TOSHIBA TA7259F

TA7259P/F/FG
TOSHIBA BIPOLAR LINEAR INTEGRATED CIRCUIT SILICON MONOLITHIC
TA7259P, TA7259F/FG
3-PHASE BRUSHLESS DC MOTOR DRIVER IC
The TA7259P/F/FG is a 3−phase Bi-directional motor driver IC.
It designed as an output driver for motors in VTR (capstan,
cylinder, and reel), tape deck, floppy disk, and record player
applications.
To detect position, use of a position sensing device is
recommended.
FEATURES
z Wide operating supply voltage range: VCC (opr.) MIN. = 7 V
z Forward and reverse rotation is controlled simply by means of a
CW / CCW control signal fed into FRS.
z High sensitivity of position sensing amplifier.
(VH = 10 mV (Typ.), TOSHIBA Ga−As Hall sensor “THS” series
is recommended.
z 3−phase Bi-directional driver and output current up to ±1.2 A.
z Few external parts required.
z Surge-protect diode connected for all input terminals (position
sensing, control, CW / CCW control inputs).
Weight
HDIP14−P−500−2.54A : 3.00 g (Typ.)
HSOP20−P−450−1.00 : 0.79 g (Typ.)
The TA7259FG is a Pb free product.
The TA7259P is an Sn-plated product including Pb.
The following conditions apply to solderability:
*Solderability
1. Use of Sn-37Pb solder bath
*solder bath temperature = 230°C
*dipping time = 5 seconds
*number of times = once
*use of R-type flux
2. Use of Sn-3.0Ag-0.5Cu solder bath
*solder bath temperature = 245°C
*dipping time = 5 seconds
*the number of times = once
*use of R-type flux
1
2006-4-14
TA7259P/F/FG
BLOCK DIAGRAM
TA7259P/TA7259F/FG
Control input
CW/CCW switch
Position sensing input
PIN FUNCTION
PIN No.
SYMBOL
FUNCTION DESCRIPTION
P TYPE
F/FG TYPE
1
1
Hb +
b−phase Hall Amp. positive input terminal
2
2
Hb −
b−phase Hall Amp. negative input terminal
3
3
Hc +
c−phase Hall Amp. positive input terminal
4
5
H−
c−phase Hall Amp. negative input terminal
5
10
RF
Output current detection terminal
6
6
Lc
c−phase drive output terminal
7
11
Lb
b−phase drive output terminal
8
12
VCC
9
13
La
10
15
FRS
Forward / Reverse / Stop switch terminal
11
16
VIN −
Control Amp, negative input terminal
12
18
VIN +
Control Amp, positive input terminal
13
19
Ha +
a−phase Hall Amp. positive input terminal
14
20
Ha −
a−phase Hall Amp. negative input terminal
Fin
Fin
GND
GND Terminal
Power supply input terminal
a−phase drive output terminal
F/FG type: NO. 4, 7, 8, 9, 14, 17 pins are no connection.
2
2006-4-14
TA7259P/F/FG
INPUT vs. OUTPUT
VNF declares RF voltage drop.
In star-connection;
VNF =RF × IL
(IL: Coil current)
Refer to the diagram below.
When VIN+ and VIN- pins short-circuit or when V11 is equal to or greater than V12, rotating becomes zero torque.
However, zero torque status is also achieved by setting the FRS input pin to the specified voltage or open status. In
this case, power consumption is reduced.
3
2006-4-14
TA7259P/F/FG
FUNCTION
FRS
(10 PIN)
L
H
M
Ha
POSITION SENSING INPUT
Hb
Hc
La
COIL OUTPUT
Lb
Lc
1
0
1
H
L
M
1
0
0
H
M
L
1
1
0
M
H
L
0
1
0
L
H
M
0
1
1
L
M
H
0
0
1
M
L
H
1
0
1
L
H
M
1
0
0
L
M
H
1
1
0
M
L
H
0
1
0
H
L
M
0
1
1
H
M
L
0
0
1
M
H
L
1
0
1
1
0
0
1
1
0
0
1
0
0
1
1
0
0
1
High Impedance
Notes)
・ Position sensing input;
“1”: Energizing +10mV or more to the positive side of each position sensing input.
“0”: Energizing −10mV or less to the negative side of each position sensing input.
In this case, DC voltage must be within the same-phase voltage range of the position sensing input.
・
Coil output;
1
“H”: VCC−
VSAT1
2
“M”: ≒ VCC
“L”: VSAT2
・
FRS input;
“L”: Applied voltage within the specified range of VF.
“H”: Applied voltage within the specified range of VR.
“M”: Applied voltage within the specified range of VS.
