论文部分内容阅读
A literal circuit with a three-track-output structure is presented based on resonant tunneling diodes(RTDs).It can be transformed conveniently into a single-track-output structure according to the definition and properties of the literal operation.A ternary resonant tunneling JK flip-flop is created based on the RTD literal circuit and the module-3 operation,and the JK flip-flop also has two optional types of output structure.The design of the ternary RTD JK flip-flop is verified by simulation.The RTD literal circuit is the key design component for achieving various types of multi-valued logic(MVL) flip-flops.It can be converted into ternary D and JK flip-flops,and the ternary JK flip-flop can also be converted simply and conveniently into ternary D and ternary T flip-flops when the input signals satisfy certain logical relationships.All these types of flip-flops can be realized using the traditional Karnaugh maps combined with the literal and module-3 operations.This approach offers a novel design method for MVL resonant tunneling flip-flop circuits.
A literal circuit with a three-track-output structure is presented based on resonant tunneling diodes (RTDs). It can be transformed to a single-track-output structure according to the definition and properties of the literal operation. A ternary resonant tunneling JK flip-flop is created based on the RTD literal circuit and the module-3 operation, and the JK flip-flop also has two optional types of output structure. The design of the ternary RTD JK flip-flop is verified by simulation. RTD literal circuit is the key design component for achieving various types of multi-valued logic (MVL) flip-flops. It can be converted into ternary D and JK flip-flops, and the ternary JK flip-flop can also be simply converted and conveniently into ternary D and ternary T flip-flops when the input signals satisfy certain logical relationships. All these types of flip-flops can be realized using the traditional Karnaugh maps combined with the literal and module-3 operations. this provide offers a novel design method for MVL resonant tunneling flip-flop circuits.