NSC LM1875TLB02

LM1875
20W Audio Power Amplifier
General Description
Features
The LM1875 is a monolithic power amplifier offering very low
distortion and high quality performance for consumer audio
applications.
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The LM1875 delivers 20 watts into a 4Ω or 8Ω load on ± 25V
supplies. Using an 8Ω load and ± 30V supplies, over 30
watts of power may be delivered. The amplifier is designed
to operate with a minimum of external components. Device
overload protection consists of both internal current limit and
thermal shutdown.
The LM1875 design takes advantage of advanced circuit
techniques and processing to achieve extremely low distortion levels even at high output power levels. Other outstanding features include high gain, fast slew rate and a wide
power bandwidth, large output voltage swing, high current
capability, and a very wide supply range. The amplifier is internally compensated and stable for gains of 10 or greater.
Connection Diagram
Up to 30 watts output power
AVO typically 90 dB
Low distortion: 0.015%, 1 kHz, 20 W
Wide power bandwidth: 70 kHz
Protection for AC and DC short circuits to ground
Thermal protection with parole circuit
High current capability: 4A
Wide supply range 16V-60V
Internal output protection diodes
94 dB ripple rejection
Plastic power package TO-220
Applications
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High performance audio systems
Bridge amplifiers
Stereo phonographs
Servo amplifiers
Instrument systems
Typical Applications
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Front View
Package
Ordering Info
NSC Package
Number
For Straight Leads
LM1875T
SL108949
T05A
For Stagger Bend
LM1875T
LB03
T05D
For 90˚ Stagger Bend
LM1875T
LB05
T05E
For 90˚ Stagger Bend
LM1875T
LB02
TA05B
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© 1999 National Semiconductor Corporation
DS005030
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LM1875 20W Audio Power Amplifier
February 1999
Absolute Maximum Ratings (Note 1)
Supply Voltage
Input Voltage
Storage Temperature
Junction Temperature
Lead Temperature
(Soldering, 10 seconds)
θJC
θJA
60V
−VEE to VCC
−65˚C to + 150˚C
150˚C
260˚C
3˚C
73˚C
Electrical Characteristics
VCC = +25V, −VEE = −25V, TAMBIENT = 25˚C, RL = 8Ω, AV = 20 (26 dB), fo = 1 kHz, unless otherwise specified.
Parameter
Supply Current
Output Power (Note 2)
THD (Note 2)
Conditions
Typical
Tested Limits
Units
70
100
mA
POUT = 0W
THD = 1%
25
POUT = 20W, fo = 1 kHz
POUT = 20W, fo = 20 kHz
POUT = 20W, RL = 4Ω, fo = 1 kHz
POUT = 20W, RL = 4Ω, fo = 20 kHz
Offset Voltage
Input Bias Current
Input Offset Current
W
%
0.015
0.05
0.4
%
%
0.022
0.07
0.6
%
±1
± 0.2
± 15
±2
± 0.5
mV
0
µA
µA
Gain-Bandwidth Product
fo = 20 kHz
5.5
Open Loop Gain
DC
90
PSRR
VCC, 1 kHz, 1 Vrms
95
52
dB
VEE, 1 kHz, 1 Vrms
83
52
dB
20W, 8Ω, 70 kHz BW
VOUT = VSUPPLY −10V
RS = 600Ω, CCIR
4
Max Slew Rate
Current Limit
Equivalent Input Noise Voltage
MHz
dB
8
V/µs
3
3
A
µVrms
Note 1: “Absolute Maximum Ratings” indicate limits beyond which damage to the device may occur. Operating Ratings indicate conditions for which the device is
functional, but do not guarantee specific performance limits.
Note 2: Assumes the use of a heat sink having a thermal resistance of 1˚C/W and no insulator with an ambient temperature of 25˚C. Because the output limiting
circuitry has a negative temperature coefficient, the maximum output power delivered to a 4Ω load may be slightly reduced when the tab temperature exceeds 55˚C.
Typical Applications
Typical Single Supply Operation
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Typical Performance Characteristics
THD vs Power Output
THD vs Frequency
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Power Output vs Supply
Voltage
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Supply Current vs Supply
Voltage
Device Dissipation vs
Ambient Temperature†
PSRR vs Frequency
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†φINTERFACE = 1˚C/W.
See Application Hints.