During testing, necessary voltage must be applied to the control input (VIN+, VIN-) and the circuit must be
driven status.
4
2006-4-14
TA7259P/F/FG
Control signal input
In the initial state of the TA7259P/F/FG, the control voltage is usually input either by an F/V inverter or
such like, where the voltage is in proportion or inverse proportion to the number of rotations, or independently.
Though output (RF pin) gain from the TA7259 control is specified in the table as 15 times, it can be reduced
to improve the characteristics of W/F etc. by applying NF.
An example of the application is shown below.
Whether NF is applied or not, the DC voltage (VIN+ and VIN−) of the control input (VIN+ pin and VIN− pin)
must be within the specified range (2.0 to VCC−2.5V). When the input DC level and F/V conversion output
(control output) cannot interface with the IC input, input DC level shift and attenuator before IC input.
One example is shown in Figure 1−c.
a)
Positive input
TA7259P/F/FG
VZ(5V is recommended)
Figure 1-a
b)
Negative input
TA7259P/F/FG
Figure 1-b
Control input
Input pin
Figure 1-c
Control output is level shifted with DC content by zenner diode and attenuator, with control signal content by R1
and R2.
5
2006-4-14
TA7259P/F/FG
Position sensing drive
Both constant current drive and constant voltage drive are available because the same-phase voltage range
of the position sensing device is wide. (Spec.: 2∼VCC−2.5V. When VCC is 12V, the range is 2 to 9.5V).
We recommend use of the TOSHIBA THS series of Ga-As position sensing devices.
In comparison with an In-Sb position sensor, the Ga−As sensor is mechanically stronger, has better
temperature characteristics, and is less prone to saturation by magnetism or current. However, its application
has been limited by its lower sensitivity when compared with the In-Sb type.
As for the TA7259, a Ga-As position sensor can be applied by improving the sensitivity of its input amp and
reducing the offset. When W/F characteristics are poor, increasing the position sensing input may be effective.
However, take care not to exceed the maximum permissible input.
Position sensing drive (1)
(For details, refer to the technical documents of the Toshiba THS series of Ga-As position sensing devices.)
6
2006-4-14
TA7259P/F/FG
ABSOLUTE MAXIMUM RATINGS (Ta = 25°C)
CHARACTERISTIC
SYMBOL
RATING
UNIT
Supply Voltage
VCC
26
V
Output Current
IO
1.2
A
Power Dissipation
TA7259P
TA7259F/FG
2.3
PD(Note)
W
1.0
Operating Temperature
Topr
−30~75
°C
Storage Temperature
Tstg
−55~150
°C
Note:
IC only.
ELECTRICAL CHARACTERISTICS (Unless otherwise specified, VCC = 12 V, Ta = 25°C)
CHARACTERISTIC
SYMBOL
TEST
CIR−
CUIT
ICC1
Quiescent Current
ICC2
1
ICC3
Input Offset Voltage
VIO
1
Residual Output Voltage
VOR
1
GV
1
Upper
VSAT1
2
Lower
VSAT2
2
Upper
IOC1
―
Lower
IOC2
―
Position Sensing Input Sensitivity
VH
1
Maximum Position Sensing Input
Voltage
VH MAX.
Position
Control
Cut−off Current
Input Operating Voltage
Rotation Control Input
Voltage (FRS input)
MIN
TYP.
MAX
FRS open
2
4
7
FRS = 5 V
2
5
9
VCC = 22 V, FRS = GND
2
5
9
―
40
―
mV
―
VIN −
= VIN + = 7 V
UNIT
mA
―
0
10
mV
―
15.0
―
―
―
1.0
1.5
―
0.4
1.0
―
―
20
―
―
20
―
―
10
―
mA
1
―
―
―
400
mVp−p
CMRH
1
―
2.0
―
VCC − 2.5
CMRC
1
―
2.0
―
VCC − 2.5
CW
VF
1
―
0
0.4
STOP
VS
1
―
2.5
3.0
3.5
CCW
VR
1
―
4.5
5.0
5.8
Voltage Gain
Saturation Voltage
TEST CONDITION
―
IL = 400 mA
VC = 20 V
7
V
µA
V
V
2006-4-14
TA7259P/F/FG
Test circuit 1
Control input
(OFF in testing Icc)
TA7259
Position
P/F/FG
sensing
FRS input
device
Test circuit 2
Control input
Testing upper
Testing under
TA7259
Position
P/F/FG
sensing
device
8
2006-4-14
TA7259P/F/FG
Notes on handling the IC
Motor drive ICs are easily affected by parasitic vibration and unnecessary feedback. This is because the
number of high impedance pins, such as position sensing inputs and control signal inputs, is large, and the
output current value is high and switched.
