CN112067159A - Temperature measuring device - Google Patents

Abstract

The application discloses temperature measurement device includes: the temperature measuring device comprises a processor and a plurality of temperature measuring sensors electrically connected with the processor; the processor is used for obtaining first target position data of the plurality of temperature measurement sensors in a target temperature measurement area and obtaining temperature data which are measured by the plurality of temperature measurement sensors and correspond to the first target position data. By using the temperature measuring device, the temperature data of different positions in the target temperature measuring area can be accurately measured based on a single temperature measuring device, so that the temperature data corresponding to a plurality of preset temperature measuring points in the target temperature measuring area can be accurately obtained.

Description

Temperature measuring device

Technical Field

The application relates to the field of temperature measurement, in particular to a temperature measurement device. The application also relates to a temperature data processing method, a temperature data processing device, electronic equipment and a computer readable storage medium. The application also relates to a data transmission method, a device, an electronic device and a computer readable storage medium.

Background

Temperature measuring devices applied in cold/hot chain transportation can be divided into two categories: one is that the measured temperature data and the corresponding time stamp are stored locally after each measurement, and after the measurement process (for example, the whole transportation journey) is finished, the data stored in the temperature measurement device is read and analyzed in a centralized manner; and the other type is that after each temperature measurement, the measured temperature data is transmitted to a gateway, an intelligent terminal, a monitoring device or a network platform server in real time so as to realize the real-time monitoring of the cold/hot chain transportation quality. For example, in an instant delivery (take-out) scene, a delivery person usually needs to open a delivery box many times to take and place meals and articles, and the temperature in the box body is affected by the external environment temperature, so that the change of the temperature in the box body can be rapidly and accurately detected and timely transmitted, and the quality control of a cold/hot chain transportation process is greatly facilitated. For example, in cold chain transportation, when the temperature in the box body exceeds a preset temperature range, an alarm prompt or a refrigerant replacement prompt is sent out in time, so that the transportation quality is ensured; on the contrary, if the temperature in the box body rises temporarily because the box cover is opened, the temperature in the box body can quickly fall to a normal temperature range because the refrigerant is sufficient, and under the condition, the temperature measuring device sensitive to reaction can detect new temperature in time, so that the phenomenon that an error alarm prompt or a refrigerant replacement prompt is sent out is avoided.

In order to enable the measured temperature to truly reflect the heat preservation condition of the box body, measuring the ambient temperature in the box body is a direct and effective method, however, the actual ambient temperature in the box body cannot be measured by the existing temperature measuring method aiming at the refrigerant, for example, under the condition that the temperature of the refrigerant is normal, the temperature in the box body exceeds the standard because the box cover is not closed, and the heat preservation quality of the box body cannot be reflected by the method of monitoring the temperature of the refrigerant under the condition. The monitoring of the environmental temperature is a non-contact temperature measuring method, which is influenced by the factors such as the placement position, posture, distance from the refrigerant, the temperature of the articles in the box body, and the like of the temperature measuring device, for example, a cold (heat) medium is placed on the side wall or the bottom of the distribution box, so that a temperature field is formed in the box body, the temperature at different positions (especially the height) in the temperature field is different, and the temperature is lower (higher) as the temperature is closer to the cold (heat) medium, so that the problem to be solved is how to accurately measure the temperature at different positions in the box body to obtain the environmental temperature in the box body.

Disclosure of Invention

The embodiment of the application provides a temperature measuring device, a temperature data processing method, a temperature data processing device, electronic equipment and a computer readable storage medium, and aims to solve the problem that the ambient temperature in a box body cannot be accurately obtained in the prior art.

The embodiment of the application provides a temperature measurement device, includes: the temperature measuring device comprises a processor and a plurality of temperature measuring sensors electrically connected with the processor; the processor is used for obtaining first target position data of the plurality of temperature measurement sensors in a target temperature measurement area and obtaining temperature data which are measured by the plurality of temperature measurement sensors and correspond to the first target position data.

Optionally, the method further includes: the pose detection element is arranged corresponding to the mainboard and electrically connected with the processor, and the temperature measurement sensors are fixedly arranged relative to the mainboard; the pose detection element is used for acquiring pose data of the mainboard in the target temperature measurement area and transmitting the pose data to the processor; the processor obtains first target position data of the plurality of thermometric sensors in a target thermometric area, comprising: and acquiring position relation data of the plurality of temperature measurement sensors relative to the mainboard, and acquiring first target position data of the plurality of temperature measurement sensors in the target temperature measurement area according to the pose data of the mainboard in the target temperature measurement area and the position relation data of the plurality of temperature measurement sensors relative to the mainboard.

Optionally, the method further includes: and the processor is also used for sending the first target position data and the temperature data corresponding to the first target position data through the data transceiver component.