Power Dissipation vs
Power Output
Power Dissipation vs
Power Output
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IOUT vs VOUT-Current Limit/
Safe Operating Area Boundary
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Typical Performance Characteristics
(Continued)
Open Loop Gain and
Phase vs Frequency
Input Bias Current
vs Supply Voltage
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Note 3: Thermal shutdown with infinite heat sink
Note 4: Thermal shutdown with 1˚C/W heat sink
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Schematic Diagram
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the external power supply, while the maximum current
passed by the output devices is usually limited by internal
circuitry to some fixed value. Short-term power dissipation is
usually not limited in monolithic audio power amplifiers, and
this can be a problem when driving reactive loads, which
may draw large currents while high voltages appear on the
output transistors. The LM1875 not only limits current to
around 4A, but also reduces the value of the limit current
when an output transistor has a high voltage across it.
When driving nonlinear reactive loads such as motors or
loudspeakers with built-in protection relays, there is a possibility that an amplifier output will be connected to a load
whose terminal voltage may attempt to swing beyond the
power supply voltages applied to the amplifier. This can
cause degradation of the output transistors or catastrophic
failure of the whole circuit. The standard protection for this
type of failure mechanism is a pair of diodes connected between the output of the amplifier and the supply rails. These
are part of the internal circuitry of the LM1875, and needn’t
be added externally when standard reactive loads are
driven.
Application Hints
STABILITY
The LM1875 is designed to be stable when operated at a
closed-loop gain of 10 or greater, but, as with any other
high-current amplifier, the LM1875 can be made to oscillate
under certain conditions. These usually involve printed circuit board layout or output/input coupling.
Proper layout of the printed circuit board is very important.
While the LM1875 will be stable when installed in a board
similar to the ones shown in this data sheet, it is sometimes
necessary to modify the layout somewhat to suit the physical
requirements of a particular application. When designing a
different layout, it is important to return the load ground, the
output compensation ground, and the low level (feedback
and input) grounds to the circuit board ground point through
separate paths. Otherwise, large currents flowing along a
ground conductor will generate voltages on the conductor
which can effectively act as signals at the input, resulting in
high frequency oscillation or excessive distortion. It is advisable to keep the output compensation components and the
0.1 µF supply decoupling capacitors as close as possible to
the LM1875 to reduce the effects of PCB trace resistance
and inductance. For the same reason, the ground return
paths for these components should be as short as possible.
Occasionally, current in the output leads (which function as
antennas) can be coupled through the air to the amplifier input, resulting in high-frequency oscillation. This normally
happens when the source impedance is high or the input
leads are long. The problem can be eliminated by placing a
small capacitor (on the order of 50 pF to 500 pF) across the
circuit input.
Most power amplifiers do not drive highly capacitive loads
well, and the LM1875 is no exception. If the output of the
LM1875 is connected directly to a capacitor with no series
resistance, the square wave response will exhibit ringing if
the capacitance is greater than about 0.1 µF. The amplifier
can typically drive load capacitances up to 2 µF or so without
oscillating, but this is not recommended. If highly capacitive
loads are expected, a resistor (at least 1Ω) should be placed
in series with the output of the LM1875. A method commonly
employed to protect amplifiers from low impedances at high
frequencies is to couple to the load through a 10Ω resistor in
parallel with a 5 µH inductor.
THERMAL PROTECTION
The LM1875 has a sophisticated thermal protection scheme
to prevent long-term thermal stress to the device. When the
temperature on the die reaches 170˚C, the LM1875 shuts
down. It starts operating again when the die temperature
drops to about 145˚C, but if the temperature again begins to
rise, shutdown will occur at only 150˚C. Therefore, the device is allowed to heat up to a relatively high temperature if
the fault condition is temporary, but a sustained fault will limit
the maximum die temperature to a lower value. This greatly
reduces the stresses imposed on the IC by thermal cycling,
which in turn improves its reliability under sustained fault
conditions.
Since the die temperature is directly dependent upon the
heat sink, the heat sink should be chosen for thermal resistance low enough that thermal shutdown will not be reached
during normal operation. Using the best heat sink possible
within the cost and space constraints of the system will improve the long-term reliability of any power semiconductor
device.
POWER DISSIPATION AND HEAT SINKING
The LM1875 must always be operated with a heat sink, even
when it is not required to drive a load. The maximum idling
current of the device is 100 mA, so that on a 60V power supply an unloaded LM1875 must dissipate 6W of power. The
54˚C/W junction-to-ambient thermal resistance of a TO-220
package would cause the die temperature to rise 324˚C
above ambient, so the thermal protection circuitry will shut
the amplifier down if operation without a heat sink is attempted.