Moreover, because it is coil loading, care must be taken not to allow the impulse to destroy the IC during
ON/OFF switching. Especially when using a high voltage supply (Vcc is 18V or more), care must be taken not to
apply voltage and current to the output transistor which exceed the specification. Use of a supply voltageof 18V
or less is recommended. Pay particular attention to the notes above when using a supply voltage over 18V.
(1) Notes in designing reliability
ⅰ)
ⅱ)
ⅲ)
ⅳ)
Do not expose the output transistor of the internal IC to high voltage and current,
especially, in motor lock status, ON/OFF switching of Vcc, output short-circuiting, etc.)
The output condenser for ringing absorption should be as small as possible because the output
transistor can be destroyed by the charge-discharge current of this condenser. When there is a
problem, adjusting the capacity of the condenser, the connecting position and the connecting method
(delta or star), and inserting a series resistor (of a few Ω to dozens of Ω) to the condenser and series
should provide the oscillating protection explained later.
In mounting to the print-board, do not stress the FIN, and solder for only a few seconds at 260℃.
Using the large earth area of the print-board to release heat from the FIN is effective in ensuring
reliability.
(2) Notes in wiring
ⅰ)
To protect from parasitic vibration, design the print-pattern following the method below.
The output coil current path must be separated from other GND lines because a switched high
current flows in this path. It is very important that the line (RF pin→RF resister→GND) should not
be of a common impedance with other circuits.
If the above is impossible or the oscillation cannot be removed completely, connect the condenser
(0.01∼0.1µF) and RF in parallel.
TA7259P/F/FG
Avoid common impedance with other circuits
Fig.
図 2.2
9
2006-4-14
TA7259P/F/FG
ⅱ)
The drive current path of the position sensing device should be connected to the GND independently.
It should be separated especially from the output current path.
If there is a plunge in position sensing device, insert the condenser (0.05~1µF) between + pin and –
pin of each position sensing device.
If there is a plunge in control input, insert the condenser (0.001∼0.1µF) between this pin and the
GND.
TA7259P/F/FG
Do not have common impedance with other
circuits.
Fig.
図33.
ⅲ)
If upper oscillation (5MHz or more) is found, connect the condensers commonly from each coil output
and then insert the condenser (C = 0.01∼0.1µF) between this connecting point and RF pin. (Fig.4−a)
Aside from using a ringing absorbing condenser, consider a different method to connect the
condenser between each coil output and RF pin. (Fig 4−b)
TA7259
P/F/FG
Fig.
図 4-a
4-a
ⅳ)
Fig.
4-b
図 4-b
Make sure to take the power supply from VCC pin
(“8” pin) directly. Design the circuit not to have the
common impedance toward GND.
Use of C2 (0.01∼0.1µF) is also effective.
TA7259
P/F/FG
Fig.図55.
10
2006-4-14
TA7259P/F/FG
(3) Connecting condenser for output ringing absorption
We recommend connecting a condenser between each coil and the GND for output ringing absorption .
However, other methods below can be also applied to prevent oscillation and destruction.
ⅰ) Changing capacity.
ⅱ) Delta connection (Fig.6−a)
ⅲ) Connect to VCC, not to the GND. (Fig. 6−b) In this case; take care not to let the IC be destroyed.
If voltage-current locus is beyond the ASO, series resistance or equivalent must be inserted.
ⅳ) Connect to RF pin.
ⅴ) Insert a resistance between condenser and series. (Fig. 6−c)
ⅵ) Combination of ⅰ), ⅱ), ⅲ), and ⅳ).
TA7259
TA7259
P/F/FG
P/F/FG
Use bipolar condenser.
Fig. 6-a
Fig. 6-b
TA7259
P/F/FG
Fig. 6-c
Others
The output transistor of the IC can be destroyed when the capacity of the output condenser or its connection is
not appropriate. To prevent destruction, confirm the voltage-current locus of the output transistor gained from
the test (see the figure below) is within the ASO. It is especially important to measure the output transistor in
SW’s ON/OFF timing and the sequence of normal rotation, reverse rotation, and normal rotation.
Current probe
To Y-axis of oscilloscope
Applying not only La but Lb
and Lc is recommended.
Current- voltage locus
To X-axis of oscilloscope
Fig. 7
11
2006-4-14
TA7259P/F/FG
Application circuit 1
Control signal input
Normal/Reverse SW
TA7259
P/F/FG
Position detection.
Constant voltage/
constant current drive.
(Constant current drive
is shown in this figure.)
