HCA600ACREF_技术文档

HCA600ACREF

Data Sheet

October 1999

File Number 4777

PRELIMINARY

600W/1000W Full Bandwidth Class D

Ampliﬁer

Features

• 600W RMS Power into 8Ω

• 1000W RMS Power into 4Ω

The HCA600ACREF reference

design delivers 600W RMS

power into a 8Ω load and

1000W into a 4Ω load.

• THD <0.02% at 1kHz and 450W into 8Ω

• SNR >110dB Relative to Full Power

• Output Noise . . . . . . . . . . . . . . . . . . . . . . . . . . . . <200µV

• Constant Group Delay

The design is part of the Intersil’s Coolaudio™ program that

supports customers to achieve a minimum time-to-market for

audio end products. As part of this program, this design is

offered after execution of a licensing agreement. At that time,

Intersil provides to the licensee a documentation package

containing: 1) a circuit description, 2) schematics, 3) test

and manufacturing information, 4) A bill of materials with all

vendors and vendor part numbers, 5) Intersil’s engineering

support contacts, 6) one evaluation unit.

• DC to 80kHz Small Signal Bandwidth

• Power Bandwidth . . . . . . . . . . . . . . . . . . . . . . . . . . .28kHz

• Slew Rate. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18V/µs

• Efﬁciency >90% at 500W into 8Ω

• Meets FCC and EN55013 Requirements for EMC

• Based On the Intersil HCA8001, Audio Speciﬁc IC

• Differential or Single Ended Input

For more information, visit our web page at

http://www.intersil.com. For technical assistance, call Central

Applications at 1-800-442-7747, or email us at

centapp@intersil.com.

• Over-Current, Over-Voltage and Thermal Protection

• Soft Clipping

• Bridgeable up to 4000W

Licensing Information

Contacts for licensing details, reference design evaluation,

and general questions are as follows:

Applications

• Sound Reinforcement

• Professional and Commercial Sound Systems

• Powered Speakers

Continental Far East, Email cfelic@ca.mbn.or.jp

Intersil Cool Audio, Email coolaud@intersil.com

• Hi-Fi Stereo

Reference Design Block Diagram

SOURCE

1

SOURCE

2

HCA600ACREF

220MM (8.7”)

PRE-AMPLIFIER

HCA600ACREF

HCA8001

POWER

SUPPLY

HEATSINK / EMI SHIELD

FETS AND DIODES

HCA8001

27.9MM (1.1”)

NOTE: The HCA600ACREF can be used in many different commercial and professional applications

including movie theater surround sound systems as depicted in this reference design block diagram.

CAUTION: These devices are sensitive to electrostatic discharge; follow proper IC Handling Procedures.

1

Coolaudio™ is a trademark of Intersil Corporation.

HCA600ACREF

Absolute Maximum Ratings

Operating Conditions

Bus Voltage, V

BUS

. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 130V (Note 1)

Bus Voltage, V . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 110V

BUS

+/-12V . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . +/-12V

+/-12V . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . +/-15V

12VFLT. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -Bus+15V

Audio Inputs. . . . . . . . . . . . . . 12V Differential Peak to Peak Voltage

12VFLT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -Bus +12V

o

Ambient Temperature Range. . . . . . . . . . . . . . . . . . . . . 0 C to 50 C

NOTE:

1. WARNING: The voltages inside the shield, at the

edge connector, and on the speaker cables are

potentially deadly. Extreme caution is required.

CAUTION: Stresses above those listed in “Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress only rating and operation of the

device at these or any other conditions above those indicated in the operational sections of this speciﬁcation is not implied.

