Insert a capacitor between this pin and ground. In
VCC
sensorless operating mode, a control voltage (the
VCO control voltage) proportional to the motor
speed is created.
1kΩ
1
SPPD
Spindle block VCO control voltage input. Insert a
capacitor between this pin and ground. A control
voltage (the VCO control voltage) proportional to
the motor speed is created.
28
SLVCO
Sled block sensorless mode VCO oscillator
VCC
connection. Insert a capacitor between this pin and
ground. The VCO oscillator frequency follows the
sled motor speed (the SLPD pin voltage).
SPVCO
Spindle block VCO oscillator connection. Insert a
capacitor between this pin and ground. The VCO
1kΩ
500Ω
32
500Ω
oscillator frequency follows the spindle motor
speed (the SPPD pin voltage).
29
SLMAX
Sled block sensorless mode VCO maximum
oscillator frequency setting. Reducing the value of
VCC
the resistor connected to this pin increases the
VCO oscillator frequency.
2
SPMAX
Spindle block VCO maximum oscillator frequency
setting. Reducing the value of the resistor
connected to this pin increases the VCO oscillator
500Ω
frequency.
11,30
GND
Small signal system ground
Continued on next page.
No.7811-7/15
LV8220FN
Continued from preceding page.
Pin
Pin
No.
Name
31
VG2
Pin Description
Equivalent Circuit
SINK side predrive drive regulator pin.
VG1
Insert a capacitor between this pin and ground.
31
20kΩ
270kΩ
130kΩ
39
SPCOM
33
SPFIL
Spindle motor common point connection.
VG1
Spindle block position detection comparator
waveform synthesizing signal filter connection.
600Ω
600Ω
39
33
34
Insert a capacitor between this pin and SPCIN (pin
34).
34
SPCIN
6kΩ
12kΩ
6kΩ
Spindle block position detection comparator
differential input. Insert a capacitor between this
pin and SPFIL (pin 33).
35
SPVS
Spindle drive block power supply. Insert a
35
capacitor between this pin and SPGND (pin 36).
40
38
38
UOUT
Spindle driver outputs.
40
VOUT
Connect these pins to the spindle motor coil.
41
WOUT
36
SPGND
43
VS2
41
36
Spindle drive block ground.
H-bridge circuit 2 drive power supply. Insert a
43
capacitor between this pin and PGND2 (pin 46).
44,45
OUT2F/R
H-bridge 2 outputs.
44
46
PGND2
45
H bridge 2 output block ground connections
46
No.7811-8/15
LV8220FN
Block Diagram
PGND2 VS2 OUT2R OUT2F IN2R IN2F OUT1R OUT1F IN1R IN1F
VS1
VCC
PGND1
LV8220FN
Pre drive
Pre drive
Logic
Logic
GND
S/S
VG1
SINK
Pre
Driver
SLMAX
SLVCO
REG
VCO
SLPD
Phase
comparator
CLK
SPBR
1/N
SPMAX
SPVCO
Sensourless
Logic
VCO
SEL
1/N
S1
S2
S3
SLCOM
Logic
VG2
SEL
Phase
comparator
SPPD
SPCIN
Sensourless
Logic
SPFIL
Waveform
synthesizer
Sled
Pre drive
Spindle
Pre drive
Waveform
synthesizer
SPCOM
SLVS
SPVS
SUO
SVO
SWO
UOUT
VOUT
WOUT
SPGND
SLGND
SLPWM
SLFG
SPFG
SPPWM
No.7811-9/15
LV8220FN
Sample Application Circuit
VS
33
32
31
30
29
28
27
26
25
SPVCO
VG2
GND
SLMAX
SLVCO
SLPD
SLVS
37 SPFG
34
SPFIL
DSP
35
SPCIN
36
SPGND
SPVS
VS
SLGND
38 UOUT
Spindle
motor
DSP
VS
SLFG 24
DSP
SUO 23
39 SPCOM
SLCOM 22
Sled motor
40 VOUT
SVO 21
41 WOUT
SWO 20
LV8220FN
42 SPPWM
SLPWM 19
43 VS2
VS1 18
44 OUT2F
OUT1F 17
45 OUT2R
OUT1R 16
46 PGND2
PGND1 15
DSP
VS
IN1R 14
47 SPBR
SPPD
SPMAX
IN2F
IN2R
VG1
VCC
CLK
S1
S2
S3
GND
DSP
SEL
1
2
3
4
5
6
7
8
9
10
11
12
48 S/S
DSP
VG1 VCC
IN1F 13
DSP
Insert a capacitor between VS and PGND and between VCC and GND.
