LM4765T/NOPB - NATIONAL SEMICONDUCTOR

LM4765

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LM4765 Overture™ Audio Power Amplifier Series Dual 30W Audio Power Amplifier with

Mute and Standby Modes

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1FEATURES DESCRIPTION

The LM4765 is a stereo audio amplifier capable of

23• SPiKe Protection delivering typically 30W per channel of continuous

• Minimal Amount of External Components average output power into an 8Ωload with less than

Necessary 0.1% THD+N.

• Quiet Fade-In/Out Mute Mode Each amplifier has an independent smooth transition

• Standby-Mode fade-in/out mute and a power conserving standby

mode which can be controlled by external logic.

• Non-Isolated 15-Lead TO-220 Package

• Wide Supply Range 20V - 66V The performance of the LM4765, utilizing its Self

Peak Instantaneous Temperature (°Ke) (SPiKe)

KEY SPECIFICATIONS protection circuitry, places it in a class above discrete

and hybrid amplifiers by providing an inherently,

• THD+N at 1kHz at 2 x 25W Continuous dynamically protected Safe Operating Area (SOA).

Average Output Power into 8Ω: 0.1% (max) SPiKe protection means that these parts are

• THD+N at 1kHz at Continuous Average Output safeguarded at the output against overvoltage,

Power of 2 x 30W into 8Ω: 0.009% (typ) undervoltage, overloads, including thermal runaway

and instantaneous temperature peaks.

• Standby Current: 6.5mA (typ)

APPLICATIONS

• High-End Stereo TVs

• Component Stereo

• Compact Stereo

TYPICAL APPLICATION

Numbers in parentheses represent pinout for amplifier B.

*Optional component dependent upon specific design requirements.

Figure 1. Typical Audio Amplifier Application Circuit

1Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of

Texas Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.

2Overture is a trademark of Texas Instruments.

3All other trademarks are the property of their respective owners.

Products conform to specifications per the terms of the Texas

Instruments standard warranty. Production processing does not

necessarily include testing of all parameters.

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CONNECTION DIAGRAM

Figure 2. Plastic Package - Top View

Non-Isolated Package

See Package Number NDL0015A

These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam

during storage or handling to prevent electrostatic damage to the MOS gates.

ABSOLUTE MAXIMUM RATINGS(1)(2)(3)

Supply Voltage |VCC| + |VEE| (No Input) 66V

Supply Voltage |VCC| + |VEE| (with Input) 64V

Common Mode Input Voltage (VCC or VEE) and |VCC| + |VEE|≤60V

Differential Input Voltage 60V

Output Current Internally Limited

Power Dissipation(4) 62.5W

ESD Susceptability(5) 2000V

Junction Temperature(6) 150°C

Thermal Resistance Non-Isolated NDL-Package θJC 1°C/W

Soldering Information NDL Package (10 sec.) 260°C

Storage Temperature −40°C to +150°C

(1) All voltages are measured with respect to the GND pins (5, 10), unless otherwise specified.

(2) 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 ensure specific performance limits. Electrical Characteristics state DC and AC electrical

specifications under particular test conditions which ensure specific performance limits. This assumes that the device is within the

Operating Ratings. Specifications are not ensured for parameters where no limit is given, however, the typical value is a good indication

of device performance.

(3) If Military/Aerospace specified devices are required, please contact the Texas Instruments Sales Office/Distributors for availability and

specifications.

(4) For operating at case temperatures above 25°C, the device must be derated based on a 150°C maximum junction temperature and a

thermal resistance of θJC = 1°C/W for the NDL package. Refer to the section DETERMINING THE CORRECT HEAT SINK.

(5) Human body model, 100 pF discharged through a 1.5 kΩresistor.

(6) The operating junction temperature maximum is 150°C, however, the instantaneous Safe Operating Area temperature is 250°C.

OPERATING RATINGS(1)(2)

Temperature Range TMIN ≤TA≤TMAX −20°C ≤TA≤+85°C

Supply Voltage |VCC| + |VEE|(3) 20V to 64V

(1) All voltages are measured with respect to the GND pins (5, 10), unless otherwise specified.

(2) 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 ensure specific performance limits. Electrical Characteristics state DC and AC electrical

specifications under particular test conditions which ensure specific performance limits. This assumes that the device is within the

Operating Ratings. Specifications are not ensured for parameters where no limit is given, however, the typical value is a good indication

of device performance.