Electrical Speciﬁcations

R

= 8Ω, V

BUS

=

110V, Supply Source Resistance < 2.5Ω, Storage Capacitor > 12,000µF, 12VFLT = 12V,

LOAD

+/-12V = +/-12V

o

T

= 25 C

A

PARAMETER

SUPPLY SPECIFICATION

Minimum Bus Voltage

SYMBOL

TEST CONDITIONS

TYP

UNITS

V

600W into 8Ω

110

3

V

A

BUS MIN

V

RMS Current

I

1kHz Sine Wave, Full Output Power (8Ω load)

1kHz Sine Wave, Full Output Power (4Ω load)

Quiescent Current, No Signal

BUS

V BUS

6

A

BUS

Average Current

I

60

400

11.5

40

75

50

1

mA

V

BUS,Q

VBUSQ

12V Float Current

I

Current supplied to power output gate driver circuitry

1kHz Sine Wave, Full Output Power (8Ω load)

No input signal

12VFLTBIAS

Minimum +/-12V

V

BIASmin

12V Max RMS Current

I+/-

mA

V

15V

Rising Under Voltage Lock Out Voltage

Falling Under Voltage Lock Out Voltage

ENABLE Threshold Voltage

ENABLE Internal Source Current

OUTPUT POWER AND EFFICIENCY

Maximum Output Power (Note 2)

Efficiency

V

Bus voltage that activates the amplifier

Bus voltage that shuts down the amplifier

Amplifier starts at this voltage, input amplifier muted

Input amplifiers active and entire amplifier active

Internal “Pull Up” Current

UV Rising

V

UV Falling

V

I

V

ENABLE1

ENABLE2

ENABLE

2

V

25

µA

P

THD = 1%, 1kHz, R

LOAD

= 8Ω

= 4Ω

600

800

1000

1200

88

W

%

MAX8Ω

10% THD

THD = 10%, 1kHz, R

LOAD

8Ω

4Ω

P

THD = 1%, 1kHz, R

LOAD

MAX4Ω

10% THD

THD = 10%, 1kHz, R = 4Ω

LOAD

PMAX

P

= 200W, 8Ω

= 500W, 8Ω

= 400W, 4Ω

= 1000W, 4Ω

EFF

OUT

95

EFF

88

90

AMPLIFIER PERFORMANCE

Total Harmonic Distortion + Noise

Signal to Noise Ratio

P

= 400W, R

LOAD

= 8Ω, 1kHz

0.015

110

%

dB

µV

%

THD+N

OUT

V

Relative to full scale output, 600W into 8Ω

SNR

Output Noise

V

200

N

Intermodulation Distortion

IMD

SMPTE, 60Hz and 7kHz, 4:1,

0.02

R

= 8Ω at 25W Output

LOAD

PSRR (∆V

OUT

/∆V

)

PSRR

DC

300

µV/V

BUS

2

HCA600ACREF

Electrical Speciﬁcations

R

= 8Ω, V

BUS

=

110V, Supply Source Resistance < 2.5Ω, Storage Capacitor > 12,000µF, 12VFLT = 12V,

LOAD

+/-12V = +/-12V (Continued)

o

T

= 25 C

A

PARAMETER

SYMBOL

TEST CONDITIONS

TYP

-65

2

UNITS

dB

PSRR (∆V

OUT

/∆V

)

PSRRac

|V

120Hz

BUS

Amplifier Output Offset Voltage

Amplifier Output Impedance

Damping Factor

|

DC voltage across the speaker, load = 8Ω

Measured at 1kHz and 10W Output

mV

OS

Z

16

mΩ

OUT

DF

500

ADDITIONAL CHARACTERISTICS

Cutoff Frequency, Referenced to 1kHz

20kHz Response, Referenced to 1kHz

Power Bandwidth

F

-3dB, R

= 8Ω at 10W Output

= 4Ω at 10W Output

80

70

kHz

dB

UPPER8

UPPER4

LOAD

F

at 20kHz Output at 20kHz and 10W, R

= 8Ω

-0.5

28

R

LOAD

P

Maximum Frequency for Full Power R

= 8Ω

kHz

V/µs

V

BW

LOAD

Maximum rate of change of the output voltage

Full Output Power, R = 8Ω

Slew Rate

SR

18

Maximum Switching Ripple on Output

Input Gain

F

12.0

26

PWM

LOAD

A

Either Inverting or non inverting input. Unused

input returned to analog ground

dB

V

Input Impedance, Inverting Input

Input Impedance, Non Inverting Input

Output Signal Phasing

R

Differential amplifier input, other input grounded

10

5

kΩ

-INPUT

R

+INPUT

Phasing

Positive going signal on non Inverting input

results in negative going amplifier output

180

Degrees

o

Over Temperature Shut Down

Over Temperature Hysteresis

Amplifier Output Current Limit

OT

Rising temperature to shutdown amplifier.

