Push–pull output: Difference between revisions

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Line 5: [[File:Pushpull.svg\|right\|thumb\|A Class B push–pull output driver using a pair of complementary PNP and NPN [[bipolar junction transistor]]s configured as [[emitter follower]]s]] ~~[[Australia\|~~A]] '''push–pull''' amplifier is a type of [[electronic circuit]] that uses a pair of active devices that alternately supply current to, or absorb current from, a connected load. This kind of amplifier can enhance both the load capacity and switching speed. Push–pull outputs are present in [[Transistor-transistor logic\|TTL]] and [[CMOS]] digital [[logic circuit]]s and in some types of [[electronic amplifier\|amplifiers]], and are usually realized by a complementary pair of [[transistor]]s, one dissipating or ''sinking'' current from the load to ground or a negative power supply, and the other supplying or ''sourcing'' current to the load from a positive power supply. Line 28: == Digital circuits == [[File:7400 Circuit.svg\|right\|thumb\|Circuit of [[Transistor–transistor logic\|TTL]] [[NAND gate]] has a 'totem pole output' stage ''(right)'' consisting of two NPN transistors in push pull. When at least one of the inputs is low, transistor ''V''<sub>1</sub> is turned on, ''V''<sub>2</sub> is turned off, ''V''<sub>3</sub> is turned on and ''V''<sub>4</sub> off, pulling output voltage high. When both inputs are high, ''V''<sub>2</sub> is on, ''V''<sub>3</sub> is off and ''V''<sub>4</sub> is turned on, pulling output low.]] A digital use of a push–pull configuration is the output of TTL and related families. The upper transistor is functioning as an active pull-up, in linear mode, while the lower transistor works digitally. For this reason they are not capable of sourcing as much current as they can ''sink'' (typically 20 times less). Because of the way these circuits are drawn schematically, with two transistors stacked vertically, normally with a level shifting diode in between, they are called "'''totem pole'''" outputs. Line 83: The transformer-less circuit with two tetrode tubes dates back to 1933: "THE USE OF A VACUUM TUBE AS A PLATE-FEED IMPEDANCE." by J.W.Horton in the Journal of the Franklin Institute 1933 volume 216 Issue 6 The '''White Cathode Follower''' (Patent 2,358,428, Sep. 1944 by E. L. C. White) is similar to the SEPP design above, but the signal input is to the ''top'' tube, acting as a cathode follower, but one where the bottom tube (in common cathode configuration) ifis fed (usually via a step-up transformer) from the current in the plate (anode) of the top device. It essentially reverses the roles of the two devices in SEPP. The bottom tube acts part way between a constant current sink and an equal partner in the push–pull workload. Again, the drive to each tube therefore might not be equal. Transistor versions of the SEPP and White follower do exist, but are rare.