Optionally, the number of the data transceiver elements is multiple, and the sending the first target location data and the temperature data corresponding to the first target location data by the data transceiver elements includes: transmitting the first target location data and temperature data corresponding to the first target location data based on a plurality of the data transceiving elements.

Optionally, the temperature measuring device further includes: a data transceiver selector electrically coupled to the processor and the plurality of data transceiver elements, the transmitting the first target location data and the temperature data corresponding to the first target location data based on the plurality of data transceiver elements, comprising: and determining a target data transceiver element from the plurality of data transceiver elements based on the data transceiver performance of the plurality of data transceiver elements in the target temperature measurement area, and instructing the data transceiver selector to control the target data transceiver element to transmit the first target position data and the temperature data corresponding to the first target position data.

Optionally, the method further includes: the pose detection element is arranged corresponding to the mainboard and electrically connected with the processor, and the data transceiver elements are fixedly arranged relative to the mainboard; the pose detection element is used for acquiring pose data of the mainboard in the target temperature measurement area and transmitting the pose data to the processor; the processor is further configured to: obtaining position relation data of the plurality of data transceiver elements relative to the main board, and obtaining second target position data of the plurality of data transceiver elements in the target temperature measurement area according to pose data of the main board in the target temperature measurement area and the position relation data of the plurality of data transceiver elements relative to the main board; correspondingly, the determining a target data transceiver component from the plurality of data transceiver components based on the data transceiver performance of the plurality of data transceiver components in the target temperature measurement area includes: and obtaining target transceiving position data meeting the preset data transceiving performance in the second target position data, and determining a target data transceiving element corresponding to the target transceiving position data from the plurality of data transceiving elements.

Optionally, the obtaining of the target transceiving position data meeting the predetermined data transceiving performance in the second target position data includes: obtaining alternative transceiving position data meeting the predetermined data transceiving performance in the target temperature measuring area based on offline experimental data or historical prior data, wherein the offline experimental data are data obtained after data transceiving performance tests are carried out on data transceiving elements preset at different positions in the target temperature measuring area, and the historical prior data are statistical data of interference degrees corresponding to data transceiving processes at different positions in the target temperature measuring area; and determining the position data matched with the alternative transceiving position data in the second target position data as the target transceiving position data.

Optionally, the determining a target data transceiver element from the plurality of data transceiver elements based on the data transceiver performance of the plurality of data transceiver elements in the target temperature measurement area includes: and instructing the data transceiving selector to perform data transceiving polling operation on the plurality of data transceiving elements, obtaining data transceiving results of the plurality of data transceiving elements in the target temperature measurement area, and determining the target data transceiving elements based on the data transceiving results.

Optionally, the sending the first target location data and the temperature data corresponding to the first target location data based on the plurality of data transceiver components includes: and transmitting the first target position data and the temperature data corresponding to the first target position data based on a data transceiving array composed of a plurality of data transceiving elements.

Optionally, at least two of the plurality of temperature sensors are symmetrically arranged with the predetermined position as a center of symmetry.

Optionally, the predetermined positions include: the geometric center point of the mainboard or the midpoint of a connecting line of at least two target temperature measuring points in the target temperature measuring area, and the at least two temperature measuring sensors are arranged corresponding to the at least two target temperature measuring points.

Optionally, the plurality of temperature measuring sensors are fixedly disposed with respect to the main board, and include: the temperature sensors are fixedly arranged on the mainboard and/or fixedly arranged outside the mainboard.

Optionally, the temperature measuring device further includes a housing, and the plurality of temperature measuring sensors are fixedly disposed outside the main board, including: the temperature sensors extend to the shell outside the mainboard through leads and are fixedly arranged with the shell.

Optionally, the data transceiver component is disposed on the motherboard or disposed outside the motherboard through a lead. Optionally, the data transceiving element is an antenna.

Optionally, the pose detection element is an inertial measurement unit.

Optionally, the temperature measuring device is applied to a distribution box, and the target temperature measuring region is a predetermined measured temperature region in the distribution box.

An embodiment of the present application further provides a temperature measuring device, including: the temperature measurement device comprises a processor, a temperature measurement sensor electrically connected with the processor, and a plurality of data receiving and transmitting elements correspondingly arranged at different positions of a target temperature measurement area; the processor is used for determining a target data transceiver element from the plurality of data transceiver elements based on the data transceiver performance of the plurality of data transceiver elements in the target temperature measuring area, and transmitting the temperature data through the target data transceiver element after receiving the temperature data measured by the temperature measuring sensor.