Set by an external thermistor

110

10

C

SD

o

OT

Difference between rising and falling temperature

shut down and start up points

C

H

I

Absolute Value

25

50

A

L

Amplifier Output Current Limit Time

(Note 3)

T

Time the amplifier must be in current limiting before

shutdown

ms

IL

NOTES:

2. At this power level, the soft clipping circuitry is beginning to activate. It functions to “round off” peaks rather than hard limit as in most linear

amplifiers. This helps to give this amplifier a pleasing sound during limiting. Moreover, this feature also makes the amplifier “sound louder”.

3. This time allows the amplifier to reproduce large, sustained peaks without shutting down, yet is adequate to protect the amplifier output from

shorted speaker lines.

3

HCA600ACREF

HCA600ACREF Connector Pin Designations

DESIGNATION

FUNCTION

WIRE COLOR

SPECIFICATIONS AND COMMENTS

1

Analog Ground

Input Ground

Black

Connect to ground of pre-amp or connect to pin 18.

(22 Gauge)

Phono

2

3

4

5

6

Non-Inv Input

Inv Input

Audio Input

Input Ground

Enable

Audio applied to pin 2 does not invert the phase of the signal.

Input impedance is 5kΩ.

Phono

Pin 3 and 4 are differential inputs. Audio applied to pin 3 inverts

the phase of the signal. Input impedance is 10kΩ.

Analog Ground

Enable

Black

(22 Gauge)

Green

(22 Gauge)

Add capacitance to delay startup or pull low to disable amp.

Optional

Fan

Controls fan or drives LED Brown

indicatingovertemperature (22 Gauge)

shutdown

7

CL_OUT

SFCL_OUT

-12V

Drives LED to indicate

onset of current limit

Grey

(22 Gauge)

Optional

8

Drives LED to indicate soft Blue

clipping is activated

Optional

(22 Gauge)

9

- Bias Supply

Purple

(22 Gauge)

50mA, -12V 10%

50mA, +12V 10%

Connect to Star Ground

10

11

12

13

14

15

16

17

18

+12V

+ Bias Supply

Power Ground

Positive Supply

Power Ground

Negative Supply

Orange

(22 Gauge)

PGND

+BUS

Black

(16 Gauge)

Red

(16 Gauge)

For best results use at least 12,000µF, 160V electrolytic

capacitor. Limit Bus under no load conditions to 130V.

+BUS

Red

(16 Gauge)

PGND

-BUS

Black

(16 Gauge)

White

(16 Gauge)

For best results use at least 12,000µF, 160V electrolytic

capacitor. Limit Bus under no load conditions to 130V.

-BUS

White

(16 Gauge)

+12VFLT

PGND

Floating 12V supply

(referenced to -Bus)

Yellow

(20 Gauge)

500mA, +12V 10%

This signal is referenced to the negative rail (-Bus).

Power Ground

Black

(16 Gauge)

Molex Part Numbers: Header - 26-60-5180, Connector - 09-50-8183, Pins - 08-52-0113

WARNING: Insulate wires. Accidental shorts between +/- Bus and bias supplies will damage the ampliﬁer.

4

HCA600ACREF

Typical Performance Curves

1.000

1

LOAD = 8Ω

0.0

-1.000

-2.000

-3.000

-4.000

LOAD = 4Ω

400W

0.1

0.01

20W

-5.000

-6.000

0.001

0.0005

10

100

1k

10k

30k

100

1k

10k

80k

FREQUENCY (Hz)

FIGURE 1. THD +N (%) vs FREQUENCY LOAD = 8Ω

FIGURE 2. AMPLIFIER FREQUENCY RESPONSE

10W - LOAD = 8Ω

AMPLIFIER OUTPUT vs INPUT

DSA 602A DIGITIZING SIGNAL ANALYZER

LOAD = 8Ω

90

78

1012

760

R = ∞

R = 20K

65

528

338

190

R = 10K

52

39

26.0

84

13.0

0.0

21

0.0

0.0 0.6 0.12 0.18 2.4 3.0 3.6 4.2 4.8 5.2 6.0

INPUT VOLTAGE (V

)

