SANYO LA4260 Datasheet

Ordering number: EN5644

Monolithic Linear IC

LA4260

2.5 W 2-Channel AF Power Amplifier for
Home Stereos and Music Centers

Features

.

Minimum number of external parts required
(No input capacitor, bootstrap capacitor required).

.

High output: 2.5 W typ. ×2.

.

Soft clip, causing little harmonic disturbance to radios
(See page 8).

.

Small pop noise at the time of power switch ON/OFF
(See page 8).

.

Built-in protector against abnormal modes (Thermal
shutdown, overvoltage).

Package Dimensions

3018A-SIP10F

unit : mm

[LA4260]

SANYO : SIP10F

Specifications

Maximum Ratings at Ta = 25°C

Parameter Symbol Conditions Ratings Unit
Maximum supply voltage V
Maximum output current I

Allowable power dissipation Pd max
Operating temperature Topr –20 to +75 °C

Storage temperature Tstg –40 to +150 °C

max 22 V

CC

OP

1 channel 2.0 A
With heat sink

(see Pd – Ta characteristics)

6.2 W

Operating Conditions at Ta = 25°C

parameter Symbol Conditions Ratings Unit
Recommended supply voltage V
Recommended load resistance R
Operating supply voltage range V

CC

CC

L

op 9to21 V

14 V

8 Ω

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22897HA(II) No.5644-1/8

LA4260

Operating Characteristics at Ta = 25°C, VCC=14V,RL=8Ω,f=1kHz, Rg = 600 Ω, (circuit 1)

Parameter Symbol Conditions min typ max Unit

Quiescent current I

CCO

Voltage gain VG 48 50 52 dB
Output power P

O

Total harmonic distortion THD P
Output noise voltage V

NO

THD = 10% 2.0 2.5 W

= 0.5 W 0.3 1.0 %

O

Rg=10kΩ, BW = 20 Hz to 20 kHz 0.65 1.5 mV
Ripple rejection ratio Rr Rg = 0, Vr = 500 mV 40 50 dB
Crosstalk CT Rg = 10 kΩ 40 55 dB
Voltage gain difference ∆VG 1.5 dB

Equivalent Circuit Block Diagram

45 60 mA

Allowable power dissipation, Pd max – W

Pd max – Ta

Infinite heat sink

No heat sink

Ambient temperature, Ta – °C

Al heat sink Tightening
torque 39 NcCm
Silicon grease applied

Thermal resistance
between junction
and outside air

θj-c 10°C/W

– °C/W

f

Thermal resistance of heat sink, θ

θf–S

f

Al heat sink t = 1.5 mm

Area of heat sink, Sf–cm

2

No.5644-2/8

LA4260

Sample Application Circuit 1:

Recommended Circuit

Sample Printed Circuit Pattern

Sample Application Circuit 2:

Circuit with minimum number of external
parts

Unit (resistance: Ω, capacitance: F)

Unit (resistance: Ω, capacitance: F)

Description of External Parts

C1, C4 100 µF Feedback capacitor

C2, C3 330 pF Input short capacitor

C5, C7 470 µF Output capacitor

C6, C8 0.1 µF

polyester film

capacitor

C9 470 µF Power capacitor

C10 100 µF Ripple filter capacitor

R1, R2 100 kΩ Input bias resistor

R3, R4 3.3 Ω Resistor connected in series with oscillation blocking capacitor.

Decreasing the capacitance value lowers the low frequency response. Increasing the
capacitance value makes the starting time later.

Reduces the high frequency noise when the input impedance is increased. Not required
when the input impedance is decreased.

Decreasing the capacitance value causes insufficient power at low frequencies.
Oscillation blocking capacitor

Decreasing the capacitance value causes oscillation to occur easily. Use a polyester film
capacitor that is good in high frequency response and temperature characteristic. The use
of an electrolytic capacitor may cause oscillation to occur at low temperatures.

Decreasing the capacitance value causes ripple to occur. Locating at a distance from the
IC or removing this capacitor may cause oscillation to occur.

Decreasing the capacitance value excessively or removing this capacitor causes ripple to
occur. However, increasing the capacitance value does not always cause ripple to be
reduced. Decreasing the capacitance value makes the starting time earlier.

Determines the bias (bias of GND potential) to be applied to the input pin and the input
impedance. Not required if variable resistors are used.

Prevents phase shift attributable to the oscillation blocking capacitor so that oscillation is
hard to occur.

No.5644-3/8