CN111860848B - Device, system and method for quantum computing measurement and control - Google Patents

Abstract

The invention discloses a device, a system and a method for quantum computing measurement and control, wherein the device is designed with a horizontal driving piece and a vertical driving piece, a measurement and control cabinet can be driven to move horizontally and vertically by driving a servo motor and a pneumatic cylinder, the whole vertical driving piece can move left and right by the sliding fit of a first limiting block and a first limiting groove, the position of a measurement and control device can be adjusted in the operation process, no dead angle exists in measurement and control, and the position is convenient to adjust for measurement and control; meanwhile, the quantum computing measurement and control system and the method are designed, the data acquisition module acquires the data of quantum computing, transmits the data to the data monitoring module and the data management module, encrypts the data through the data encryption module and outputs the encrypted data through the data output module, and the measurement and control system plays roles in acquisition, detection, management, encryption and output in the whole process, and the modules are strongly connected and convenient to operate.

Description

Device, system and method for quantum computing measurement and control

Technical Field

The invention relates to the field of measurement and control of quantum computation, in particular to a device, a system and a method for quantum computation measurement and control.

Background

The quantum computation is a novel computation mode for regulating and controlling the quantum information unit to calculate according to the quantum mechanics law. Compared with the traditional general computer, the theoretical model is a general turing machine; the theoretical model of the general quantum computer is a general turing machine which is re-interpreted by using the law of quantum mechanics. From the computational aspect, quantum computers can only solve the problems that traditional computers can solve, but from the computational efficiency, some known quantum algorithms can process problems faster than traditional general-purpose computers due to quantum mechanical superposition.

The position of the measurement and control cabinet for quantum calculation measurement and control is fixed in the working process, the measurement and control cabinet is not easy to move, and when four corners are measured and controlled, the measurement and control device can be manually moved to realize measurement and control. Meanwhile, data acquisition, detection, output and the like are needed during measurement and control, but the connection among the modules is not strong, so that a plurality of devices are needed to realize different functions, and the operation is inconvenient.

Disclosure of Invention

In order to solve the defects in the background art, the invention aims to provide a device, a system and a method for quantum computing measurement and control, which are designed with a horizontal driving piece and a vertical driving piece, wherein a servo motor and a pneumatic cylinder are driven to drive a measurement and control cabinet to move horizontally and vertically, and the vertical driving piece integrally moves left and right through the sliding fit of a first limiting block and a first limiting groove, so that the position of a measurement and control device can be adjusted in the operation process, no dead angle exists in measurement and control, and the position is convenient to adjust for measurement and control;

meanwhile, the quantum computing measurement and control system and the method are designed, the data acquisition module acquires the data of quantum computing, transmits the data to the data monitoring module and the data management module, encrypts the data through the data encryption module and outputs the encrypted data through the data output module, and the measurement and control system plays roles in acquisition, detection, management, encryption and output in the whole process, and the modules are strongly connected and convenient to operate.

The aim of the invention can be achieved by the following technical scheme:

the utility model provides a device for quantum calculates measurement and control, includes measurement and control switch board, the below of measurement and control switch board is provided with horizontal driving piece, and horizontal driving piece includes two parallel distribution's first support frame and second support frame, and the upper end of first support frame is fixed with first slide rail, slides on the first slide rail and is provided with first slider, and the upper end of second support frame is fixed with the second slide rail, slides on the second slide rail and is provided with the second slider.

The upper end both sides of second support frame all are fixed with the curb plate, and the end fixing of curb plate has servo motor, servo motor's output fixedly connected with lead screw, and the slip is provided with the nut on the lead screw, fixedly connected with backup pad on the nut, the bottom and the second slider fixed connection of backup pad, be connected with the joint board between the upper end of backup pad and the upper end of first slider.

The top of horizontal drive spare is provided with vertical drive spare, and vertical drive spare includes the foundation column riser of vertical direction, and foundation column riser top one side is fixed with the foundation column diaphragm, and the upper end of foundation column diaphragm is fixed with the pneumatic cylinder, and the pneumatic cylinder activity on the pneumatic cylinder runs through the foundation column diaphragm, and the bottom mounting of pneumatic cylinder has the lifter plate.