(3) Operation is ensured up to 64V, however, distortion may be introduced from SPiKe Protection Circuitry if proper thermal considerations

are not taken into account. Refer to the APPLICATION INFORMATION section for a complete explanation.

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ELECTRICAL CHARACTERISTICS(1)(2)

The following specifications apply for VCC = +28V, VEE =−28V with RL= 8Ωunless otherwise specified. Limits apply for TA=

25°C.

Symbol Parameter Conditions LM4765 Units

(Limits)

Typical(3) Limit(4)

|VCC| + Power Supply Voltage(5) GND −VEE ≥9V 18 20 V (min)

|VEE| 64 V (max)

PO(6) Output Power (Continuous THD + N = 0.1% (max),

Average) f = 1 kHz

|VCC| = |VEE| = 28V, RL= 8Ω30 25 W/ch (min)

|VCC| = |VEE| = 20V, RL= 4Ω22 15 W/ch (min)

THD + N Total Harmonic Distortion Plus 30 W/ch, RL= 8Ω0.08 %

Noise 15 W/ch, RL= 4Ω, |VCC| = |VEE| = 20V 0.1 %

20 Hz ≤f≤20 kHz, AV= 26 dB

Xtalk Channel Separation f = 1 kHz, VO= 10.9 Vrms 80 dB

SR(6) Slew Rate VIN = 1.414 Vrms, trise = 2 ns 18 12 V/μs (min)

Itotal(7) Total Quiescent Power Both Amplifiers VCM = 0V,

Supply Current VO= 0V, IO= 0 mA

Standby: Off 50 80 mA (max)

Standby: On 6.5 8 mA (max)

VOS(7) Input Offset Voltage VCM = 0V, IO= 0 mA 2.0 15 mV (max)

IBInput Bias Current VCM = 0V, IO= 0 mA 0.2 0.5 μA (max)

IOS Input Offset Current VCM = 0V, IO= 0 mA 0.002 0.2 μA (max)

IOOutput Current Limit |VCC| = |VEE| = 10V, tON = 10 ms, 3.5 2.9 Apk (min)

VO= 0V

VOD(7) Output Dropout Voltage(8) |VCC–VO|, VCC = 20V, IO= +100 mA 1.8 2.3 V (max)

|VO–VEE|, VEE =−20V, IO=−100 mA 2.5 3.2 V (max)

PSRR(7) Power Supply Rejection Ratio VCC = 30V to 10V, VEE =−30V, 115 85 dB (min)

VCM = 0V, IO= 0 mA

VCC = 30V, VEE =−30V to −10V 110 85 dB (min)

VCM = 0V, IO= 0 mA

CMRR(7) Common Mode Rejection Ratio VCC = 35V to 10V, VEE =−10V to −35V, 110 80 dB (min)

VCM = 10V to −10V, IO= 0 mA

AVOL(7) Open Loop Voltage Gain RL= 2 kΩ,ΔVO= 30V 110 90 dB (min)

GBWP Gain Bandwidth Product fO= 100 kHz, VIN = 50 mVrms 7.5 5 MHz (min)

eIN(6) Input Noise IHF—A Weighting Filter 2.0 8 μV (max)

RIN = 600Ω(Input Referred)

(1) All voltages are measured with respect to the GND pins (5, 10), unless otherwise specified.

(2) 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 ensure specific performance limits. Electrical Characteristics state DC and AC electrical

specifications under particular test conditions which ensure specific performance limits. This assumes that the device is within the

Operating Ratings. Specifications are not ensured for parameters where no limit is given, however, the typical value is a good indication

of device performance.

(3) Typicals are measured at 25°C and represent the parametric norm.

(4) Limits are specifications that all parts are tested in production to meet the stated values.

(5) VEE must have at least −9V at its pin with reference to ground in order for the under-voltage protection circuitry to be disabled. In

addition, the voltage differential between VCC and VEE must be greater than 14V.

(6) AC Electrical Test; Refer to TEST CIRCUIT #2 .

(7) DC Electrical Test; Refer to TEST CIRCUIT #1.

(8) The output dropout voltage, VOD, is the supply voltage minus the clipping voltage. Refer to the Clipping Voltage vs. Supply Voltage

graph in the TYPICAL PERFORMANCE CHARACTERISTICS section.

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ELECTRICAL CHARACTERISTICS(1)(2) (continued)

The following specifications apply for VCC = +28V, VEE =−28V with RL= 8Ωunless otherwise specified. Limits apply for TA=

25°C.