No.7811-10/15
LV8220FN
LV8220FN Functional Description and Notes on External Components
The LV8220FN is a system motor driver IC that can implement, with just a single chip, the motor driver circuits
required for CD and MD systems. Since the LV8220FN provides not only a spindle driver, but drivers (with an Hbridge structure) for sled, focus, and tracking motors, it can contribute to miniaturization and thinner form factors in end
products. Since the spindle and sled drivers adopt a direct PWM sensorless drive technique, they provide high
efficiency motor drive with a minimal number of external components.
Read the following notes before designing driver circuits using the LV8220FN to design a system with fully satisfactory
characteristics.
1. Channel Structure
The LV8220FN drive circuits have the 4-channel structure shown below. To minimize power loss in the output
blocks, this IC adopts synchronous commutation direct PWM (the recommended PWM frequency is 132kHz) in all
channels, and at the same time, adopts low on-resistance DMOS devices (total high and low side on-resistance: 0.8Ω,
typical) as the output transistors.
Furthermore, this IC’s sled driver channel can operate in either three-phase sensorless or three-phase stepper drive
mode as selected by the SEL pin.
Applications
Three-pahse
Three-phase
sensorless
stepping
Spindle
c
Sled
c
H-bridge
c
Remarks
Select the mode on SEL pin
Focus
c
Tracking
c
2. Power Supply Pins
The LV8220FN has six power supply pins: the small signal system circuit power supply VCC (pin 6), the source
output gate drive power supply VG1 (pin 5), and power supplies for each of the output transistors, namely SPVS (pin
35), SLVS (pin 26), VS1 (pin 18), and VS2 (pin 43). All of these pins must be connected to an external power supply.
(Since this IC does not include a built-in charge pump circuit for output gate drive, power must also be supplied to
the VG1 pin.) Since VG2 (pin 31) is the output of an internal 4V regulator, there is no need to connect a power
supply to this pin. Note that capacitor must be inserted between each power supply pin and ground.
When power is first applied, it is desirable to apply power in the order VS first, then VG1, and finally VCC.
Although no problems with IC operation will occur of any other order is used, note that circuit current (ICC) may
flow during the period until all power supply levels have been provided.
3. S/S Circuit
The S/S pin (pin 48) functions as the system start/stop pin. A high level starts IC operation and causes all channels to
operate in drive mode. A low level switches the IC to the standby state (power saving mode). In the standby state, all
power supply currents go to zero. Total system power consumption can be reduced by manipulating the S/S pin to
operate the drivers intermittently.
Note that the S/S pin must be held at the low level while the VCC power supply level is first applied.
4. CLK Pin
The LV8220FN CLK pin (pin 7) must be connected to the reference clock signal supplied by the DSP. The CLK
signal is used as the reference clock for spindle block and sled block sensorless drive logic operation. Therefore, the
CLK signal is always required in start mode. A frequency 32 times that of the PWM input signal must be provided as
the CLK input signal. (Example: when the SPPWM and SLPWM input frequency is 132kHz, the CLK signal must be
4.224MHz.)
No.7811-11/15
LV8220FN
5. Spindle Driver Circuit
5.1 Speed Control Techniques
Spindle clock speed control uses the BRK control signal and the PWM control signal supplied by the external
DSP. The PWM control signal from the DSP is input to the SPPWM pin (pin 42), and the sink (low) side
transistor's duty is controlled according to the duty of the input signal to control the motor speed. When a high
level is input to the SPPWM pin, the sink side transistor is turned on (i.e., acceleration is applied to the motor).