The bottom end fixing of lifter plate has the supporting baseplate, observes and controls the switch board setting and is fixed with the limiting plate respectively in the upper end of supporting baseplate, and the equal threaded connection of side of limiting plate has the screw rod, and one end of screw rod is provided with the baffle, and another end of screw rod is provided with the handle, and the side of baffle is provided with the grip block, and grip block and baffle contact each other but are not fixed.

The bottom of grip block is provided with the second stopper, and second stopper and seting up the second spacing groove sliding fit on supporting the base plate.

Further, the upper surface of the bearing plate is provided with first limit grooves which are distributed in parallel and are in a T shape.

Further, the side of foundation post riser is provided with the connecting plate, and the bottom of connecting plate is provided with the first stopper that is the T type of parallel distribution, first stopper and first spacing groove sliding fit.

Further, a third sliding block is fixed on the side wall, close to the top end, of the lifting plate, the third sliding block is arranged on a third sliding rail in a sliding mode, and the third sliding rail is fixed on the inner wall of the base column vertical plate.

Further, the measurement and control cabinet comprises a cabinet body, a door body and a signal lamp are respectively arranged at the side end and the upper end of the cabinet body, and a display screen is arranged at the upper end of the door body.

The measurement and control system comprises a measurement and control cabinet, wherein a PLC (programmable logic controller) is arranged in the measurement and control cabinet and is connected with a data acquisition module, a data monitoring module, a data management module, a data encryption module and a data output module.

Further, the data acquisition module, the data monitoring module, the data management module, the data encryption module and the data output module are sequentially connected.

A method for quantum computing measurement and control, the measurement and control method comprising the steps of:

the data acquisition module acquires quantum calculated data, transmits the quantum calculated data to the data monitoring module and the data management module, encrypts the quantum calculated data through the data encryption module and outputs the quantum calculated data through the data output module.

The invention has the beneficial effects that:

1. the invention is designed with a horizontal driving piece and a vertical driving piece, the measurement and control cabinet can be driven to move horizontally and vertically by driving the servo motor and the pneumatic cylinder, the vertical driving piece can move left and right integrally by the sliding fit of the first limiting block and the first limiting groove, the position of the measurement and control device can be adjusted in the operation process, no dead angle exists in measurement and control, and the position can be conveniently adjusted for measurement and control;

2. the invention designs a quantum computing measurement and control system and a method, and starts, the data acquisition module acquires data of quantum computing, transmits the data to the data monitoring module and the data management module, encrypts the data through the data encryption module and outputs the data through the data output module, and the measurement and control system plays roles of acquisition, detection, management, encryption and output in the whole process, and the modules are strongly connected and convenient to operate.

Drawings

The invention is further described below with reference to the accompanying drawings.

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of a horizontal drive member of the present invention;

FIG. 3 is a schematic view of a vertical drive of the present invention;

FIG. 4 is a schematic view of a support substrate of the present invention;

FIG. 5 is a schematic diagram of a measurement and control cabinet of the present invention;

FIG. 6 is a schematic diagram of a measurement and control system of the present invention.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

In the description of the present invention, it should be understood that the terms "open," "upper," "lower," "thickness," "top," "middle," "length," "inner," "peripheral," and the like indicate orientation or positional relationships, merely for convenience in describing the present invention and to simplify the description, and do not indicate or imply that the components or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present invention.

The device for quantum computing measurement and control comprises a measurement and control cabinet 4, wherein a horizontal driving piece 1 is arranged below the measurement and control cabinet 4, and the horizontal driving piece 1 comprises a first supporting frame 11 and a second supporting frame 12 which are distributed in parallel. The upper end of the first supporting frame 11 is fixed with a first sliding rail 13, and a first sliding block 131 is slidably arranged on the first sliding rail 13; the upper end of the second support frame 12 is fixed with a second slide rail 14, and a second slide block 141 is slidably arranged on the second slide rail 14.