1ms/DIV

RMS

FIGURE 3. AMPLIFIER TRANSFER CHARACTERISTIC WITH

VARIOUS SETTINGS OF SOFT CLIPPING

RESISTOR

FIGURE 4. OSCILLOSCOPE DISPLAY OF AMPLIFIER

OUTPUT WITH SOFT CLIPPING CIRCUIT

ENABLED

Soft Clipping

DSA 602A DIGITIZING SIGNAL ANALYZER

Figures 3, 4 and 5 show the effects of the soft clipping

circuitry within the ampliﬁer. Figure 3 shows the transfer

characteristic of the ampliﬁer for various values of the soft

clipping programming resistor. An important aspect of soft

clipping is the apparent increase in sound level. As soft

clipping is reached, the upper and lower envelop of the

sinewave is gradually reduced. This “soft” rounding reduces

the higher harmonics that would result if hard clipping as

shown in Figure 5 was enabled. Soft clipping also results in

an ampliﬁer with a more pleasing sound. Figure 4 shows the

rounding of the output with soft clipping, while Figure 5

shows the ampler output without soft clipping.

1ms/DIV

FIGURE 5. OSCILLOSCOPE DISPLAY OF AMPLIFIER

OUTPUT WITH SOFT CLIPPING CIRCUIT

DISABLED

5

HCA600ACREF

Full Size Outline of HCA600ACREF Board

HCA600ACREFC

TOP VIEW

PC BOARD CONNECTIONS SHOWN

FROM THE TOP OR COMPONENT SIDE

18

1

OUT+

OUT-

76.2MM (3.08”)

6

HCA600ACREF

Schematic Diagram of HCA600ACREF Board Test Setup

OUTPUT END OF HCA600ACREF

TO AUDIO GENERATOR

ANALYZER GND

TO DISTORTION ANALYZER INPUT

AMPLIFIER LOAD RESISTOR

-

1

2

V

+

1

2

V

S

F

C

L

O

U

T

+

12V

-

A

G

N

D

+

I

N

P

U

T

-

I

N

P

U

T

A

G

N

D

E

N

A

B

L

F

A

N

C

L

O

U

T

P

G

N

D

+

B

U

S

+

B

U

S

P

G B

N U

-

B

U

S

1 P

2 G

V N

F D

L

D

S

E

T

+

12V

-

+

12,000µF

MAKE SURE SUPPLY

IS STABLE WITH

CAPACITORS

120V

+

120V

-

+

12,000µF

+

12V

-

TO EARTH GND

CAUTION: Remove all power when inserting or removing the amplifier board. Make sure power supply capacitors are discharged or damage to the

amplifier may result.

a thermal shutdown and in extreme cases failure, so this should

be avoided. Music does not contain high frequency high power

signals so this is not a concern in real applications.

Board Test Equipment and Test Procedure

for Intersil HCA600ACREF Ampliﬁer

Equipment required for evaluation of the Intersil

WARNING: This amp is DC coupled. Do not apply DC to

the input. In applications, a DC blocking cap is required in

the preamp or between the preamp and the amplifier. For

example, a 2.2µF film capacitor between the preamp and

the -input will roll the frequency response off at 7Hz (10K

input impedance).

HCA600ACREF Ampliﬁer is as follows:

1. Few bench supplies can deliver the rated voltage and

current for this ampliﬁer. Furthermore, most linear bench

supplies cannot sink current. If at all possible a 1KVA

transformer (92V-0-92V) and rectiﬁer should be used to

supply main power. See Figure 6. Bench supplies can be

used to provide bias as shown on the next page.

2. THD measurements are not valid if the AP filters are not

used. The AP interprets the carrier of a class D amplifier as

noise. Filters must be used to remove the carrier. Always

make sure that either the 22, 30 or 80kHz filters in the AP

are selected. The 80kHz filter does not attenuate the carrier

completely, and if it is selected an external 80kHz RC filter

should also be used. This filter must use a high quality cap

so that it does not contribute to THD. A 10K metal film

resistor with a 180pF polypropylene cap does the job well.