Symbol Parameter Conditions LM4765 Units

(Limits)

Typical(3) Limit(4)

SNR Signal-to-Noise Ratio PO= 1W, A—Weighted, 98 dB

Measured at 1 kHz, RS= 25Ω

PO= 25W, A—Weighted 108 dB

Measured at 1 kHz, RS= 25Ω

AMMute Attenuation Pin 6,11 at 2.5V 115 80 dB (min)

Standby Pin

VIL Standby Low Input Voltage Not in Standby Mode 0.8 V (max)

VIH Standby High Input Voltage In Standby Mode 2.0 2.5 V (min)

Mute pin

VIL Mute Low Input Voltage Outputs Not Muted 0.8 V (max)

VIH Mute High Input Voltage Outputs Muted 2.0 2.5 V (min)

TEST CIRCUIT #1

DC Electrical Test; Refer to TEST CIRCUIT #1

Figure 3. DC Electrical Test Circuit

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TEST CIRCUIT #2

AC Electrical Test; Refer to TEST CIRCUIT #2 .

Figure 4. AC Electrical Test Circuit

Bridged Amplifier Application Circuit

Figure 5. Bridged Amplifier Application Circuit

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Single Supply Application Circuit

Note: *Optional components dependent upon specific design requirements.

Figure 6. Single Supply Amplifier Application Circuit

Auxiliary Amplifier Application Circuit

Figure 7. Special Audio Amplifier Application Circuit

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Equivalent Schematic

(excluding active protection circuitry)

Figure 8. LM4765 (One Channel Only)

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EXTERNAL COMPONENTS DESCRIPTION

Components Functional Description

1 RBPrevents currents from entering the amplifier's non-inverting input which may be passed through to the load upon

power down of the system due to the low input impedance of the circuitry when the undervoltage circuitry is off.

This phenomenon occurs when the supply voltages are below 1.5V.

2 RiInverting input resistance to provide AC gain in conjunction with Rf.

3 RfFeedback resistance to provide AC gain in conjunction with Ri.

4 Ci(1) Feedback capacitor which ensures unity gain at DC. Also creates a highpass filter with Riat fC= 1/(2πRiCi).

5 CSProvides power supply filtering and bypassing. Refer to the application section for proper placement and selection

of bypass capacitors.

6 RV(1) Acts as a volume control by setting the input voltage level.

7 RIN(1) Sets the amplifier's input terminals DC bias point when CIN is present in the circuit. Also works with CIN to create a

highpass filter at fC= 1/(2πRINCIN). Refer to Figure 7.

8 CIN(1) Input capacitor which blocks the input signal's DC offsets from being passed onto the amplifier's inputs.

9 RSN(1) Works with CSN to stabilize the output stage by creating a pole that reduces high frequency instabilities.

10 CSN(1) Works with RSN to stabilize the output stage by creating a pole that reduces high frequency instabilities. The pole is

set at fC= 1/(2πRSNCSN). Refer to Figure 7.

11 L (1) Provides high impedance at high frequencies so that R may decouple a highly capacitive load and reduce the Q of

the series resonant circuit. Also provides a low impedance at low frequencies to short out R and pass audio signals

12 R (1) to the load. Refer to Figure 7.

13 RAProvides DC voltage biasing for the transistor Q1 in single supply operation.

14 CAProvides bias filtering for single supply operation.

15 RINP(1) Limits the voltage difference between the amplifier's inputs for single supply operation. Refer to the CLICKS AND

POPS application section for a more detailed explanation of the function of RINP.

16 RBI Provides input bias current for single supply operation. Refer to the CLICKS AND POPS application section for a

more detailed explanation of the function of RBI.

17 REEstablishes a fixed DC current for the transistor Q1 in single supply operation. This resistor stabilizes the half-

supply point along with CA.

(1) Optional components dependent upon specific design requirements.

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TYPICAL PERFORMANCE CHARACTERISTICS

THD + N vs Frequency THD + N vs Frequency

Figure 9. Figure 10.

THD + N vs Frequency THD + N vs Output Power

Figure 11. Figure 12.

THD + N vs Output Power THD + N vs Output Power

Figure 13. Figure 14.

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TYPICAL PERFORMANCE CHARACTERISTICS (continued)

Clipping Voltage vs Supply Voltage Clipping Voltage vs Supply Voltage

Figure 15. Figure 16.