The upper end both sides of second support frame 12 are fixed with curb plate 142, and the tip of curb plate 142 is fixed with servo motor 15, and servo motor 15's output fixedly connected with lead screw 151, the last nut 152 that slides and be provided with of lead screw 151, fixedly connected with backup pad 16 on the nut 152, the bottom and the second slider 141 fixed connection of backup pad 16 are connected with between the upper end of backup pad 16 and the upper end of first slider 131 and accept board 17, and the upper surface of accepting board 17 opens and has parallel distribution's the first spacing groove 171 that is T.

By driving the servo motor 15, the nut 152 slides on the screw 151, and the support plate 16 and the first slider 131 can drive the receiving plate 17 to slide horizontally.

As shown in fig. 1 and 3, a vertical driving member 2 is arranged above the horizontal driving member 1, the vertical driving member 2 comprises a base column vertical plate 21 in the vertical direction, a connecting plate 22 is arranged at the side end of the base column vertical plate 21, a first limiting block 221 which is in a T shape and is distributed in parallel is arranged at the bottom end of the connecting plate 22, and the first limiting block 221 and the first limiting groove 171 are in sliding fit. A base column transverse plate 23 is fixed on one side of the top end of the base column vertical plate 21, a pneumatic cylinder 24 is fixed on the upper end of the base column transverse plate 23, a pneumatic cylinder 241 on the pneumatic cylinder 24 movably penetrates through the base column transverse plate 23, and a lifting plate 25 is fixed on the bottom end of the pneumatic cylinder 241.

The side wall of the lifting plate 25, which is close to the top end, is fixed with a third sliding block 26, the third sliding block 26 is slidably arranged on a third sliding rail 27, and the third sliding rail 27 is fixed on the inner wall of the base column vertical plate 21.

The vertical driving member 2 as a whole can be moved left and right by the sliding fit of the first stopper 221 and the first stopper groove 171. By driving the pneumatic cylinder 24, the lifting plate 25 can be moved up and down in the direction of the third slide rail 27.

As shown in fig. 1 and 4, the bottom end of the lifting plate 25 is fixed with a supporting base plate 3, both side ends of the supporting base plate 3 are respectively fixed with a limiting plate 31, both side ends of the limiting plate 31 are connected with a screw rod 32 in a threaded manner, one end of the screw rod 32 is provided with a baffle 321, the other end of the screw rod 32 is provided with a handle 322, a clamping plate 33 is arranged on the side of the baffle 321, and the clamping plate 33 and the baffle 321 are in contact but not fixed with each other.

The bottom of grip block 33 is provided with second stopper 331, and second stopper 331 and seting up the second spacing groove 34 sliding fit on supporting substrate 3, and rotation handle 322 can adjust the distance between two grip blocks 33 through screw feeding.

As shown in fig. 1 and 5, the measurement and control cabinet 4 is disposed at an upper end of the support substrate 3, the measurement and control cabinet 4 includes a cabinet body 41, a door body 42 and a signal lamp 44 are respectively disposed at a side end and an upper end of the cabinet body 41, and a display screen 43 is disposed at an upper end of the door body 42.

In use, the two clamping plates 33 can clamp the measurement and control cabinet 4 by rotating the handle 322. The measurement and control cabinet 4 can be driven to move horizontally and vertically through the horizontal driving piece 1 and the vertical driving piece 2, so that the position can be conveniently adjusted to carry out measurement and control.

The utility model provides a be used for quantum calculation measurement and control system, includes measurement and control switch board 4, is provided with the PLC controller in the measurement and control switch board 4, and the PLC controller is connected with data acquisition module, data monitoring module, data management module, data encryption module and data output module. The data acquisition module, the data monitoring module, the data management module, the data encryption module and the data output module are sequentially connected.

The data acquisition module acquires data of quantum computation, transmits the data to the data monitoring module and the data management module, encrypts the data through the data encryption module and outputs the data through the data output module. In the whole process, the measurement and control system plays roles of acquisition, detection, management, encryption and output.

In the description of the present specification, the descriptions of the terms "one embodiment," "example," "specific example," and the like, mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present invention. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiments or examples. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The foregoing has shown and described the basic principles, principal features and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present invention, and various changes and modifications may be made without departing from the spirit and scope of the invention, which is defined in the appended claims.