Optionally, the method further includes: the system comprises a mainboard and a pose detection element which is arranged corresponding to the mainboard and electrically connected with the processor, wherein the pose detection element is used for acquiring pose data of the mainboard in a target temperature measurement area and transmitting the pose data to the processor; the plurality of data transceiver components are fixedly arranged relative to the main board, and the processor determines a target data transceiver component from the plurality of data transceiver components based on data transceiver performance of the plurality of data transceiver components in the target temperature measurement area, including: obtaining positional relationship data of the plurality of data receiving and transmitting elements relative to the main board; obtaining target position data of the data transceiver elements in a target temperature measuring area according to pose data of the main board in the target temperature measuring area and position relation data of the data transceiver elements relative to the main board; and obtaining target transceiving position data meeting the preset data transceiving performance in the target position data, and determining a target data transceiving element corresponding to the target transceiving position data from the plurality of data transceiving elements.

Optionally, the obtaining of the target transceiving position data meeting the predetermined data transceiving performance in the target position data includes: obtaining alternative transceiving position data meeting the predetermined data transceiving performance in the target temperature measuring area based on offline experimental data or historical prior data, wherein the offline experimental data are data obtained after data transceiving performance tests are carried out on data transceiving elements preset at different positions in the target temperature measuring area, and the historical prior data are statistical data of interference degrees corresponding to data transceiving processes at different positions in the target temperature measuring area; and determining the position data matched with the alternative transceiving position data in the target position data as the target transceiving position data.

Optionally, the method further includes: a data transceiver selector electrically connected to the processor and the plurality of data transceiver elements, the processor transmitting the temperature data through the target data transceiver element, comprising: instructing the data transceiver selector to control the target data transceiver element to transmit the temperature data.

Optionally, the determining a target data transceiver element from the plurality of data transceiver elements based on the data transceiver performance of the plurality of data transceiver elements in the target temperature measurement area includes: and instructing the data transceiving selector to perform data transceiving polling operation on the plurality of data transceiving elements, obtaining data transceiving results of the plurality of data transceiving elements in the target temperature measurement area, and determining the target data transceiving elements based on the data transceiving results.

Optionally, the pose detection element is an inertial measurement unit. The data receiving and transmitting element is arranged on the mainboard or arranged outside the mainboard through a lead. The data transceiving element is an antenna.

Optionally, the temperature measuring device is applied to a distribution box, and the target temperature measuring region is a predetermined measured temperature region in the distribution box.

An embodiment of the present application further provides a temperature data processing method, including:

acquiring pose data of a target carrier in a target temperature measuring area, wherein a plurality of temperature measuring sensors are fixedly arranged in the target temperature measuring area corresponding to the target carrier;

obtaining position relation data of the plurality of temperature measuring sensors relative to the target carrier;

obtaining target position data of the temperature measuring sensors in the target temperature measuring area according to the pose data and the position relation data;

and receiving temperature data from the plurality of temperature measuring sensors, and sending the temperature data and the target position data corresponding to the temperature data.

An embodiment of the present application further provides a data sending method, including:

acquiring pose data of a target carrier in a target area, wherein a plurality of data transceiving elements are fixedly arranged in the target area corresponding to the target carrier;

obtaining positional relationship data of the plurality of data-transceiving elements with respect to the target carrier;

obtaining target position data of the plurality of data transceiver elements in the target area according to the pose data and the position relation data;

obtaining target transceiving position data meeting the predetermined data transceiving performance in the target position data;

and determining a data transceiving element corresponding to the target transceiving position data among the plurality of data transceiving elements as a target data transceiving element for receiving and transmitting data in the target area.

The embodiment of the present application further provides that obtaining the target transceiving position data meeting the predetermined data transceiving performance in the target position data includes: obtaining alternative transceiving position data which meet the predetermined data transceiving performance in the target area based on offline experimental data or historical prior data, wherein the offline experimental data are data obtained after data transceiving performance tests are carried out on data transceiving elements preset at different positions in the target area, and the historical prior data are statistical data of interference degrees corresponding to data transceiving processes at different positions in the target area; and determining the position data matched with the alternative transceiving position data in the target position data as the target transceiving position data.

An embodiment of the present application further provides a temperature data processing apparatus, including:

the system comprises a pose data acquisition unit, a pose data acquisition unit and a pose data acquisition unit, wherein the pose data acquisition unit is used for acquiring pose data of a target carrier in a target temperature measurement area, and a plurality of temperature measurement sensors are fixedly arranged in the target temperature measurement area corresponding to the target carrier;

the position relation data acquisition unit is used for acquiring the position relation data of the plurality of temperature measurement sensors relative to the target carrier;

the target position data obtaining unit is used for obtaining target position data of the temperature measuring sensors in the target temperature measuring area according to the pose data and the position relation data;

and the data sending unit is used for receiving the temperature data from the plurality of temperature measuring sensors and sending the temperature data and the corresponding target position data.