Clipping Voltage vs Supply Voltage Output Power vs Load Resistance

Figure 17. Figure 18.

Power Dissipation vs Output Power Power Dissipation vs Output Power

Figure 19. Figure 20.

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TYPICAL PERFORMANCE CHARACTERISTICS (continued)

Output Power vs Supply Voltage Output Mute vs Mute Pin Voltage

Figure 21. Figure 22.

Output Mute vs Mute Pin Voltage Channel Separation vs Frequency

Figure 23. Figure 24.

Pulse Response Large Signal Response

Figure 25. Figure 26.

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TYPICAL PERFORMANCE CHARACTERISTICS (continued)

Power Supply Rejection Ratio Common-Mode Rejection Ratio

Figure 27. Figure 28.

Open Loop Frequency Response Safe Area

Figure 29. Figure 30.

SPiKe Protection Response Supply Current vs Supply Voltage

Figure 31. Figure 32.

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TYPICAL PERFORMANCE CHARACTERISTICS (continued)

Pulse Thermal Resistance Pulse Thermal Resistance

Figure 33. Figure 34.

Supply Current vs Output Voltage Pulse Power Limit

Figure 35. Figure 36.

Pulse Power Limit Supply Current vs Case Temperature

Figure 37. Figure 38.

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TYPICAL PERFORMANCE CHARACTERISTICS (continued)

Supply Current (ICC) vs Standby Pin Voltage Supply Current (IEE) vs Standby Pin Voltage

Figure 39. Figure 40.

Input Bias Current vs Case Temperature

Figure 41.

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APPLICATION INFORMATION

MUTE MODE

By placing a logic-high voltage on the mute pins, the signal going into the amplifiers will be muted. If the mute

pins are left floating or connected to a logic-low voltage, the amplifiers will be in a non-muted state. There are

two mute pins, one for each amplifier, so that one channel can be muted without muting the other if the

application requires such a configuration. Refer to the TYPICAL PERFORMANCE CHARACTERISTICS section

for curves concerning Mute Attenuation vs Mute Pin Voltage.

STANDBY MODE

The standby mode of the LM4765 allows the user to drastically reduce power consumption when the amplifiers

are idle. By placing a logic-high voltage on the standby pins, the amplifiers will go into Standby Mode. In this

mode, the current drawn from the VCC supply is typically less than 10 μA total for both amplifiers. The current

drawn from the VEE supply is typically 4.2 mA. Clearly, there is a significant reduction in idle power consumption

when using the standby mode. There are two Standby pins, so that one channel can be put in standby mode

without putting the other amplifier in standby if the application requires such flexibility. Refer to the TYPICAL

PERFORMANCE CHARACTERISTICS section for curves showing Supply Current vs. Standby Pin Voltage for

both supplies.

UNDER-VOLTAGE PROTECTION

Upon system power-up, the under-voltage protection circuitry allows the power supplies and their corresponding

capacitors to come up close to their full values before turning on the LM4765 such that no DC output spikes

occur. Upon turn-off, the output of the LM4765 is brought to ground before the power supplies such that no

transients occur at power-down.

OVER-VOLTAGE PROTECTION

The LM4765 contains over-voltage protection circuitry that limits the output current to approximately 3.5 Apk

while also providing voltage clamping, though not through internal clamping diodes. The clamping effect is quite

the same, however, the output transistors are designed to work alternately by sinking large current spikes.

SPiKe PROTECTION

The LM4765 is protected from instantaneous peak-temperature stressing of the power transistor array. The Safe

Operating graph in the TYPICAL PERFORMANCE CHARACTERISTICS section shows the area of device

operation where SPiKe Protection Circuitry is not enabled. The waveform to the right of the SOA graph

exemplifies how the dynamic protection will cause waveform distortion when enabled. Please refer to AN-898 for

more detailed information.

THERMAL PROTECTION

The LM4765 has a sophisticated thermal protection scheme to prevent long-term thermal stress of the device.

When the temperature on the die reaches 165°C, the LM4765 shuts down. It starts operating again when the die

temperature drops to about 155°C, but if the temperature again begins to rise, shutdown will occur again at

165°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 cause the device to cycle in a Schmitt Trigger fashion between the thermal

shutdown temperature limits of 165°C and 155°C. This greatly reduces the stress 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 used, the heat sink should be chosen such

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, as discussed in the DETERMINING THE CORRECT HEAT SINK Section.

