Exploring Logic Circuits: T Flip-Flop Circuits

T flip-flop circuits 

A flip-flop also regarded as the latch is an electronic circuit that contains two different states that can be used to store information in these various state. In much simpler terms a flip-flop can be termed as a bi-stable multivibrator ( Geary et al., 2015 ). In this aspect, the real stability of the circuit is determined by the charge passing in the circuit in the current moment. In this aspect, the dictation of the circuit’s state is determined by the signal sent from the input unit. In this manner, the state of the circuit is determined by the fate of two different signals from the input. However, the flip-flop circuits have a couple of various circuits such as Toggle flip-flop. 

The T flip-flop circuits acquire its name from the ability to toggle between two different state, which is the memory state and the toggle state ( Geary et al., 2015 ). Through this ability to maintain to maneuver through the two different states, the circuit tends to be the best choice since the two states can be “1” or “0” representing ON and OFF respectively. 

Commonly regarded as T flip-flop, is one of the circuits that significantly changes on the edge of each clock edge. In this manner, there is a high variation of the signal given. The circuit provides nearly a half of the input signal provided by the T input. Through this aspect, the T flip-flop circuit is highly convincing and significantly used in the construction of the binary counters, binary addition devices as well as the frequency dividers. On the same note, the circuit can also be made from J-K flip-flop ( Lin et al., 2014 ). By tying the two different inputs of the J-K circuit with a high voltage, this can be used to create or manufacture the Toggle circuit significantly. In this aspect, T flip-flop is used to make a parallel register of the 2-bit load. 

References 

Lin, Y. F., Xu, Y., Wang, S. T., Li, S. L., Yamamoto, M., Aparecido‐Ferreira, A., ... & Ueno, K. (2014). Ambipolar MoTe2 transistors and their applications in logic circuits. Advanced Materials , 26 (20), 3263-3269. 

Geary, K., Casey, R., Carey, D., & Mallard, T. (2015). U.S. Patent No. 9,209,809 . Washington, DC: U.S. Patent and Trademark Office.