An embodiment of the present application further provides a data sending apparatus, including:

a pose data obtaining unit for obtaining pose data of a target carrier in a target area, the target area being fixedly provided with a plurality of data transceiving elements corresponding to the target carrier;

a positional relationship data obtaining unit for obtaining positional relationship data of the plurality of data-transceiving elements with respect to the object carrier;

a target position data obtaining unit configured to obtain target position data of the plurality of data transceiver elements in the target area according to the pose data and the position relationship data;

a target transceiving position data obtaining unit configured to obtain target transceiving position data that satisfies predetermined data transceiving performance among the target position data;

a target data transceiving element determining unit configured to determine a data transceiving element corresponding to the target transceiving position data among the plurality of data transceiving elements as a target data transceiving element for receiving and transmitting data in the target area.

Optionally, the obtaining of the target transceiving position data meeting the predetermined data transceiving performance in the target position data includes: obtaining alternative transceiving position data which meet the predetermined data transceiving performance in the target area based on offline experimental data or historical prior data, wherein the offline experimental data are data obtained after data transceiving performance tests are carried out on data transceiving elements preset at different positions in the target area, and the historical prior data are statistical data of interference degrees corresponding to data transceiving processes at different positions in the target area; and determining the position data matched with the alternative transceiving position data in the target position data as the target transceiving position data.

The embodiment of the application also provides an electronic device, which comprises a processor and a memory; wherein the memory is configured to store one or more computer instructions, wherein the one or more computer instructions are executed by the processor to implement the method as described above.

Embodiments of the present application also provide a computer-readable storage medium having one or more computer instructions stored thereon, which are executed by a processor to implement the method as described above.

Compared with the prior art, the embodiment of the application has the following advantages:

the temperature measuring device that this application embodiment provided includes: the temperature measuring device comprises a processor and a plurality of temperature measuring sensors electrically connected with the processor; the processor is used for obtaining first target position data of the plurality of temperature measurement sensors in a target temperature measurement area and obtaining temperature data which are measured by the plurality of temperature measurement sensors and correspond to the first target position data. By using the temperature measuring device, the temperature data of different positions in a target temperature measuring area can be accurately measured based on a single temperature measuring device, and in a cold/hot chain transportation scene, the temperature data can be used as the environmental temperature data in the transportation box, so that the problem that the existing box can not accurately obtain the environmental temperature in the box is effectively solved.

Drawings

FIG. 1 is a schematic view of a temperature measuring device provided in a first embodiment of the present application;

FIG. 2 is a schematic view of a temperature measuring device provided in a second embodiment of the present application;

FIG. 3 is a flow chart of a temperature data processing method according to a third embodiment of the present application;

fig. 4 is a flowchart of a data transmission method according to a fourth embodiment of the present application;

fig. 5 is a block diagram of a unit of a temperature data processing apparatus according to a fifth embodiment of the present application;

fig. 6 is a schematic logical structure diagram of an electronic device according to a sixth embodiment of the present application;

fig. 7 is a block diagram of a data transmission apparatus according to an eighth embodiment of the present application;

fig. 8 is a schematic logical structure diagram of an electronic device according to a ninth embodiment of the present application;

the attached drawings are marked as follows: mainboard 1, processor 2, data transceiver element 3, temperature sensor 4, position appearance detecting element 5, data transceiver selector 6

Detailed Description

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present application. This application is capable of implementation in many different ways than those herein set forth and of similar import by those skilled in the art without departing from the spirit of this application and is therefore not limited to the specific implementations disclosed below.

Aiming at a temperature measurement scene, in order to accurately obtain temperature data of a plurality of preset temperature measurement points in a temperature measurement area and guarantee data transmission quality, the application provides a temperature measurement device, a temperature data processing method, a temperature data processing device, electronic equipment and a computer readable storage medium corresponding to the method, and also provides a data transmission method, a data transmission device, electronic equipment and a computer readable storage medium corresponding to the method. The following provides embodiments for detailed description of the above method, apparatus, electronic device, and computer-readable storage medium.

As shown in fig. 1, a first embodiment of the present application provides a temperature measuring device including: the temperature measuring system comprises a mainboard 1, a processor 2 arranged on the mainboard 1, a data transceiver element 3, a plurality of temperature measuring sensors 4 electrically connected with the processor 2, and a pose detecting element 5 arranged corresponding to the mainboard 1 and electrically connected with the processor 2, wherein the processor 2 is used for obtaining first target position data of the plurality of temperature measuring sensors 4 in a target temperature measuring area, obtaining temperature data corresponding to the first target position data and measured by the plurality of temperature measuring sensors 4, and sending the first target position data and the temperature data corresponding to the first target position data through the data transceiver element 3.