2. Three12V, 500mAPowerSupplies(iftransformerwiththe

required secondary windings is not available).

3. Distortion Analyzer such as the Audio Precision System

One or System Two or equivalent.

4. Load resistors, 8Ω, 500W and 4Ω, 1000W and a fan.

5. Associated connectors and cables.

6. HCA600ACREF Ampliﬁer Board.

If the carrier is visible with a scope on the reading output of

the AP, then the AP is including the switching frequency in its

THD+ Noise calculations. The number is not valid.

Test Procedure for Evaluation of HCA600ACREF

1. The power supply sequencing is not critical with one

exception. The -12V must be applied at the same time or

before the +12V. If not, the amp may not start.

Selecting the 80kHz ﬁlter and using a single pole external

80kHz low pass ﬁlter allows the 2nd, 3rd and 4th harmonics

of a 20kHz signal to be observed.

Frequency sweeps should be limited between 3Hz and 80kHz

at high powers. Amplitude vs. frequency sweeps at full power

will not damage the amplifier. Nevertheless, high frequency

(>10kHz) high power continuous sine wave testing may result in

The external RC ﬁlter should also be used when measuring

IMD and CCIF.

7

HCA600ACREF

Block Diagram of HCA600ACREF Test Setup

AUDIO PRECISION OR OTHER DISTORTION ANALYZER

AUDIO PRECISION

SET TO

UNBALANCED

GROUNDED

.

8Ω LOAD

RESISTOR

.

+12V

200mA

+

-

-12V

+12V

200mA

+

-

+

I

-

I

A N N A

G P P G

N U U N

D T T D

12VFLT

500mA

+

-

+BUS (125V)

-

+

1

2

V

-

1

2

V

-BUS (-125V)

-

PGND

1kVA POWER SUPPLY

(SEE BELOW)

CAUTION: Remove power and discharge capacitors before removing or inserting the ampliﬁer. Failure to do so may

damage the module.

NOTES:

4. Differential input. input signal to - INPUT and + INPUT returned to analog ground.

5. When using + INPUT, return - INPUT to analog ground.

6. Enable may be left open since a 25µA pull up current will enable the IC. The fan, CL and SFCL all may also be left open.

8

HCA600ACREF

Power Supply For the HCA600ACREF

D3

15A

125V NO LOAD

PINS 12, 13

+BUS

1kVA TRANSFORMER

12,000µF

D2

160V

-125V NO LOAD

PINS 15, 16

-BUS

92VAC

AC INPUT

+

-

15A

12,000µF

160V

D1

D4

PINS 11, 14, 18

PGND

STAR GROUND

19V NO LOAD

+12V

-12V

PIN 10

+12V

12V

REG

19V NO LOAD

13.6VAC

470µF

35V

100µF

16V

+

-

PIN 9

-12V

REG

470µF

35V

100µF

16V

12VFLT

1A

12V

REG

13.6VAC

19V NO LOAD

PIN 17

12VFLT

PINS 1, 4

AGND

100µF

25V

1,000µF

35V

WARNING: High voltage secondary.

NOTES:

7. D1, D2 are 200V, 3A diodes. These will blow both fuses if either MOSFET in the power amplifier fails short.

8. D3, D4 are 200V, 1A diodes that return energy to the supply if a fuse blows.

FIGURE 6.

Power Supply Speciﬁcations

+Bus and -Bus

+12V and -12V

The voltage necessary to achieve full power is 110V. In an

unregulated supply, the no load voltage will be signiﬁcantly

higher. The MOSFETs used in the ampliﬁer support the

differential voltage between the buses. That is if the +/-Bus

are 125V, then each MOSFET has to support 250V. The

breakdown of the MOSFETS is 275V. Care must be take to

ensure that under no load, high line conditions this

breakdown voltage is not exceeded. Doing so may damage

the ampliﬁer.

Each supply draws approximately 40mA. Regulation is

required. For best results make sure that the rectiﬁed

secondary voltage at minimum line voltage is greater than

the dropout voltage of the regulator. Any 100mA, 12V, linear

regulator can be used.

