NSC LMD18200T

LMD18200
3A, 55V H-Bridge
General Description
The LMD18200 is a 3A H-Bridge designed for motion control
applications. The device is built using a multi-technology process which combines bipolar and CMOS control circuitry with
DMOS power devices on the same monolithic structure. Ideal
for driving DC and stepper motors; the LMD18200 accommodates peak output currents up to 6A. An innovative circuit
which facilitates low-loss sensing of the output current has
been implemented.
Features
■
■
■
■
Delivers up to 3A continuous output
Operates at supply voltages up to 55V
Low RDS(ON) typically 0.33Ω per switch at 3A
TTL and CMOS compatible inputs
■
■
■
■
■
■
No “shoot-through” current
Thermal warning flag output at 145°C
Thermal shutdown (outputs off) at 170°C
Internal clamp diodes
Shorted load protection
Internal charge pump with external bootstrap capability
Applications
■
■
■
■
■
DC and stepper motor drives
Position and velocity servomechanisms
Factory automation robots
Numerically controlled machinery
Computer printers and plotters
Functional Diagram
1056801
FIGURE 1. Functional Block Diagram of LMD18200
© 2011 National Semiconductor Corporation
10568
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LMD18200 3A, 55V H-Bridge
February 7, 2011
LMD18200
Connection Diagram and Ordering Information
1056802
11-Lead TO-220 Package
Top View
Order Number LMD18200T
See NS Package TA11B
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2
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please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
Total Supply Voltage (VS, Pin 6)
Voltage at Pins 3, 4, 5, 8 and 9
Voltage at Bootstrap Pins
(Pins 1 and 11)
Peak Output Current (200 ms)
Continuous Output Current (Note 2)
60V
12V
Operating Ratings
VOUT +16V
6A
3A
(Note 1)
Junction Temperature, TJ
VS Supply Voltage
−40°C to +125°C
+12V to +55V
Electrical Characteristics
(Note 5)
The following specifications apply for VS = 42V, unless otherwise specified. Boldface limits apply over the entire operating temperature range, −40°C ≤ TJ ≤ +125°C, all other limits are for TA = TJ = 25°C.
Symbol
Parameter
Conditions
Typ
Limit
Units
RDS(ON)
Switch ON Resistance
Output Current = 3A (Note 6)
0.33
0.40/0.6
Ω (max)
RDS(ON)
Switch ON Resistance
Output Current = 6A (Note 6)
0.38
0.45/0.6
Ω (max)
VCLAMP
Clamp Diode Forward Drop
Clamp Current = 3A (Note 6)
1.2
1.5
V (max)
VIL
Logic Low Input Voltage
Pins 3, 4, 5
−0.1
V (min)
0.8
V (max)
IIL
Logic Low Input Current
VIN = −0.1V, Pins = 3, 4, 5
−10
μA (max)
VIH
Logic High Input Voltage
Pins 3, 4, 5
2
V (min)
IIH
Logic High Input Current
VIN = 12V, Pins = 3, 4, 5
Current Sense Output
IOUT = 1A (Note 8)
377
12
V (max)
10
μA (max)
325/300
μA (min)
425/450
μA (max)
±9
%
9
11
V (min)
V (max)
Current Sense Linearity
1A ≤ IOUT ≤ 3A (Note 7)
Undervoltage Lockout
Outputs turn OFF
TJW
Warning Flag Temperature
Pin 9 ≤ 0.8V, IL = 2 mA
145
VF(ON)
Flag Output Saturation Voltage
TJ = TJW, IL = 2 mA
0.15
IF(OFF)
Flag Output Leakage
VF = 12V
0.2
TJSD
Shutdown Temperature
Outputs Turn OFF
170
IS
Quiescent Supply Current
All Logic Inputs Low
13
tDon
Output Turn-On Delay Time
Sourcing Outputs, IOUT = 3A
300
ns
Sinking Outputs, IOUT = 3A
300
ns
Sourcing Outputs, IOUT = 3A
100
ns
Sinking Outputs, IOUT = 3A
80
ns
Sourcing Outputs, IOUT = 3A
200
ns
Sinking Outputs, IOUT = 3A
200
ns
Sourcing Outputs, IOUT = 3A
75
ns
Sinking Outputs, IOUT = 3A
70
ns
ton
tDoff
toff
Output Turn-On Switching Time
Output Turn-Off Delay Times
Output Turn-Off Switching Times
±6
°C
V
10
μA (max)
25
mA (max)
°C
Bootstrap Capacitor = 10 nF
Bootstrap Capacitor = 10 nF
tpw
Minimum Input Pulse Width
Pins 3, 4 and 5
1
μs
tcpr
Charge Pump Rise Time
No Bootstrap Capacitor
20
μs
3
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LMD18200
Power Dissipation (Note 3)
25W
Power Dissipation (TA = 25°C, Free Air)
3W
Junction Temperature, TJ(max)
150°C
ESD Susceptibility (Note 4)
1500V
Storage Temperature, TSTG
−40°C to +150°C
Lead Temperature (Soldering, 10 sec.)