In the present embodiment, the plurality of temperature sensors 4 are fixedly disposed with respect to the main board 1; the data transceiver component 3 can be an antenna for transmitting or receiving wireless signals, and the pose detection component 5 can be an Inertial Measurement Unit (IMU) for detecting and obtaining pose data (position data and attitude data) of the main board 1 in a target temperature measurement area and transmitting the pose data to the processor 2; the processor 2 obtains first target position data of the plurality of temperature measurement sensors 4 in the target temperature measurement area, which may specifically be: the method comprises the steps of obtaining position relation data of a plurality of temperature measuring sensors 4 relative to a main board 1, and obtaining first target position data of the plurality of temperature measuring sensors 4 in a target temperature measuring area according to pose data of the main board 1 in the target temperature measuring area and the position relation data of the plurality of temperature measuring sensors 4 relative to the main board 1. After receiving the temperature data measured by the plurality of temperature measuring sensors 4, the processor 2 sends the first target position data and the corresponding temperature data through the data transceiver component 3. For example, in a take-out delivery scenario, the temperature measuring device may be applied to a delivery box, the target temperature measurement area may be a predetermined measured temperature area in the delivery box, and the data transceiver component 3 transmits a plurality of position data corresponding to the plurality of temperature measuring sensors 4 in the target temperature measurement area and temperature data corresponding to each position data to a delivery resource having a terminal delivery capability and a data transceiver function, such as a network platform server of a take-out platform, a delivery unmanned aerial vehicle, a delivery robot, or a delivery unmanned vehicle, for monitoring and counting an ambient temperature corresponding to the measured temperature area of the delivery box.

The position relation data of the plurality of temperature sensors 4 relative to the main board 1 can be position data and distance data of each temperature sensor 4 of the plurality of temperature sensors 4 relative to a geometric center point or other preset reference points of the main board 1, and first target position data of the plurality of temperature sensors 4 in a target temperature measuring area can be calculated and obtained through the position data, the distance data, and position data and posture data of the main board 1 in the target temperature measuring area.

In the measured temperature area of the distribution box, the plurality of temperature measuring sensors 4 are fixedly arranged relative to the main board 1, and the purpose is to enable the plurality of temperature measuring sensors 4 to measure the temperatures of different preset temperature measuring points in the box body. In the case where the position of the main board 1 in the target temperature measurement area is defined in advance (for example, a member for placing the temperature measurement device in a fixed orientation is preset in the distribution box, and the member may be a partition in the distribution box), the posture detection element 5 only needs to detect and obtain posture data (for example, a yaw angle and the like) of the main board 1 in the target temperature measurement area.

In this embodiment, the number of the data transceiver components 3 is plural, the plural data transceiver components are fixedly disposed with respect to the motherboard 1, and the transmitting of the first target position data and the temperature data corresponding to the first target position data by the data transceiver components 3 may be: based on the plurality of data transceiver elements transmitting the first target position data and the temperature data corresponding to the first target position data, the process can be specifically implemented in two ways:

the first method is as follows: the target data transceiver component is determined from the plurality of data transceiver components 3 based on the data transceiver performance of the plurality of data transceiver components 3 in the target temperature measurement area, and the data transceiver selector 6 is instructed to control the target data transceiver component to transmit the first target position data and the corresponding temperature data, that is, the temperature measurement device is further provided with the data transceiver selector 6, and the data transceiver selector 6 is electrically connected with the processor 2 and the plurality of data transceiver components 3. In this embodiment, the plurality of data transceiver components 3 are fixedly disposed with respect to the motherboard, and in this manner, the processor 2 is further configured to: acquiring position relation data of the plurality of data transceiver elements 3 relative to the main board 1, and acquiring second target position data of the plurality of data transceiver elements 3 in a target temperature measuring area according to the pose data of the main board 1 in the target temperature measuring area and the position relation data of the plurality of data transceiver elements 3 relative to the main board 1; correspondingly, the above-mentioned determining the target data transceiver element from the plurality of data transceiver elements 3 based on the data transceiver performance of the plurality of data transceiver elements 3 in the target temperature measurement area may be: target transceiving position data satisfying a predetermined data transceiving performance among the second target position data is obtained, and a target data transceiving element corresponding to the target transceiving position data is determined from the plurality of data transceiving elements 3. The positional relationship data of the data transceiver components 3 with respect to the motherboard 1 may be orientation data and distance data of each data transceiver component of the data transceiver components 3 with respect to a geometric center point or other predetermined reference point of the motherboard 1.