※ 1:
※ 2:
※ 3:
Hall supply
Coil current
VZ of zenner diode should correspond to DC level of control signal input.
(VZ = 2.5∼9V. In considering temperature characteristics, applying 5V is recommended. DC voltage of
negative control input (VIN−pin) equals VZ+RF・IL.
RF is determined by the coil impedance, F/V converter voltage (control input), and necessary starting torque.
However, please apply within the range of 0.3 to 5Ω.
Connect this condenser when there is a plunge in control input.
Application circuit 2
Control signal input
TA7259
Position sensing device
P/F/FG
Normal/Reverse SW
Note:
Utmost care is necessary in the design of the output, VCC, VM, and GND lines since the IC may be
destroyed by short-circuiting between outputs, air contamination faults, or faults due to improper grounding, or
by short-circuiting between contiguous pins.
12
2006-4-14
TA7259P/F/FG
TA7259F/FG
TA7259P
13
2006-4-14
TA7259P/F/FG
PACKAGE DIMENSIONS
HDIP14−P−500−2.54A
Unit: mm
Weight: 3.00 g (Typ.)
14
2006-4-14
TA7259P/F/FG
HSOP20−P−450−1.00
Unit: mm
Weight: 0.79 g (Typ.)
15
2006-4-14
TA7259P/F/FG
Notes on Contents
1. Block Diagrams
Some of the functional blocks, circuits, or constants in the block diagram may be omitted or simplified
for explanatory purposes.
2. Equivalent Circuits
The equivalent circuit diagrams may be simplified or some parts of them may be omitted for
explanatory purposes.
3. Timing Charts
Timing charts may be simplified for explanatory purposes.
4. Application Circuits
The application circuits shown in this document are provided for reference purposes only. Thorough
evaluation is required, especially at the mass production design stage.
Toshiba does not grant any license to any industrial property rights by providing these examples of
application circuits.
5. Test Circuits
Components in the test circuits are used only to obtain and confirm the device characteristics. These
components and circuits are not guaranteed to prevent malfunction or failure from occurring in the
application equipment.
IC Usage Considerations
Notes on handling of ICs
[1] The absolute maximum ratings of a semiconductor device are a set of ratings that must not be
exceeded, even for a moment. Do not exceed any of these ratings.
Exceeding the rating(s) may cause device breakdown, damage or deterioration, and may result in
injury by explosion or combustion.
[2] Use an appropriate power supply fuse to ensure that a large current does not continuously flow in
case of over-current and/or IC failure. The IC will break down completely when used under
conditions that exceed its absolute maximum ratings, when the wiring is routed improperly or when
an abnormal pulse noise occurs from the wiring or load, causing a large current to continuously flow
and the breakdown lead to smoke or ignition. To minimize the effects of the flow of a large current
in case of breakdown, appropriate settings, such as fuse capacity, fusing time and insertion circuit
location, are required.
[3] If your design includes an inductive load such as a motor coil, incorporate a protection circuit into
the design to prevent device malfunction or breakdown caused by the current resulting from the
inrush current at power ON or the negative current resulting from the back electromotive force at
power OFF. IC breakdown may cause injury, smoke or ignition.
Use a stable power supply with ICs with built-in protection functions. If the power supply is
unstable, the protection function may not operate, causing IC breakdown. IC breakdown may cause
injury, smoke or ignition.
[4] Do not insert devices in the wrong orientation or incorrectly.
Make sure that the positive and negative terminals of power supplies are connected properly.
Otherwise, the current or power consumption may exceed the absolute maximum rating, and
exceeding the rating(s) may cause device breakdown, damage or deterioration, and may result in
injury by explosion or combustion.
In addition, do not apply current to any device that is incorrectly inserted or oriented, even for an
instant.
16
2006-4-14
TA7259P/F/FG
Points to remember on handling of ICs
(1) Heat Radiation Design
In using an IC with large current flow such as a power amp, regulator or driver, please design the
device so that heat is appropriately radiated, so as not to exceed the specified junction temperature
(TJ) at any time and condition. These ICs generate heat even during normal use. An inadequate IC
heat radiation design can lead to a decrease in IC life, deterioration of IC characteristics or IC
breakdown. In addition, please design the device taking into consideration the effect of IC heat
radiation on peripheral components.
(2) Back-EMF
When a motor rotates in the reverse direction, stops or slows down abruptly, a current flows back to the motor’s
power supply due to the effect of back-EMF. If the current sink capability of the power supply is small, the
device’s motor power supply and output pins might be exposed to conditions beyond maximum ratings. To avoid
this problem, take the effect of back-EMF into consideration in system design.
17
2006-4-14
TA7259P/F/FG
18
2006-4-14