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DETERMlNlNG MAXIMUM POWER DISSIPATION

Power dissipation within the integrated circuit package is a very important parameter requiring a thorough

understanding if optimum power output is to be obtained. An incorrect maximum power dissipation calculation

may result in inadequate heat sinking causing thermal shutdown and thus limiting the output power.

Equation 1 exemplifies the theoretical maximum power dissipation point of each amplifier where VCC is the total

supply voltage.

PDMAX = VCC2/2π2RL(1)

Thus by knowing the total supply voltage and rated output load, the maximum power dissipation point can be

calculated. The package dissipation is twice the number which results from Equation 1 since there are two

amplifiers in each LM4765. Refer to the graphs of Power Dissipation versus Output Power in the TYPICAL

PERFORMANCE CHARACTERISTICS section which show the actual full range of power dissipation not just the

maximum theoretical point that results from Equation 1.

DETERMINING THE CORRECT HEAT SINK

The choice of a heat sink for a high-power audio amplifier is made entirely to keep the die temperature at a level

such that the thermal protection circuitry does not operate under normal circumstances.

The thermal resistance from the die (junction) to the outside air (ambient) is a combination of three thermal

resistances, θJC,θCS, and θSA. In addition, the thermal resistance, θJC (junction to case), of the LM4765 is 1°C/W.

Using Thermalloy Thermacote thermal compound, the thermal resistance, θCS (case to sink), is about 0.2°C/W.

Since convection heat flow (power dissipation) is analogous to current flow, thermal resistance is analogous to

electrical resistance, and temperature drops are analogous to voltage drops, the power dissipation out of the

LM4765 is equal to the following:

PDMAX = (TJMAX−TAMB)/θJA

where

• TJMAX = 150°C, TAMB is the system ambient temperature

•θJA =θJC +θCS +θSA (2)

Once the maximum package power dissipation has been calculated using Equation 1, the maximum thermal

resistance, θSA, (heat sink to ambient) in °C/W for a heat sink can be calculated. This calculation is made using

Equation 3 which is derived by solving for θSA in Equation 2.

θSA = [(TJMAX−TAMB)−PDMAX(θJC +θCS)]/PDMAX (3)

Again it must be noted that the value of θSA is dependent upon the system designer's amplifier requirements. If

the ambient temperature that the audio amplifier is to be working under is higher than 25°C, then the thermal

resistance for the heat sink, given all other things are equal, will need to be smaller.

SUPPLY BYPASSING

The LM4765 has excellent power supply rejection and does not require a regulated supply. However, to improve

system performance as well as eliminate possible oscillations, the LM4765 should have its supply leads

bypassed with low-inductance capacitors having short leads that are located close to the package terminals.

Inadequate power supply bypassing will manifest itself by a low frequency oscillation known as “motorboating” or

by high frequency instabilities. These instabilities can be eliminated through multiple bypassing utilizing a large

tantalum or electrolytic capacitor (10 μF or larger) which is used to absorb low frequency variations and a small

ceramic capacitor (0.1 μF) to prevent any high frequency feedback through the power supply lines.

If adequate bypassing is not provided, the current in the supply leads which is a rectified component of the load

current may be fed back into internal circuitry. This signal causes distortion at high frequencies requiring that the

supplies be bypassed at the package terminals with an electrolytic capacitor of 470 μF or more.

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BRIDGED AMPLIFIER APPLICATION

The LM4765 has two operational amplifiers internally, allowing for a few different amplifier configurations. One of

these configurations is referred to as “bridged mode” and involves driving the load differentially through the

LM4765's outputs. This configuration is shown in Figure 5. Bridged mode operation is different from the classical

single-ended amplifier configuration where one side of its load is connected to ground.

A bridge amplifier design has a distinct advantage over the single-ended configuration, as it provides differential

drive to the load, thus doubling output swing for a specified supply voltage. Consequently, theoretically four times

the output power is possible as compared to a single-ended amplifier under the same conditions. This increase in

attainable output power assumes that the amplifier is not current limited or clipped.

A direct consequence of the increased power delivered to the load by a bridge amplifier is an increase in internal

power dissipation. For each operational amplifier in a bridge configuration, the internal power dissipation will

increase by a factor of two over the single ended dissipation. Thus, for an audio power amplifier such as the

LM4765, which has two operational amplifiers in one package, the package dissipation will increase by a factor

of four. To calculate the LM4765's maximum power dissipation point for a bridged load, multiply Equation 1 by a

factor of four.