In this embodiment, the obtaining of the target transceiving position data satisfying the predetermined data transceiving performance in the second target position data may be implemented as follows: firstly, obtaining alternative transceiving position data (a position with better wireless transmission performance) meeting the predetermined data transceiving performance in a target temperature measuring region based on offline experimental data or historical prior data, wherein the offline experimental data is data obtained after data transceiving performance test is carried out on a data transceiving element 3 preset at different positions in the target temperature measuring region, and the historical prior data is statistical data of interference degrees corresponding to data transceiving processes at different positions in the target temperature measuring region, for example, the interference degrees of an upper vacant region or other non-shielded regions of a distribution box in the data transceiving processes are statistically obtained to be lower; and secondly, determining position data matched with the alternative transceiving position data in the second target position data as target transceiving position data.

The above-mentioned determination of the target data transceiver element from the plurality of data transceiver elements 3 based on the data transmission/reception performance of the plurality of data transceiver elements 3 in the target temperature measurement area may be: the data transceiver selector 6 is instructed to perform a data transceiver polling operation for the plurality of data transceiver elements 3, obtain data transceiver results of the plurality of data transceiver elements 3 in the target temperature measurement area, and determine the target data transceiver element based on the data transceiver results.

The second method comprises the following steps: the first target position data and the temperature data corresponding thereto are transmitted based on a data transmitting/receiving array composed of a plurality of data transmitting/receiving elements 3. For example, the first target position data and the temperature data corresponding to the first target position data are transmitted by using an antenna array, and this process may be implemented based on the existing method of transmitting data by using an antenna array, which is not described herein again.

The temperature measuring device can be fixed (embedded, hung or adhered) in advance at a fixed position of the transportation box body, in a takeaway distribution scene, a partition plate capable of flexibly adjusting the position is usually arranged in the box body of the distribution box body, the partition plate is positioned at the center or the middle part of the box body, the temperature measuring device is configured on the partition plate and can be used for measuring the environmental temperature (a temperature field formed inside the box body) in the distribution box body, however, even if the temperature measuring device is fixedly arranged on the partition plate, the partition plate can be turned upside down when being placed into the distribution box body, so that the actual position of a temperature measuring sensor on the temperature measuring device in the box body is not matched with the position of a preset temperature measuring point, the temperature measuring sensor cannot measure the temperature of the preset temperature measuring point in the box body, the usability of temperature monitoring results is reduced, and the data comparison based on the distribution quality among a plurality of distribution, for example, the plurality of distribution boxes are provided with preset temperature measurement points at the same position, each preset temperature measurement point is provided with a temperature measurement sensor, and the distribution quality of the plurality of distribution boxes can be determined by comparing the temperature data of the preset temperature measurement points of the plurality of distribution boxes. In this embodiment, in order to effectively monitor the distribution quality of the plurality of distribution boxes and make the temperature measured by the temperature measuring sensors on the temperature measuring device be the temperature of the preset temperature measuring points in the box body, at least two of the plurality of temperature measuring sensors 4 are symmetrically arranged with a predetermined position as a symmetric center, the predetermined position may be a geometric center point of the motherboard 1 or a middle point of a connection line of at least two target temperature measuring points in a target temperature measuring area, and the at least two temperature measuring sensors are arranged in advance corresponding to the at least two target temperature measuring points. Through the symmetrical arrangement, the temperature measurement result of a preset temperature measurement point in a target temperature measurement area can be prevented from being influenced when the temperature measurement device is placed upside down, for example, the temperature measurement device is detachably arranged on a partition plate in the distribution box, when the distribution main body places the temperature measurement device upside down, the temperature measurement sensor symmetrically arranged can prevent the temperature at the preset temperature measurement point from being incapable of being measured due to deflection of the position of the temperature measurement sensor 4 correspondingly arranged at the preset temperature measurement point, so that the temperature at the preset temperature measurement point in the distribution box can be accurately measured under the condition that the temperature measurement device is placed upside down, the usability of the temperature monitoring result can be ensured, and the data comparison based on the distribution quality among a plurality of distribution boxes can be realized.

Above-mentioned a plurality of temperature sensor 4 for 1 fixed settings of mainboard, can indicate that a plurality of temperature sensor 4 are fixed to be set up on the mainboard or outside the mainboard, perhaps some temperature sensor are fixed to be set up on the mainboard, some temperature sensor are fixed to be set up outside the mainboard, in this embodiment, temperature measuring device still includes casing (not shown in the figure), above-mentioned a plurality of temperature sensor are fixed to be set up specifically can indicate outside the mainboard: the temperature sensors extend to the shell outside the main board through the leads and are fixedly arranged with the shell. In this embodiment, the data transceiver component 3 may also be disposed on the motherboard or disposed outside the motherboard through a lead.