The motor is decelerated by either applying short-circuit braking (by turning off the PWM signal), or by applying
reverse torque braking by inputting a brake command to the SPBR pin (pin 47). The SPBR pin switches the
direction of the torque applied by the driver; when a low level is input to the SPBR pin, the IC switches to
reverse torque braking mode. When the motor has slowed to an adequately low speed in reverse torque braking
mode (when SPBRK is low), the circuit switches to short-circuit braking to stop the motor.
Note that when stopping the motor with the braking function, if the timing with which this circuit switches to
short-circuit braking is too fast and problems such as the motor remaining in motion occur, the value of the
resistor connected to the SPMAX pin (pin 2) must be reduced. If the motor moves back and forth without
stopping and the IC does not switch to short-circuit braking when the speed approaches zero, insert a resistor
with a value from a few kΩ up to under 100kΩ at the SPCOM pin (pin 39). (Verify that insertion of this resistor
does not degrade the startup characteristics.)
The spindle driver circuit uses variable-duty soft switching to reduce motor drive noise for quiet operation.
5.2 Spindle Block Position Detection Comparator Circuit
The spindle block position detection comparator circuit is provided to detect the position of the rotor using the
back EMF generated when the motor turns. The IC determines the timing with which the output block applies
current to the motor based on the position information acquired by this circuit. Startup problems due to
comparator input noise can be resolved by inserting a capacitor (about 1000 to 4700pF) between the SPCIN pin
(pin 34) and the SPFIL pin (pin 33). Note that if this capacitor is too large, the output commutation timing may
be delayed at higher speeds and efficiency may be lowered.
5.3 VCO Circuit Constants
The LV8220FN spindle block adopts a sensorless drive technique. Sensorless drive is implemented by detecting
the back EMF signal generated by the motor and setting the commutation timing accordingly. Thus the timing
control uses the VCO signal. We recommend using the following procedure to determine the values of the VCO
circuit's external components.
(1) Connect components with provisional values.
Connect a 1µF capacitor and a 4.7MΩ resistor in parallel between the SPPD pin (pin 1) and ground, connect a
68kΩ resistor between SPMAX (pin 2) and ground, and connect a 3300pF capacitor between SPVCO (pin
32) and ground.
(2) Determine the value of the SPVCO pin (pin 32) capacitor.
Select a value such that the startup time to the target speed is the shortest and such that the variations in
startup time are minimized. If the value of this capacitor is too large, the variations in the startup time will be
excessive, and if too small, the motor may fail to turn. Since the optimal value of the SPVCO pin constant
differs with the motor characteristics and the startup current, the value of this component must be verified
again if the motor used or any circuit specifications are changed.
(3) Determine the value of the SPMAX (pin 2) resistor.
Select a resistor value such that the SPPD pin voltage is about VCC-1.0V or lower with the motor operating
at the target maximum speed. If the value of this resistor is too large, the SPPD pin voltage may rise
excessively.
(4) Determine the value of the SPPD pin (pin 1) capacitor.
If the SPFG output (pin 37) pulse signal becomes unstable at the lowest motor speed that will be used,
increase the value of the SPPD pin capacitor.
(5) Determine the value of the resistor connected between the SPPD pin (pin 1) and ground.
The LV8220FN generates a VCO control voltage that corresponds to the spindle motor speed at the SPPD pin.
When the S/S pin is used to implement intermittent drive to reduce system power consumption, the potential
of the SPPD pin in power saving mode remains fixed at the level determined by the charge stored on the
capacitor. Therefore, it is necessary to attach a large resistor (several MΩ) for voltage discharge to the SPPD
pin. Choose a value for this resistor such that the time for complete discharge is longer than the motor freerunning deceleration time. Note that if an oscilloscope probe is attached to the SPPD when determining the
value of this constant, the discharge characteristics will differ due to the probe impedance. This issue requires
care when testing in an actual system. (We recommend using an FET probe.) If intermittent drive (freerunning deceleration) is not used, this discharge resistor is not required.
No.7811-12/15
LV8220FN
5.4 Spindle FG Output Circuit
The SPFG pin (pin 37) is the spindle block FG output, and outputs a pulse signal equivalent to a single Hall
sensor FG output. This pin goes to the low level (MOS output circuit) in power saving mode and short braking
stop mode. Note that the SPFG pin is susceptible to damage from ESD, and requires care during handling. (This
only applies to the SPFG pin; the SLFG pin does not have this issue.)