Claims (6)

1. The utility model provides a device for quantum computation observes and controls, includes measurement and control cabinet (4), its characterized in that, the below of measurement and control cabinet (4) is provided with horizontal driving piece (1), horizontal driving piece (1) are including two parallel distribution's first support frame (11) and second support frame (12), the upper end of first support frame (11) is fixed with first slide rail (13), slide on first slide rail (13) and be provided with first slider (131), the upper end of second support frame (12) is fixed with second slide rail (14), slide on second slide rail (14) and be provided with second slider (141);

the two sides of the upper end of the second supporting frame (12) are fixedly provided with side plates (142), the end parts of the side plates (142) are fixedly provided with servo motors (15), the output ends of the servo motors (15) are fixedly connected with screw rods (151), nuts (152) are slidably arranged on the screw rods (151), the nuts (152) are fixedly connected with supporting plates (16), the bottom ends of the supporting plates (16) are fixedly connected with second sliding blocks (141), and a bearing plate (17) is connected between the upper ends of the supporting plates (16) and the upper ends of the first sliding blocks (131);

a vertical driving piece (2) is arranged above the horizontal driving piece (1), the vertical driving piece (2) comprises a base column vertical plate (21) in the vertical direction, a base column transverse plate (23) is fixed on one side of the top end of the base column vertical plate (21), a pneumatic cylinder (24) is fixed at the upper end of the base column transverse plate (23), a pneumatic cylinder (241) on the pneumatic cylinder (24) movably penetrates through the base column transverse plate (23), and a lifting plate (25) is fixed at the bottom end of the pneumatic cylinder (241);

the bottom end of the lifting plate (25) is fixedly provided with a supporting substrate (3), the measurement and control cabinet (4) is arranged at the upper end of the supporting substrate (3), two side ends of the supporting substrate (3) are respectively fixedly provided with a limiting plate (31), the side ends of the limiting plates (31) are respectively connected with a screw rod (32) in a threaded manner, one end part of the screw rod (32) is provided with a baffle (321), the other end part of the screw rod (32) is provided with a handle (322), the side of the baffle (321) is provided with a clamping plate (33), and the clamping plate (33) and the baffle (321) are in contact but not fixed;

the bottom end of the clamping plate (33) is provided with a second limiting block (331), and the second limiting block (331) is in sliding fit with a second limiting groove (34) formed in the supporting substrate (3);

the upper surface of the bearing plate (17) is provided with first limit grooves (171) which are distributed in parallel and are in a T shape;

the side end of the base column vertical plate (21) is provided with a connecting plate (22), the bottom end of the connecting plate (22) is provided with first limiting blocks (221) which are distributed in parallel and are in T shape, and the first limiting blocks (221) are in sliding fit with the first limiting grooves (171).

2. The device for quantum computing measurement and control according to claim 1, wherein a third sliding block (26) is fixed on the side wall, close to the top end, of the lifting plate (25), the third sliding block (26) is slidably arranged on a third sliding rail (27), and the third sliding rail (27) is fixed on the inner wall of the base column vertical plate (21).

3. The device for quantum computing measurement and control according to claim 1, wherein the measurement and control cabinet (4) comprises a cabinet body (41), a door body (42) and a signal lamp (44) are respectively arranged at the side end and the upper end of the cabinet body (41), and a display screen (43) is arranged at the upper end of the door body (42).

4. A device for quantum computing measurement and control system, comprising the device for quantum computing measurement and control according to any one of claims 1-3, wherein the measurement and control system comprises a measurement and control cabinet (4), and a PLC (programmable logic controller) is arranged in the measurement and control cabinet (4) and is connected with a data acquisition module, a data monitoring module, a data management module, a data encryption module and a data output module.

5. The system of claim 4, wherein the data acquisition module, the data monitoring module, the data management module, the data encryption module and the data output module are sequentially connected.

6. A method for quantum computing measurement and control, comprising the system for quantum computing measurement and control according to claim 4 or 5, characterized in that the method for measurement and control comprises the following steps:

the data acquisition module acquires quantum calculated data, transmits the quantum calculated data to the data monitoring module and the data management module, encrypts the quantum calculated data through the data encryption module and outputs the quantum calculated data through the data output module.

Images