By using the temperature measuring device provided by this embodiment, temperature data of different positions (which may be positions where preset temperature measuring points are located) in a target temperature measuring region can be accurately measured based on a single temperature measuring device, and the temperature data can be used as environmental temperature data corresponding to the target temperature measuring region (temperature field data of the target temperature measuring region), or further interpolation calculation is performed based on the temperature data (for example, interpolation calculation is performed based on a predetermined linear relationship, which may be a linear relationship between a position in the target temperature measuring region and a temperature), so as to obtain temperature field data corresponding to the target temperature measuring region; target data transceiving elements are selected from the plurality of data transceiving elements 3 based on data transmission performance to transmit data, and further target data transceiving elements with better data transmission performance are selected in real time according to pose data of the main board 1 corresponding to a target temperature measurement area, so that the data transmission process is free from interference of the temperature measurement area, and the data transmission efficiency and accuracy are improved.

A second embodiment of the present application additionally provides a temperature measuring device, comprising: the temperature measuring device comprises a main board 1, a processor 2 arranged on the main board, a temperature measuring sensor 4 electrically connected with the processor 2, a plurality of data transceiving elements 3 correspondingly arranged at different positions of a target temperature measuring area, and a data transceiving selector 6 electrically connected with the processor 2 and the plurality of data transceiving elements 3; the data transceiver component 3 may be an antenna for transmitting or receiving wireless signals, and may be disposed on the motherboard 1 or disposed outside the motherboard 1 through a lead. The processor 2 is configured to determine a target data transceiver element from the plurality of data transceiver elements 3 based on data transceiving performance of the plurality of data transceiver elements 3 in a target temperature measurement area, and transmit temperature data measured by the temperature measurement sensor 4 through the target data transceiver element after receiving the temperature data. In a cold chain or hot chain distribution scene, the temperature measuring device can be applied to a distribution box, and the target temperature measuring area can be a preset measured temperature area in the distribution box

In this embodiment, the temperature measuring apparatus further includes a pose detection element 5 disposed corresponding to the motherboard 1 and electrically connected to the processor 2, where the pose detection element 5 may be an inertial measurement unit, and is configured to obtain pose data of the motherboard 1 in the target temperature measurement area and transmit the pose data to the processor 2; the plurality of data transceiver components 3 are fixedly disposed with respect to the motherboard 1, and the determining a target data transceiver component from the plurality of data transceiver components 3 based on the data transceiving performance of the plurality of data transceiver components 3 in the target temperature measurement area may specifically be: obtaining positional relationship data of a plurality of data transmitting and receiving elements 3 with respect to the main board 1; obtaining target position data of the data transceiver elements 3 in the target temperature measuring area according to the pose data of the mainboard 1 in the target temperature measuring area and the position relation data of the data transceiver elements 3 relative to the mainboard 1; target transmitting/receiving position data satisfying a predetermined data transmitting/receiving performance among the target position data is obtained, and a target data transmitting/receiving element corresponding to the target transmitting/receiving position data is determined from the plurality of data transmitting/receiving elements 3.

In this embodiment, the obtaining of the target transceiving position data meeting the predetermined data transceiving performance in the target position data may specifically refer to: obtaining alternative transceiving position data meeting the predetermined data transceiving performance in the target temperature measuring area based on offline experimental data or historical prior data, wherein the offline experimental data are data obtained after data transceiving performance tests are carried out on data transceiving elements 3 preset at different positions in the target temperature measuring area, and the historical prior data are statistical data of interference degrees corresponding to data transceiving processes at different positions in the target temperature measuring area; and determining the position data matched with the alternative transceiving position data in the target position data as the target transceiving position data.

In this embodiment, the temperature measuring device further includes a data transceiver selector 6 electrically connected to the processor 2 and the plurality of data transceiver elements 4, where the processor transmits temperature data through the target data transceiver element, which may specifically be: the instruction data transceiving selector 6 controls the target data transceiving element to transmit the temperature data. The above-mentioned determining the target data transceiver element from the plurality of data transceiver elements 3 based on the data transceiver performance of the plurality of data transceiver elements 3 in the target temperature measurement area may further include: the data transceiver selector 6 is instructed to perform a data transceiver polling operation for the plurality of data transceiver elements 3, obtain data transceiver results of the plurality of data transceiver elements 3 in the target temperature measurement area, and determine the target data transceiver element based on the data transceiver results.

By using the temperature measuring device provided by the embodiment, the target data transceiving elements can be selected from the plurality of data transceiving elements for data transmission based on the data transmission performance, and the target data transceiving elements with better data transmission performance are further selected in real time according to the pose data of the mainboard corresponding to the target temperature measurement area, so that the data transmission process is free from the interference of the temperature measurement area, and the data transmission efficiency and accuracy are improved.