6. Sled Driver Circuit
6.1 Mode Settings
The LV8220FN sled driver circuit has two modes, three-phase sensorless and three-phase stepper drive mode.
The mode is selected with the SEL pin (pin 12). The functions of this IC's S1 to S3 pins (pins 8, 9, and 10) are
switched according to the drive mode as shown in the table.
Mode settings
Operation mode
Pin name and function
SEL1
Three-phase stepping
L
Three-phase sensorless
H
S1
S2
Remarks
S3
Decoder input
F/R
BRK
SLFG outputs three Hall sensor equivalent.
-
SLFG outputs a Hall sensor equivalent
Note: When a low level is input to the S2 pin (F/R function), this circuit has the same commutation logic as the
spindle block.
This IC’s sled driver can operate in speed control (torque control) mode controlled by a PWM signal input to the
SLPWM (pin 19) pin. Like the sensorless block, torque control is applied to the sink side transistor, and the sink
side transistor is turned on (for acceleration) when the SLPWM pin is high.
6.2 Stepping Mode Operation
Set the SEL pin low to use the sled driver in three-phase stepping mode.
Sled Motor Stepping Logic (When SEL is low)
S/S
S1
S2
S3
SUO
SVO
SWO
Inner area FG
Outer area FG
Inner area
Outer area
H
L
L
L
H
L
Z
L→H
H→L
↑
↓
H
H
L
L
H
Z
L
H→L
L→H
↑
↓
H
L
H
L
Z
H
L
L→H
H→L
↑
↓
H
H
H
L
L
H
Z
H→L
L→H
↑
↓
H
L
L
H
L
Z
H
L→H
H→L
↑
↓
H
H
L
H
Z
L
H
H→L
L→H
↑
↓
H
L
H
H
Z
Z
Z
L
L
Change to
Change to
H
H
H
H
Z
Z
Z
L
L
the decoder
the decoder
L
input
input
L
×
×
×
Z
Z
Z
L
Notes: Z: Open (both the high side and low side transistors off)
The inner/outer changes follow the specifications of the Sanyo LC896442 DSP.
The stepping mode drive logic operates as shown in the table. The S1 to S3 pins (pins 8, 9, and 10) are the sled
driver decoder inputs and include internal pull-up resistors. These pins are connected to the DSP. The LV8220FN
allows the drive torque to be controlled by the signal input to the SLPWM pin (pin 19). (This circuit supports
synchronous commutation.)
The SLFG pin (pin 24) is the sled driver position detection comparator output, and has a MOS output circuit. In
stepping mode, it outputs a signal equivalent to a three-phase FG signal. This pin's output signal is used to feed
back the sled motor speed information (position information) to the DSP or microcontroller.
No.7811-13/15
LV8220FN
6.3 Sensorless Mode Operation and Determining External Component Values
When the sled driver is used in three-phase sensorless mode, set the SEL1 pin high and the SEL2 pin low.
Although basic operation in sensorless mode is the same as that of the spindle block, the sled sensorless mode
has a forward/reverse function and uses a hard switching drive method.
The S1 pin (pin 8) is used for forward/reverse switching in sled sensorless mode, and the S2 pin (pin 9) is used
for braking. The IC applies reverse torque braking when S2 is set high. (Note: this has the reverse phase input
from that of the spindle block braking pin, SPBRK.)
Like the spindle driver, reverse torque braking mode (when S2 is high) slows the motor to and adequately slow
speed, switches to short-circuit braking state, and stops. Note that when stopping the motor with the braking
function, if the timing with which this circuit switches to short-circuit braking is too fast and problems such as
the motor remaining in motion occur, the value of the resistor connected to the SLMAX pin (pin 29) must be
reduced. If the motor moves back and forth without stopping and the IC does not switch to short-circuit braking
when the speed approaches zero, insert a resistor with a value from a few kΩ up to under 100kΩ at the SLCOM
pin (pin 22). (Verify that insertion of this resistor does not degrade the startup characteristics.)