300°C
Absolute Maximum Ratings (Note 1)
LMD18200
Electrical Characteristics Notes
Note 1: Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. DC and AC electrical specifications do not apply when operating
the device beyond its rated operating conditions.
Note 2: See Application Information for details regarding current limiting.
Note 3: The maximum power dissipation must be derated at elevated temperatures and is a function of TJ(max), θJA, and TA. The maximum allowable power
dissipation at any temperature is PD(max) = (TJ(max) − TA)/θJA, or the number given in the Absolute Ratings, whichever is lower. The typical thermal resistance from
junction to case (θJC) is 1.0°C/W and from junction to ambient (θJA) is 30°C/W. For guaranteed operation TJ(max) = 125°C.
Note 4: Human-body model, 100 pF discharged through a 1.5 kΩ resistor. Except Bootstrap pins (pins 1 and 11) which are protected to 1000V of ESD.
Note 5: All limits are 100% production tested at 25°C. Temperature extreme limits are guaranteed via correlation using accepted SQC (Statistical Quality Control)
methods. All limits are used to calculate AOQL, (Average Outgoing Quality Level).
Note 6: Output currents are pulsed (tW < 2 ms, Duty Cycle < 5%).
Note 7: Regulation is calculated relative to the current sense output value with a 1A load.
Note 8: Selections for tighter tolerance are available. Contact factory.
Typical Performance Characteristics
RDS(ON) vs Temperature
VSAT vs Flag Current
1056816
1056817
RDS(ON) vs
Supply Voltage
Supply Current vs
Supply Voltage
1056819
1056818
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4
LMD18200
Supply Current vs
Frequency (VS = 42V)
Supply Current vs
Temperature (VS = 42V)
1056821
1056820
Current Sense Output
vs Load Current
Current Sense
Operating Region
1056823
1056822
Test Circuit
1056808
5
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LMD18200
Switching Time Definitions
1056809
145°C (junction temperature). However the chip will not shut
itself down until 170°C is reached at the junction.
Pin 10, OUTPUT 2: Half H-bridge number 2 output.
Pin 11, BOOTSTRAP 2 Input: Bootstrap capacitor pin for
Half H-bridge number 2. The recommended capacitor (10 nF)
is connected between pins 10 and 11.
Pinout Description
(See Connection Diagram)
Pin 1, BOOTSTRAP 1 Input: Bootstrap capacitor pin for half
H-bridge number 1. The recommended capacitor (10 nF) is
connected between pins 1 and 2.
Pin 2, OUTPUT 1: Half H-bridge number 1 output.
Pin 3, DIRECTION Input: See Table 1. This input controls
the direction of current flow between OUTPUT 1 and OUTPUT 2 (pins 2 and 10) and, therefore, the direction of rotation
of a motor load.
Pin 4, BRAKE Input: See Table 1. This input is used to brake
a motor by effectively shorting its terminals. When braking is
desired, this input is taken to a logic high level and it is also
necessary to apply logic high to PWM input, pin 5. The drivers
that short the motor are determined by the logic level at the
DIRECTION input (Pin 3): with Pin 3 logic high, both current
sourcing output transistors are ON; with Pin 3 logic low, both
current sinking output transistors are ON. All output transistors can be turned OFF by applying a logic high to Pin 4 and
a logic low to PWM input Pin 5; in this case only a small bias
current (approximately −1.5 mA) exists at each output pin.
Pin 5, PWM Input: See Table 1. How this input (and DIRECTION input, Pin 3) is used is determined by the format of the
PWM Signal.
Pin 6, VS Power Supply
Pin 7, GROUND Connection: This pin is the ground return,
and is internally connected to the mounting tab.
Pin 8, CURRENT SENSE Output: This pin provides the
sourcing current sensing output signal, which is typically
377 μA/A.
