TDA7266B ,10+10W DUAL BRIDGE AMPLIFIERELECTRICAL CHARACTERISTICS (Continued)Symbol Parameter Test Condition Min. Typ. Max. UnitVT Mute Th ..
TDA7266D ,5W+5W DUAL BRIDGE AMPLIFIERTDA7266D5W+5W DUAL BRIDGE AMPLIFIERPRELIMINARY DATA■ WIDE SUPPLY VOLTAGE RANGE (3.5 - 12V)TECHNOLOG ..
TDA7266D13TR ,7+7W DUAL BRIDGE AMPLIFIERELECTRICAL CHARACTERISTICS (V = 11V, R = 8Ω, f = 1kHz, T = 25°C unless otherwiseCC L ambspecified.) ..
TDA7266L ,5W MONO BRIDGE AMPLIFIERELECTRICAL CHARACTERISTICS (Continued)Symbol Parameter Test Condition Min. Typ. Max. UnitVT St-by T ..
TDA7266M ,7W MONO BRIDGE AMPLIFIERELECTRICAL CHARACTERISTICS (V = 11V, R = 8Ω, f = 1kHz, T = 25°C unless otherwiseCC L ambspecified.) ..
TDA7266P ,3+3W Dual Bridge AmplifierFEATURESFigure 1. Package■ TECHNOLOGY BI20II■ WIDE SUPPLY VOLTAGE RANGE (3.5 - 12V)■ OUTPUT POWER:– ..
THC63LVD1024 , 135MHz 67Bits LVDS Receiver
THC63LVD104 , 90MHz 30Bits COLOR LVDS Receiver
THC63LVD823B , 160MHz 51Bits LVDS Transmitter
THC63LVDM83D , REDUCED SWING LVDS 24Bit COLOR HOST-LCD PANEL INTERFACE
THC63LVDM83D , REDUCED SWING LVDS 24Bit COLOR HOST-LCD PANEL INTERFACE
THC63LVDM87 , LOW POWER / SMALL PACKAGE / 24Bit COLOR LVDS TRANSMITTER
TDA7266B
10+10W DUAL BRIDGE AMPLIFIER
TDA7266B10+10W DUAL BRIDGE AMPLIFIER
WIDE SUPPLY VOLTAGE RANGE (6V -18V)
MINIMUM EXTERNAL COMPONENTS
– NO SVR CAPACITOR
– NO BOOTSTRAP
– NO BOUCHEROT CELLS
– INTERNALLY FIXED GAIN
STAND-BY & MUTE FUNCTIONS
SHORT CIRCUIT PROTECTION
THERMAL OVERLOAD PROTECTION
DESCRIPTIONThe TDA7266B is a dual bridge amplifier specially
designed for TV and Portable Radio applications.
BLOCK AND APPLICATION DIAGRAM
PIN CONNECTION (Top view)
ABSOLUTE MAXIMUM RATINGS
THERMAL DATA
ELECTRICAL CHARACTERISTICS (VCC = 13V, RL = 8Ω, f = 1kHz, Tamb = 25°C unless otherwise
specified.)
TDA7266B2/9
Figure 1: Microprocessor Application
ELECTRICAL CHARACTERISTICS (Continued)
APPLICATION SUGGESTIONSTAND-BY AND MUTE FUNCTIONS
(A) Microprocessor ApplicationIn order to avoid annoying "Pop-Noise" during
Turn-On/Off transients, it is necessary to guaran-
tee the right St-by and mute signals sequence.
It is quite simple to obtain this function using a mi-
croprocessor (Fig. 1 and 2).
At first St-by signal (from mP) goes high and the
voltage across the St-by terminal (Pin 7) starts to
increase exponentially. The external RC network
is intended to turn-on slowly the biasing circuits of
the amplifier, this to avoid "POP" and "CLICK" on
the outputs.
When this voltage reaches the St-by threshold
level, the amplifier is switched-on and the external
capacitors in series to the input terminals (C3,
C5) start to charge.
It’s necessary to mantain the mute signal low until
the capacitors are fully charged, this to avoid that
the device goes in play mode causing a loud "Pop
Noise" on the speakers. delay of 100-200ms between St-by and mute
signals is suitable for a proper operation.
TDA7266B3/9
Figure 2: Microprocessor Driving Signals.
(B) Low Cost ApplicationIn low cost applications where the mP is not pre-
sent, the suggested circuit is shown in fig.3.
The St-by and mute terminals are tied together
and they are connected to the supply line via an
external voltage divider.
The device is switched-on/off from the supply line
and the external capacitor C4 is intended to delay
the St-by and mute threshold exceeding, avoiding
"Popping" problems.
TDA7266B4/9
Figure 3: Stand-alone Low-cost Application.
Figure 3b: PCB and Component Layout of the Application Circuit (Fig. 1).
TDA7266B5/9
0.1 1 10
THD(%)
Pout (W)
Figure 4: Distortion vs Output Power
0.5 20k50 100 200 500 1k 2k 5k 10k
THD(%)
Frequency (Hz)
Figure 5: Distortion vs Frequency
5.0000 100 1k 10k 100k
Level(dBr)
frequency (Hz)
Figure 6: Frequency Respone0
(W) 8 9 10 11 12 Vs(V)
D99AU1080
Figure 7: Output Power vs Supply Voltage 0.5 1234 56 7 8 9 10110
Ptot(W)
2 x Pout (W)
Figure 8: Total Power Dissipation & Efficiency vsOutput Power 1.5 2 2.5 3 3.5 4 4.5 5
Attenuation (dB)
Vpin.6(V)
Figure 9: Mute Attenuation vs. V pin.6
TDA7266B
6/9