DISTORTION
The preceding suggestions regarding circuit board grounding techniques will also help to prevent excessive distortion
levels in audio applications. For low THD, it is also necessary to keep the power supply traces and wires separated
from the traces and wires connected to the inputs of the
LM1875. This prevents the power supply currents, which are
large and nonlinear, from inductively coupling to the LM1875
inputs. Power supply wires should be twisted together and
separated from the circuit board. Where these wires are soldered to the board, they should be perpendicular to the
plane of the board at least to a distance of a couple of
inches. With a proper physical layout, THD levels at 20 kHz
with 10W output to an 8Ω load should be less than 0.05%,
and less than 0.02% at 1 kHz.
In order to determine the appropriate heat sink for a given
application, the power dissipation of the LM1875 in that application must be known. When the load is resistive, the
maximum average power that the IC will be required to dissipate is approximately:
CURRENT LIMIT AND SAFE OPERATING AREA (SOA)
PROTECTION
where VS is the total power supply voltage across the
LM1875, RL is the load resistance, and PQ is the quiescent
power dissipation of the amplifier. The above equation is
only an approximation which assumes an “ideal” class B out-
A power amplifier’s output transistors can be damaged by
excessive applied voltage, current flow, or power dissipation.
The voltage applied to the amplifier is limited by the design of
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Application Hints
If a mica insulator is used, the thermal resistance will be
about 1.6˚C/W lubricated and 3.4˚C/W dry. For this example,
we assume a lubricated mica insulator between the LM1875
and the heat sink. The heat sink thermal resistance must
then be less than
4.2˚C/W−2˚C/W−1.6˚C/W = 0.6˚C/W.
(Continued)
put stage and constant power dissipation in all other parts of
the circuit. The curves of “Power Dissipation vs Power Output” give a better representation of the behavior of the
LM1875 with various power supply voltages and resistive
loads. As an example, if the LM1875 is operated on a 50V
power supply with a resistive load of 8Ω, it can develop up to
19W of internal power dissipation. If the die temperature is to
remain below 150˚C for ambient temperatures up to 70˚C,
the total junction-to-ambient thermal resistance must be less
than
This is a rather large heat sink and may not be practical in
some applications. If a smaller heat sink is required for reasons of size or cost, there are two alternatives. The maximum ambient operating temperature can be reduced to 50˚C
(122˚F), resulting in a 1.6˚C/W heat sink, or the heat sink can
be isolated from the chassis so the mica washer is not
needed. This will change the required heat sink to a 1.2˚C/W
unit if the case-to-heat-sink interface is lubricated.
Note: When using a single supply, maximum transfer of heat away from the
LM1875 can be achieved by mounting the device directly to the heat
sink (tab is at ground potential); this avoids the use of a mica or other
type insulator.
Using θJC = 2˚C/W, the sum of the case-to-heat-sink interface
thermal resistance and the heat-sink-to-ambient thermal resistance must be less than 2.2˚C/W. The case-to-heat-sink
thermal resistance of the TO-220 package varies with the
mounting method used. A metal-to-metal interface will be
about 1˚C/W if lubricated, and about 1.2˚C/W if dry.
The thermal requirements can become more difficult when
an amplifier is driving a reactive load. For a given magnitude
of load impedance, a higher degree of reactance will cause
a higher level of power dissipation within the amplifier. As a
general rule, the power dissipation of an amplifier driving a
60˚ reactive load (usually considered to be a worst-case
loudspeaker load) will be roughly that of the same amplifier
driving the resistive part of that load. For example, a loudspeaker may at some frequency have an impedance with a
magnitude of 8Ω and a phase angle of 60˚. The real part of
this load will then be 4Ω, and the amplifier power dissipation
will roughly follow the curve of power dissipation with a 4Ω
load.
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Component Layouts
Split Supply
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Single Supply
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Physical Dimensions
inches (millimeters) unless otherwise noted
TO-220 Power Package (T)
Order Number LM1875T LB03
NS Package Number T05D
Order Number LM1875T SL108949
NS Package Number T05A
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Physical Dimensions
inches (millimeters) unless otherwise noted (Continued)
Order Number LM1875T LB05
NS Package Number T05E
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LM1875 20W Audio Power Amplifier
Physical Dimensions
inches (millimeters) unless otherwise noted (Continued)
Order Number LM1875T LB02
NS Package Number TA05B
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ure to perform when properly used in accordance
with instructions for use provided in the labeling, can
be reasonably expected to result in a significant injury
to the user.
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