12VFLT

This voltage is needed to drive the gates of the MOSFETs.

The current required is on the order of 400mA. This voltage

should also be regulated. The current is high enough that a

1A regulator with heatsinking is required. This supply is

referenced to -Bus. Do not reference this supply to

ground as the amp will be damaged.

This limitation makes it difﬁcult to achieve full power from an

unregulated power supply. The output impedance of the

transformer has to be very low and the size of the bulk

capacitance must be large. A better solution is to use a

switching power supply. This allows the ampliﬁer to be used

to its full potential. With an unregulated power supply, 500W

is the maximum power. The ampliﬁer will still be able to

provide 600W transient RMS power.

NOTE: In applications that use multiple modules, power supplies

can be shared as long as the currents of each supply is scaled

accordingly.

The voltages on +/-Bus are dangerous. Be careful. Do not

touch the components inside the shield when power is

applied. Make sure the bulk capacitance in the power supply

is discharged before disconnecting or connecting the edge

connector. Don’t touch uninsulated speaker wires when the

amp is running at high powers. Diodes D1- D4 are for

required for safety. Use them.

While not shown in the power supply diagram, high

frequency ceramic caps (0.1µF) should be placed in parallel

with the electrolytic capacitors for the +/-12V bias and

12VFLT. This additional ﬁltering will improve the performance

of the ampliﬁer.

9

HCA600ACREF

large inductor should be glued to the shield and the board,

Heat Sinking

so that it is anchored securely. Thermal grease between the

transfer plate and shield is required. Place small washers

under the heatsink to lift it up off the board. The washer next

to R3 requires thermal grease on both sides so that the

thermistor used to sense the temperature of the thermal

transfer plate will be in thermal contact.

The HCA600ACREF heat sink must be supplemented to

achieve full power. The amount of additional heatsinking

depends on the airﬂow.

For bench testing, a small fan set up within inches of the

board blowing across the shield is sufﬁcient for full power

testing. The resistors used to test the board will also likely

require a fan.

GROUNDING

As in all audio ampliﬁers, grounding is important. The

module has two ground planes, power and analog. These

are connected on the board by a zero ohm jumper, R31. In

most applications, this jumper should be removed, and

analog ground should make one and only one connection

with power ground, (star ground) - see Figure 6 for power

supply transformer.

In applications, the internal thermal transfer plate should be

bolted to the chassis. This can be accomplished by either

placing the board horizontally so that the shield is in thermal

contact with the bottom or side of the chassis or by using an

L bracket which mounts to both the chassis and the thermal

plate. The shield will not make good thermal contact with the

thermal transfer plate unless a stiff piece of aluminum is

bolted to the transfer plate from the outside of the shield.

The reference design uses 125 mil aluminum bars for this

purpose. The chassis and L bracket can also serve the same

purpose, allowing the aluminum bars to be discarded. The

aluminum shield is necessary for EMC compliance. Do not

remove it.

AUTOMATIC RESTART INTO SHORT

The ampliﬁer is capable of distinguishing a low impedance

load from a dead short. If the output is shorted with a low

impedance, the amp will deliver 30A for 50ms and then shut

down. If the impedance is very low (a short), the ampliﬁer will

deliver 50A for a short burst and then shut down. In either

case, power must be cycled by the user to restart the

ampliﬁer. The amp will not shut down if the impedance of the

loudspeaker dips, or if the speakers are momentarily

shorted. In this case, the ampliﬁer limits the current supplied

to the loudspeaker. The ampliﬁer is designed for use with 4Ω

and 8Ω speakers. It is stable into 2Ω and 1Ω loads, but the

magnetics and heatsinking are not designed for low

To ensure a long and reliable life, the heatsinking should be

o

designed so that the module typically runs at 70 C or less.

Higher operating temperatures will reduce the lifetime of

the module.

It is also important to use high temperature ﬁber washers

when mounting the FETs to the transfer plate. Teﬂon™ and

plastic washers will ﬂow at high temperatures causing the

FETs to loose contact with the transfer plate and fail.

impedance speakers or multiple speakers in parallel.

