Texas Instruments 3 Channel 25W Audio Power Amplifier with Mute and Standby LM4782TABD/NOPB LM4782TABD/NOPB Datenbogen
Produktcode
LM4782TABD/NOPB
SNAS231B – FEBRUARY 2004 – REVISED MARCH 2013
BI-AMP AND TRI-AMP APPLICATIONS
Bi-amping is the practice of using two different amplifiers to power the individual drivers in a speaker enclosure.
For example, a two-way speaker enclosure might have a tweeter and a subwoofer. One amplifier would drive the
tweeter and another would drive the subwoofer. One advantage is that the gain of each amplifier can be adjusted
for the different driver sensitivities. Another advantage is the crossover can be designed before the amplifier
stages with low cost op amps instead of large passive components. With the crossover before the amplifier
stages no power is wasted in the passive crossover as each individual amplifier provides the correct frequencies
for the driver. Tri-Amping is using three different amplifier stages in the same way bi-amping is done. Bi-amping
can also be done on a three-way speaker design by using one amplifier for the subwoofer and another for the
midrange and tweeter.
For example, a two-way speaker enclosure might have a tweeter and a subwoofer. One amplifier would drive the
tweeter and another would drive the subwoofer. One advantage is that the gain of each amplifier can be adjusted
for the different driver sensitivities. Another advantage is the crossover can be designed before the amplifier
stages with low cost op amps instead of large passive components. With the crossover before the amplifier
stages no power is wasted in the passive crossover as each individual amplifier provides the correct frequencies
for the driver. Tri-Amping is using three different amplifier stages in the same way bi-amping is done. Bi-amping
can also be done on a three-way speaker design by using one amplifier for the subwoofer and another for the
midrange and tweeter.
The LM4782 is perfectly suited for bi-amp or tri-amp applications with it's three amplifiers. Two of the amplifiers
can be configured for bridge or parallel mode to drive a subwoofer with the third amplifier driving the tweeter or
tweeter and midrange. An example would be to use a 4
can be configured for bridge or parallel mode to drive a subwoofer with the third amplifier driving the tweeter or
tweeter and midrange. An example would be to use a 4
Ω
subwoofer and 8
Ω
tweeter/midrange with the LM4782
in parallel and single-ended modes. Each amplifier would see an 8
Ω
load but the subwoofer would have twice
the output power as the tweeter/midrange. The gain of each amplifier may also be adjusted for the desired
response. Using the LM4782 in a tri-amp configuration would allow the gain of each amplifier to be adjusted to
achieve the desired speaker response.
response. Using the LM4782 in a tri-amp configuration would allow the gain of each amplifier to be adjusted to
achieve the desired speaker response.
SINGLE-SUPPLY AMPLIFIER APPLICATION
The typical application of the LM4782 is a split supply amplifier. But as shown in
, the LM4782 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 LM4782 functions, like the mute
function.
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 LM4782 functions, like the mute
function.
The LM4782 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 LM4782, a “level shifter,” like the one shown in
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 LM4782, a “level shifter,” like the one shown in
, must be employed. A
level shifter is not needed in a split-supply configuration since ground is also half-supply.
Figure 49. Level Shift Circuit
When the voltage at the Logic Input node is 0V, the 2N3904 is “off” and thus resistor R
c
pulls 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. R
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. R
shift
, along with C
shift
, creates an RC time constant
that reduces transients when the mute or standby functions are enabled or disabled. Additionally, R
shift
limits the
current supplied by the internal logic gates of the LM4782 which insures device reliability. Refer to the
and
sections in the
section for a more detailed description of
these functions.
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