Pin 9, THERMAL FLAG Output: This pin provides the thermal warning flag output signal. Pin 9 becomes active-low at
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TABLE 1. Logic Truth Table
PWM
Dir
Brake
H
H
L
H
H
L
H
L
X
H
L
X
L
L
L
H
H
H
Active Output Drivers
Source 1, Sink 2
Sink 1, Source 2
Source 1, Source 2
Source 1, Source 2
Sink 1, Sink 2
NONE
Application Information
TYPES OF PWM SIGNALS
The LMD18200 readily interfaces with different forms of PWM
signals. Use of the part with two of the more popular forms of
PWM is described in the following paragraphs.
Simple, locked anti-phase PWM consists of a single, variable duty-cycle signal in which is encoded both direction and
amplitude information (see Figure 2). A 50% duty-cycle PWM
signal represents zero drive, since the net value of voltage
(integrated over one period) delivered to the load is zero. For
the LMD18200, the PWM signal drives the direction input (pin
3) and the PWM input (pin 5) is tied to logic high.
6
LMD18200
1056804
FIGURE 2. Locked Anti-Phase PWM Control
Sign/magnitude PWM consists of separate direction (sign)
and amplitude (magnitude) signals (see Figure 3). The (absolute) magnitude signal is duty-cycle modulated, and the
absence of a pulse signal (a continuous logic low level) rep-
resents zero drive. Current delivered to the load is proportional to pulse width. For the LMD18200, the DIRECTION
input (pin 3) is driven by the sign signal and the PWM input
(pin 5) is driven by the magnitude signal.
1056805
FIGURE 3. Sign/Magnitude PWM Control
tween transitions of the Direction, Brake, and/or PWM input
signals. A conservative approach is be sure there is at least
500ns delay between the end of the first transition and the
beginning of the second transition. See Figure 4.
SIGNAL TRANSITION REQUIREMENTS
To ensure proper internal logic performance, it is good practice to avoid aligning the falling and rising edges of input
signals. A delay of at least 1 µsec should be incorporated be-
7
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LMD18200
1056824
FIGURE 4. Transitions in Brake, Direction, or PWM Must Be Separated By At Least 1 µsec
ing high load currents a greater amount of supply bypass
capacitance (in general at least 100 μF per Amp of load current) is required to absorb the recirculating currents of the
inductive loads.
USING THE CURRENT SENSE OUTPUT
The CURRENT SENSE output (pin 8) has a sensitivity of 377
μA per ampere of output current. For optimal accuracy and
linearity of this signal, the value of voltage generating resistor
between pin 8 and ground should be chosen to limit the maximum voltage developed at pin 8 to 5V, or less. The maximum
voltage compliance is 12V.
It should be noted that the recirculating currents (free wheeling currents) are ignored by the current sense circuitry. Therefore, only the currents in the upper sourcing outputs are
sensed.
CURRENT LIMITING
Current limiting protection circuitry has been incorporated into
the design of the LMD18200. With any power device it is important to consider the effects of the substantial surge currents through the device that may occur as a result of shorted
loads. The protection circuitry monitors this increase in current (the threshold is set to approximately 10 Amps) and shuts
off the power device as quickly as possible in the event of an
overload condition. In a typical motor driving application the
most common overload faults are caused by shorted motor
windings and locked rotors. Under these conditions the inductance of the motor (as well as any series inductance in the
VCC supply line) serves to reduce the magnitude of a current
surge to a safe level for the LMD18200. Once the device is
shut down, the control circuitry will periodically try to turn the
power device back on. This feature allows the immediate return to normal operation in the event that the fault condition
has been removed. While the fault remains however, the device will cycle in and out of thermal shutdown. This can create
voltage transients on the VCC supply line and therefore proper
supply bypassing techniques are required.
The most severe condition for any power device is a direct,
hard-wired (“screwdriver”) long term short from an output to
ground. This condition can generate a surge of current
through the power device on the order of 15 Amps and require
the die and package to dissipate up to 500 Watts of power for
the short time required for the protection circuitry to shut off
the power device. This energy can be destructive, particularly
at higher operating voltages (>30V) so some precautions are
in order. Proper heat sink design is essential and it is normally
necessary to heat sink the VCC supply pin (pin 6) with 1 square
inch of copper on the PCB.
USING THE THERMAL WARNING FLAG
The THERMAL FLAG output (pin 9) is an open collector transistor. This permits a wired OR connection of thermal warning
flag outputs from multiple LMD18200's, and allows the user
to set the logic high level of the output signal swing to match
system requirements. This output typically drives the interrupt
input of a system controller. The interrupt service routine
would then be designed to take appropriate steps, such as
reducing load currents or initiating an orderly system shutdown. The maximum voltage compliance on the flag pin is
12V.