This value of PDMAX can be used to calculate the correct size heat sink for a bridged amplifier application. Since

the internal dissipation for a given power supply and load is increased by using bridged-mode, the heatsink's θSA

will have to decrease accordingly as shown by Equation 3. Refer to the section, DETERMINING THE CORRECT

HEAT SINK, for a more detailed discussion of proper heat sinking for a given application.

SINGLE-SUPPLY AMPLIFIER APPLICATION

The typical application of the LM4765 is a split supply amplifier. But as shown in Figure 6, the LM4765 can also

be used in a single power supply configuration. This involves using some external components to create a half-

supply bias which is used as the reference for the inputs and outputs. Thus, the signal will swing around half-

supply much like it swings around ground in a split-supply application. Along with proper circuit biasing, a few

other considerations must be accounted for to take advantage of all of the LM4765 functions.

The LM4765 possesses a mute and standby function with internal logic gates that are half-supply referenced.

Thus, to enable either the Mute or Standby function, the voltage at these pins must be a minimum of 2.5V above

half-supply. In single-supply systems, devices such as microprocessors and simple logic circuits used to control

the mute and standby functions, are usually referenced to ground, not half-supply. Thus, to use these devices to

control the logic circuitry of the LM4765, a “level shifter,” like the one shown in Figure 42, must be employed. A

level shifter is not needed in a split-supply configuration since ground is also half-supply.

Figure 42. Level Shift Circuit

When the voltage at the Logic Input node is 0V, the 2N3904 is “off” and thus resistor Rcpulls up mute or standby

input to the supply. This enables the mute or standby function. When the Logic Input is 5V, the 2N3904 is “on”

and consequently, the voltage at the collector is essentially 0V. This will disable the mute or standby function,

and thus the amplifier will be in its normal mode of operation. Rshift, along with Cshift, creates an RC time constant

that reduces transients when the mute or standby functions are enabled or disabled. Additionally, Rshift limits the

current supplied by the internal logic gates of the LM4765 which insures device reliability. Refer to the MUTE

MODE and STANDBY MODE sections in the APPLICATION INFORMATION section for a more detailed

description of these functions.

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CLICKS AND POPS

In the typical application of the LM4765 as a split-supply audio power amplifier, the IC exhibits excellent “click”

and “pop” performance when utilizing the mute and standby modes. In addition, the device employs Under-

Voltage Protection, which eliminates unwanted power-up and power-down transients. The basis for these

functions are a stable and constant half-supply potential. In a split-supply application, ground is the stable half-

supply potential. But in a single-supply application, the half-supply needs to charge up just like the supply rail,

VCC. This makes the task of attaining a clickless and popless turn-on more challenging. Any uneven charging of

the amplifier inputs will result in output clicks and pops due to the differential input topology of the LM4765.

To achieve a transient free power-up and power-down, the voltage seen at the input terminals should be ideally

the same. Such a signal will be common-mode in nature, and will be rejected by the LM4765. In Figure 6, the

resistor RINP serves to keep the inputs at the same potential by limiting the voltage difference possible between

the two nodes. This should significantly reduce any type of turn-on pop, due to an uneven charging of the

amplifier inputs. This charging is based on a specific application loading and thus, the system designer may need

to adjust these values for optimal performance.

As shown in Figure 6, the resistors labeled RBI help bias up the LM4765 off the half-supply node at the emitter of

the 2N3904. But due to the input and output coupling capacitors in the circuit, along with the negative feedback,

there are two different values of RBI, namely 10 kΩand 200 kΩ. These resistors bring up the inputs at the same

rate resulting in a popless turn-on. Adjusting these resistors values slightly may reduce pops resulting from

power supplies that ramp extremely quick or exhibit overshoot during system turn-on.

AUDIO POWER AMPLlFIER DESIGN

Design a 15W/8ΩAudio Amplifier

Given:

Power Output 15 Wrms

Load Impedance 8Ω

Input Level 1 Vrms(max)

Input Impedance 47 kΩ

Bandwidth 20 Hz−20 kHz ±0.25 dB

A designer must first determine the power supply requirements in terms of both voltage and current needed to

obtain the specified output power. VOPEAK can be determined from Equation 4 and IOPEAK from Equation 5.

