8120E 主机架 英维思系统模块

The TRICONEX 8312 can create integrated circuits to perform arbitrary operations on analog and digital signals. In computation, signals are usually digital and can be interpreted as binary data. Computer hardware and software operate on binary representations of information to perform calculations; This is done by calculating the Boolean function in… The upper input and output results are stored downstream for some output devices; Reserve or further processing.

TRICONEX 8312 Because all Turing machines can run any computable function it is always possible to design custom hardware that performs the same function as a given software. Instead, software can always be used to simulate the functionality of a given piece of hardware. Custom hardware can provide a higher performance-to-power ratio for the same functions specified in software. Hardware description languages (HDL) such as Verilog and very high density lipoprotein can simulate the same semantics as software and synthesise design into a nettable that can be programmed into an FPGA or written into a logic gate integrated circuit.

The vast majority of software-based computing in the TRICONEX 8312 takes place in implementation of von Neumann buildings, collectively known as stored program computers. Computer programs are stored as data executed by processors. Such a processor must extract and decode instructions, as well as load data operands from memory (as part of the instruction cycle) to execute the instructions that make up the software program. Relying on a common cache results in a “von Neumann bottleneck,” which is a fundamental limitation on software throughput on processors that implement von Neumann architectures. Even in the modified Harvard building, where instructions and data are decoded in hierarchical memory systems, instructions have overhead opcodes and multiplexing techniques available to execute units in a microprocessor or microcontroller, resulting in low circuit utilization. Modern processors offer simultaneous multithreading to take advantage of the underutilized instruction-level parallelism of available processor functional units between different hardware threads.