SUPPLY BYPASSING
During switching transitions the levels of fast current changes
experienced may cause troublesome voltage transients
across system stray inductance.
It is normally necessary to bypass the supply rail with a high
quality capacitor(s) connected as close as possible to the
VS Power Supply (Pin 6) and GROUND (Pin 7). A 1 μF highfrequency ceramic capacitor is recommended. Care should
be taken to limit the transients on the supply pin below the
Absolute Maximum Rating of the device. When operating the
chip at supply voltages above 40V a voltage suppressor (transorb) such as P6KE62A is recommended from supply to
ground. Typically the ceramic capacitor can be eliminated in
the presence of the voltage suppressor. Note that when drivwww.national.com
8
Typical Applications
FIXED OFF-TIME CONTROL
This circuit controls the current through the motor by applying
an average voltage equal to zero to the motor terminals for a
fixed period of time, whenever the current through the motor
exceeds the commanded current. This action causes the motor current to vary slightly about an externally controlled average level. The duration of the Off-period is adjusted by the
resistor and capacitor combination of the LM555. In this circuit
the Sign/Magnitude mode of operation is implemented (see
Types of PWM Signals).
1056806
FIGURE 5. Internal Charge Pump Circuitry
For higher switching frequencies, the LMD18200 provides for
the use of external bootstrap capacitors. The bootstrap principle is in essence a second charge pump whereby a large
value capacitor is used which has enough energy to quickly
charge the parasitic gate input capacitance of the power device resulting in much faster rise times. The switching action
is accomplished by the power switches themselves Figure
6. External 10 nF capacitors, connected from the outputs to
the bootstrap pins of each high-side switch provide typically
less than 100 ns rise times allowing switching frequencies up
to 500 kHz.
1056807
FIGURE 6. Bootstrap Circuitry
9
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LMD18200
INTERNAL PROTECTION DIODES
A major consideration when switching current through inductive loads is protection of the switching power devices from
the large voltage transients that occur. Each of the four
switches in the LMD18200 have a built-in protection diode to
clamp transient voltages exceeding the positive supply or
ground to a safe diode voltage drop across the switch.
The reverse recovery characteristics of these diodes, once
the transient has subsided, is important. These diodes must
come out of conduction quickly and the power switches must
be able to conduct the additional reverse recovery current of
the diodes. The reverse recovery time of the diodes protecting
the sourcing power devices is typically only 70 ns with a reverse recovery current of 1A when tested with a full 6A of
forward current through the diode. For the sinking devices the
recovery time is typically 100 ns with 4A of reverse current
under the same conditions.
INTERNAL CHARGE PUMP AND USE OF BOOTSTRAP
CAPACITORS
To turn on the high-side (sourcing) DMOS power devices, the
gate of each device must be driven approximately 8V more
positive than the supply voltage. To achieve this an internal
charge pump is used to provide the gate drive voltage. As
shown in Figure 5, an internal capacitor is alternately switched
to ground and charged to about 14V, then switched to V supply thereby providing a gate drive voltage greater than V
supply. This switching action is controlled by a continuously
running internal 300 kHz oscillator. The rise time of this drive
voltage is typically 20 μs which is suitable for operating frequencies up to 1 kHz.
LMD18200
1056810
FIGURE 7. Fixed Off-Time Control
1056811
FIGURE 8. Switching Waveforms
LM3524D is a general purpose PWM controller. The relationship of peak motor current to adjustment voltage is shown in
Figure 10.
TORQUE REGULATION
Locked Anti-Phase Control of a brushed DC motor. Current
sense output of the LMD18200 provides load sensing. The
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10
LMD18200
1056812
FIGURE 9. Locked Anti-Phase Control Regulates Torque
1056813
FIGURE 10. Peak Motor Current
vs Adjustment Voltage
of motor speed to the speed adjustment control voltage is
shown in Figure 12.
VELOCITY REGULATION
Utilizes tachometer output from the motor to sense motor
speed for a locked anti-phase control loop. The relationship
11
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LMD18200
1056814
FIGURE 11. Regulate Velocity with Tachometer Feedback
1056815
FIGURE 12. Motor Speed vs
Control Voltage
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LMD18200
Physical Dimensions inches (millimeters) unless otherwise noted
11-Lead TO-220 Power Package (T)
Order Number LMD18200T
NS Package Number TA11B
13
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LMD18200 3A, 55V H-Bridge
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