CN112379725A - Input/output equipment of optical chip - Google Patents

Abstract

The invention discloses an input/output device for an optical chip, comprising: the system comprises three modules of input equipment, output equipment and an optical signal storage. The optical signal memory of the input and output device of the optical chip converts the optical signals with different frequencies into binary commands and stores a plurality of binary commands into different addresses in the optical signal memory. The input and output equipment of the optical chip converts input characters into binary commands through the input equipment, performs addressing operation of the binary commands through the novel optical energy central processing unit, converts addressing results from the binary into hexadecimal, and displays the results through the output equipment.

Description

Input/output equipment of optical chip

Technical Field

The invention relates to an input-output device for an optical chip.

Technical Field

The memory is mainly a container for storing various commands of the computer system, and the commands stored in the memory are all binary commands. The memory stores a number of computer commands and each command is assigned a unique address number.

The input device is a device for inputting data and information to the computer, and is a bridge for the computer to communicate with a user or other devices, and the input device is one of main devices for exchanging information between the user and a computer system.

The output equipment mainly accepts computer data output display, printing, sound, controls and operates peripheral equipment operation, and also expresses various calculation result data or information in the form of numbers, characters, images, sound and the like.

Disclosure of Invention

The invention aims to solve the input and output problems of a novel optical energy central processing unit.

The input-output device for the optical chip comprises: the input device, the output device and the optical signal storage are three modules.

The optical signal memory stores computer input and output commands to the optical signal memory through the binary optical signal frequency commands through the novel optical energy central processing unit, and the optical signal memory allocates each binary optical signal frequency command to a unique memory address.

The operator inputs command or data to the computer system through the input device, the input command or data is transmitted to the novel optical energy central processing unit, the novel optical energy central processing unit converts the input hexadecimal optical signal command or data into binary optical signal data, and the novel optical energy central processing unit transmits the converted binary optical signal data or binary optical signal command to the optical signal storage.

The optical signal memory receives binary optical signal data from the novel optical energy processor, and carries out addressing operation of the optical signal memory through optical signal frequency.

The optical signal memory returns the addressing result to the novel optical energy central processing unit in a binary optical signal frequency mode.

The novel optical energy central processing unit receives the binary optical signal frequency data or the command, converts the binary optical signal frequency data or the command into hexadecimal optical signal frequency data or the command, and transmits the hexadecimal optical signal frequency data or the command to the output equipment through the novel optical energy central processing unit.

When the output device of the optical chip receives the hexadecimal optical signal frequency data or the command, the hexadecimal optical signal frequency data or the command is displayed through the output device.

Drawings

FIG. 1 is a schematic block diagram showing the overall configuration and flow of the system.

Detailed Description

Firstly, when an operator presses a start key, the input and output equipment of the optical chip can check whether the access is normal or not.

When the input and output device of the optical chip is normally connected, an operator can perform normal input operation through the input device of the optical chip.

When the input equipment of the optical chip is abnormally accessed, the input equipment can be displayed through the output equipment of the optical chip and is reminded of abnormal access.

When an operator has input data or commands, the input equipment is subjected to character splitting through the input data or commands by the novel optical energy central processing unit, the address matching speed is improved through the character splitting, and the operator has good experience.

The specific hexadecimal optical signal frequency value of the operator input command or data is determined by the character split by the novel optical energy central processing unit.

When the novel optical energy central processing unit does not divide data or commands input by an operator, the address matching speed is low, and similarly, the data or commands input by the operator are converted into hexadecimal systems.

When an operator inputs an error command or error data through the input device and transmits the error data or command to the novel optical energy central processing unit, the novel optical energy central processing unit can not determine the specific hexadecimal optical signal frequency value of the command or data input by the operator.

And the correct hexadecimal optical signal frequency value is converted into a binary optical signal frequency value by the novel optical energy central processing unit.

And transmitting the converted binary optical signal frequency value to an optical signal storage, performing memory address matching of the binary optical signal frequency value, and performing value taking operation on the matched memory address.

If the binary optical signal frequency value is transmitted to the optical signal storage, when the binary optical signal frequency value cannot be matched with the memory address, the matching result is transmitted to the novel optical energy central processing unit, and the matching result is displayed through the output equipment.

If the binary optical signal frequency value is successfully matched, the binary frequency value matched from the memory address is taken out, and the binary value is transmitted to the novel optical energy central processing unit.

When the novel optical energy central processing unit receives the transmitted binary frequency value, the binary optical signal frequency value is converted into the hexadecimal optical signal frequency, and the hexadecimal optical signal frequency value is transmitted to the output equipment of the optical chip.

When the output device of the optical chip receives the hexadecimal optical signal frequency value, the hexadecimal optical signal frequency value is converted into specific data or a command, and finally the specific data or the command is displayed for a user to view.

The above-described implementation of the present invention is only for clearly illustrating the technical solutions of the present invention, and is not to be understood as limiting the present invention in any way. The present invention has many known alternatives and modifications in the art, which fall within the scope of the present invention without departing from the spirit of the present invention.

Claims (4)

1. The invention discloses an input/output device for an optical chip, comprising: the input device, the output device and the optical signal storage are three modules.

2. Storing the optical signals with different frequencies into an optical signal storage, allocating independent addresses to the optical signals, and enabling the addresses to be unique identifiers of commands.

3. The input content is transmitted to a novel optical energy central processing unit through the input equipment of the optical chip, the input characters are subjected to binary conversion, hexadecimal conversion is carried out to binary commands, and the addressing operation of the optical signal memory is carried out through the binary commands.

4. And converting the addressing result from binary system to hexadecimal system, and displaying the addressing result from the hexadecimal system through an output device.

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