If auto restart into a dead short is absolutely required, then

populate R59 with a 10Ω 805 resistor, and change C11 to a

0.1µF, 10V, 1206 capacitor. The current limit time out will

now be 5ms, and the ampliﬁer will always try to restart after

a dead short one or more times. For safety and reliability

issues, if the current ramps to more than 50A on any start up

attempt, the ampliﬁer will shut down and power will need to

be cycled. In this mode, unless the short is removed quickly

the fuses in the power supply will blow. After the short is

removed and the fuses replaced the amp will restart. Most

users should not use auto restart, as it is easier for the

customer to cycle power than replace a fuse.

At one third power into 4Ω (333W) the efﬁciency is 85%. The

ampliﬁer shuts down when the heat sink temperature is

o

100 C. Allowing for a temperature rise of 50 degrees above

ambient, the thermal resistance of the heat sink must be

o

approximately 1 C per watt. A fan is highly recommended.

With a small fan, the existing heat sink bolted to the chassis

is more than adequate.

125 mil BARS

SHIELD

EMC COMPLIANCE AND POWER SUPPLY WIRING

TRANSFER PLATE

As with all Harris reference designs the ampliﬁer meets both

FCC and CE requirements when placed in a suitable chassis

with appropriate use of by-pass capacitance. The audio

input requires a 1000pF NPO capacitor to chassis, and the

+speaker cable requires a 0.047µF 200V NPO or X7R

capacitor. The negative audio input and speaker return

should be grounded to the chassis. A power line ﬁlter is also

required to meet conducted emission speciﬁcations.

PC BOARD

FIGURE 7.

Assembly

Make sure the FETs are secure, and use thermal grease on

both sides of the aluminum oxide spacers. Glue the

inductors down and ensure that the coils of the output choke

do not run against the shield. This, may cause a short. The

Teﬂon™ is a trademark of E. I. Du Pont De Nemours and Company.

10

HCA600ACREF

Power supply wiring is important. The wires for the +/-Bus

Authorized Intersil Licensing Agents

must be kept close to their return (power ground). Twisting

the cables is recommended. The bias supplies should also

be kept close to their returns (AGND). Twisting is

recommended. The return for the 12VFLT is the -Bus. The

primary wires for the transformer should be twisted as

should the secondary wires to the rectiﬁers. When twisting is

not possible, use tie wraps. Low frequency EMI issues are

usually due to radiation from the bridge rectiﬁers as the

board itself is compliant.

Asia

Continental Far East, Inc.

3-1-5 Azabudai, Minato-ku

Tokyo 106, Japan

Tel: 03-3584-0339

FAX: 03-3588-0930

All Intersil semiconductor products are manufactured, assembled and tested under ISO9000 quality systems certiﬁcation.

Intersil semiconductor products are sold by description only. Intersil Corporation reserves the right to make changes in circuit design and/or specifications at any time with-

out notice. Accordingly, the reader is cautioned to verify that data sheets are current before placing orders. Information furnished by Intersil is believed to be accurate and

reliable. However, no responsibility is assumed by Intersil or its subsidiaries for its use; nor for any infringements of patents or other rights of third parties which may result

from its use. No license is granted by implication or otherwise under any patent or patent rights of Intersil or its subsidiaries.

For information regarding Intersil Corporation and its products, see web site www.intersil.com

Sales Ofﬁce Headquarters

NORTH AMERICA

EUROPE

ASIA

Intersil Corporation

Intersil SA

Mercure Center

100, Rue de la Fusee

1130 Brussels, Belgium

TEL: (32) 2.724.2111

FAX: (32) 2.724.22.05

Intersil (Taiwan) Ltd.

7F-6, No. 101 Fu Hsing North Road

Taipei, Taiwan

Republic of China

TEL: (886) 2 2716 9310

FAX: (886) 2 2715 3029

P. O. Box 883, Mail Stop 53-204

Melbourne, FL 32902

TEL: (407) 724-7000

FAX: (407) 724-7240

11


型号：	HCA600ACREF
厂家：	Intersil
描述：	600W/1000W Full Bandwidth Class D Amplifier 600W / 1000W全带宽D类放大器放大器
文件：	总11页 (文件大小：353K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

HCA600ACREF [INTERSIL]

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