(4)

(5)

To determine the maximum supply voltage the following conditions must be considered. Add the dropout voltage

to the peak output swing VOPEAK, to get the supply rail at a current of IOPEAK. The regulation of the supply

determines the unloaded voltage which is usually about 15% higher. The supply voltage will also rise 10% during

high line conditions. Therefore the maximum supply voltage is obtained from the following equation.

Max supplies ≈± (VOPEAK + VOD) (1 + regulation) (1.1) (6)

For 15W of output power into an 8Ωload, the required VOPEAK is 15.49V. A minimum supply rail of 20.5V results

from adding VOPEAK and VOD. With regulation, the maximum supplies are ±26V and the required IOPEAK is 1.94A

from Equation 5. It should be noted that for a dual 15W amplifier into an 8Ωload the IOPEAK drawn from the

supplies is twice 1.94 Apk or 3.88 Apk. At this point it is a good idea to check the Power Output vs Supply

Voltage to ensure that the required output power is obtainable from the device while maintaining low THD+N. In

addition, the designer should verify that with the required power supply voltage and load impedance, that the

required heatsink value θSA is feasible given system cost and size constraints. Once the heatsink issues have

been addressed, the required gain can be determined from Equation 7.

(7)

From Equation 7, the minimum AVis: AV≥11.

By selecting a gain of 21, and with a feedback resistor, Rf= 20 kΩ, the value of Rifollows from Equation 8.

Ri= Rf(AV−1) (8)

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SNAS030C –AUGUST 1998–REVISED APRIL 2013

Thus with Ri= 1 kΩa non-inverting gain of 21 will result. Since the desired input impedance was 47 kΩ, a value

of 47 kΩwas selected for RIN. The final design step is to address the bandwidth requirements which must be

stated as a pair of −3 dB frequency points. Five times away from a −3 dB point is 0.17 dB down from passband

response which is better than the required ±0.25 dB specified. This fact results in a low and high frequency pole

of 4 Hz and 100 kHz respectively. As stated in the External Components section, Riin conjunction with Cicreate

a high-pass filter.

Ci≥1/(2π* 1 kΩ* 4 Hz) = 39.8 μF; use 39 μF. (9)

The high frequency pole is determined by the product of the desired high frequency pole, fH, and the gain, AV.

With a AV= 21 and fH= 100 kHz, the resulting GBWP is 2.1 MHz, which is less than the ensured minimum

GBWP of the LM4765 of 5 MHz. This will ensure that the high frequency response of the amplifier will be no

worse than 0.17 dB down at 20 kHz which is well within the bandwidth requirements of the design.

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SNAS030C –AUGUST 1998–REVISED APRIL 2013

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REVISION HISTORY

Changes from Revision B (April 2013) to Revision C Page

• Changed layout of National Data Sheet to TI format .......................................................................................................... 19

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PACKAGE OPTION ADDENDUM

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Addendum-Page 1

PACKAGING INFORMATION

Orderable Device Status

(1)

Package Type Package

Drawing Pins Package

Qty Eco Plan

(2)

Lead/Ball Finish

(6)

MSL Peak Temp

(3)

Op Temp (°C) Device Marking

(4/5)

Samples

LM4765T/NOPB NRND TO-220 NDL 15 20 TBD Call TI Call TI -20 to 85 LM4765T

(1) The marketing status values are defined as follows:

ACTIVE: Product device recommended for new designs.

LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.

NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.

PREVIEW: Device has been announced but is not in production. Samples may or may not be available.

OBSOLETE: TI has discontinued the production of the device.

(2) Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability

information and additional product content details.

TBD: The Pb-Free/Green conversion plan has not been defined.

Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that

lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.

Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between

the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above.

Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight

in homogeneous material)

(3) MSL, Peak Temp. - The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.

(4) There may be additional marking, which relates to the logo, the lot trace code information, or the environmental category on the device.

(5) Multiple Device Markings will be inside parentheses. Only one Device Marking contained in parentheses and separated by a "~" will appear on a device. If a line is indented then it is a continuation

of the previous line and the two combined represent the entire Device Marking for that device.

(6) Lead/Ball Finish - Orderable Devices may have multiple material finish options. Finish options are separated by a vertical ruled line. Lead/Ball Finish values may wrap to two lines if the finish

value exceeds the maximum column width.

Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information

provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and

continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.

TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.

In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.

MECHANICAL DATA

NDL0015A

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TA15A (Rev B)

IMPORTANT NOTICE

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