Although the sled driver can be set to the standby state by stopping the motor with the S2 (brake) pin, the internal
circuits used for sensorless drive will continue to operate. Therefore, it is desirable to set the circuit to the
standby state in stepping mode to minimize circuit current.
The procedure for determining the VCO circuit external component values for sled sensorless mode is essentially
the same as that for the spindle block VCO external components. (See the description of that procedure earlier in
this document.) For the initial provisional component values, connect a 1µF capacitor and a 4.7MΩ resistor in
parallel between the SLPD pin (pin 27) and ground, connect a 56kΩ resistor between SLMAX (pin 29) and
ground, and connect a 1500pF capacitor between SLVCO (pin 28) and ground. Then determine the optimal
capacitance for SLVCO, the optimal resistance for SLMAX, and the optimal capacitance and resistance for
SLPD.
In sled sensorless mode, the SLFG pin outputs a pulse signal equivalent to a single Hall sensor FG signal.
7. Actuator Block
The LV8220FN incorporates three H-bridge channels for use as actuator drivers for the focus and tracking systems.
The logic input pin include built-in pull-down resistors. A PWM signal is used for control, and the circuit supports
synchronous commutation.
The figures below show reference data related to the dead band during control.
LV8220FN
Actuator Small-Signal I/O Characteristics (magnified)
VCC=VS=2.3V PWM=132kHz (0-2.3V)
3
OUT[mV]
OUT[V]
LV8220FN
Actuator Small-Signal I/O Characteristics
VCC=VS=2.3V PWM=132kHz (0-2.3V)
2
100
80
60
1
40
20
0
-2.5 -2
-1.5
-1
-0.5
0
0.5
1
1.5
2
2.5
IN[V]
-1
-2
No load
50Ω
10Ω
0
-100-80
-60
-40
-20
-20
-40
-60
-80
0
20
40
60
80 100
IN[mV]
No load
50Ω
10Ω
-3
-100
The input and output are smoothed with a low-pass
filter consisting of a 1.0kΩ resistor and 2.2µF capacitor.
The input and output are smoothed with a low-pass
filter consisting of a 1.0kΩ resistor and 2.2µF capacitor.
No.7811-14/15
LV8220FN
8. Notes on PCB Pattern Design
The LV8220FN is a system driver IC implemented in a Bi-DMOS process; the IC chip includes bipolar circuits,
MOS logic circuits, and MOS drive circuits integrated on the same chip. As a result, extreme care is required with
respect to the pattern layout when designing application circuits.
1) Ground and VCC/VS wiring layout
The LV8220FN ground and power supply pins are classified as follows.
Small-signal system ground pins → GND (pin 30)
Large-signal system ground pins → PGND1 (pin 15), PGND2 (pin 46), SPGND (pin 36), SLGND (pin 25)
Small-signal system power supply pin → VCC (pin 6)
Large-signal system power supply pins → VS1 (pin 18), VS2 (pin 43), SPVS (pin 35), SLVS (pin 26)
A capacitor must be inserted, as close as possible to the IC, between the small-signal system power supply pin
(pin 6) and ground pins (pin 30).
The large-signal system ground pins (PGND system) must be connected with the shortest possible lines, and
furthermore in a manner such that there is no shared impedance with the small-signal system ground lines.
Capacitors must also be inserted, as close as possible to the IC, between the large-signal system power supply (VS
system) pins and the large-signal system ground pins.
2) Positioning the small-signal system external components
The small-signal system external components that are also connected to ground must be connected to the smallsignal system ground with lines that are as short as possible.
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
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to smoke or fire, or accidents that could cause damage to other property. When designing equipment, adopt
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limited to protective circuits and error prevention circuits for safe design, redundant design, and structural
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No part of this publication may be reproduced or transmitted in any form or by any means, electronic or
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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 Co.,Ltd. product that you intend to use.
Information (including circuit diagrams and circuit parameters) herein is for example only; it is not guaranteed
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This catalog provides information as of May, 2007. Specifications and information herein are subject
to change without notice.
PS No.7811-15/15