A third embodiment of the present application provides a method for processing temperature data, an application subject of the method may be the processor in the first embodiment, and reference may be made to the first embodiment for details regarding implementation of the present embodiment. Fig. 3 is a flowchart of a temperature data processing method according to a third embodiment of the present application, and the method according to this embodiment is described below with reference to fig. 3. The following description refers to embodiments for the purpose of illustrating the principles of the methods, and is not intended to be limiting in actual use.

As shown in fig. 3, the temperature data processing method provided in this embodiment includes the following steps:

s101, obtaining pose data of the target carrier in a target temperature measuring area, wherein a plurality of temperature measuring sensors are fixedly arranged in the target temperature measuring area corresponding to the target carrier. The target carrier may be a main board of the temperature measuring device, the target temperature measuring area may be a preset temperature measured area in the distribution box, and the pose data may be position data and posture data of the main board in the temperature measured area.

S102, acquiring position relation data of the plurality of temperature measurement sensors relative to the target carrier, wherein the position relation data can be position data and distance data of each temperature measurement sensor in the plurality of temperature measurement sensors relative to a geometric center point or other preset reference points of the target carrier, and the position relation data can be preset data.

And S103, acquiring target position data of the plurality of temperature measuring sensors in the target temperature measuring area according to the pose data and the position relation data.

And S104, receiving the temperature data from the plurality of temperature measuring sensors, and sending the temperature data and the corresponding target position data.

By using the temperature data processing method provided by this embodiment, the temperature data of different positions (which may be positions where preset temperature measuring points are located) in the target temperature measuring region can be accurately measured based on a single temperature measuring device, and the temperature data can be used as the environment temperature data corresponding to the target temperature measuring region (temperature field data of the target temperature measuring region), or further, interpolation calculation is performed based on the temperature data (for example, interpolation calculation is performed based on a predetermined linear relationship, which may be a linear relationship between the position and the temperature in the target temperature measuring region), so as to obtain the temperature field data corresponding to the target temperature measuring region.

A fourth embodiment of the present application provides a data transmission method, an implementation subject of the method may be applied to a computing device, fig. four is a flowchart of the data transmission method provided in the fourth embodiment of the present application, and the method provided in this embodiment is described in detail below with reference to fig. 4. The following description refers to embodiments for the purpose of illustrating the principles of the methods, and is not intended to be limiting in actual use.

As shown in fig. 4, the data transmission method provided in this embodiment includes the following steps:

s201, obtaining pose data of the target carrier in a target area, wherein a plurality of data transceiving elements are fixedly arranged in the target area corresponding to the target carrier.

S202, obtaining the position relation data of the plurality of data transceiving elements relative to the target carrier.

And S203, acquiring target position data of the plurality of data transceiver elements in the target area according to the pose data and the position relation data.

And S204, obtaining target transceiving position data meeting the predetermined data transceiving performance in the target position data.

S205, a data transceiver element corresponding to the target transceiver position data among the plurality of data transceiver elements is determined as a target data transceiver element for receiving and transmitting data in the target area.

The obtaining of the target transceiving position data meeting the predetermined data transceiving performance in the target position data may specifically be: acquiring alternative transceiving position data meeting the predetermined data transceiving performance in a target area based on offline experimental data or historical prior data, wherein the offline experimental data are data acquired after data transceiving performance tests are performed on data transceiving elements preset at different positions in the target area, and the historical prior data are statistical data of interference degrees corresponding to data transceiving processes at different positions in the target area; and determining the position data matched with the alternative transceiving position data in the target position data as the target transceiving position data.

The data transmission method provided by the embodiment selects the target data transceiver element from the plurality of data transceiver elements for data transmission based on the data transmission performance, and further selects the target data transceiver element with better data transmission performance in real time according to the pose data of the target carrier corresponding to the target temperature measurement area, so that the data transmission process is free from interference of the temperature measurement area, and the data transmission efficiency and accuracy are improved.

The fifth embodiment of the present application also provides a temperature data processing apparatus, since the apparatus embodiment is substantially similar to the method embodiment, so that the description is simple, and the details of the related technical features can be found in the corresponding description of the method embodiment provided above, and the following description of the apparatus embodiment is only illustrative.

Referring to fig. 5, to understand the embodiment, fig. 5 is a block diagram of a unit of the temperature data processing apparatus provided in the embodiment, and as shown in fig. 5, the apparatus provided in the embodiment includes:

a pose data obtaining unit 501, configured to obtain pose data of a target carrier in a target temperature measurement area, where a plurality of temperature measurement sensors are fixedly disposed in the target temperature measurement area and correspond to the target carrier;

a position relation data obtaining unit 502, configured to obtain position relation data of the multiple temperature measurement sensors relative to the target carrier;

a target position data obtaining unit 503, configured to obtain target position data of the multiple temperature measurement sensors in the target temperature measurement area according to the pose data and the position relationship data;

the data sending unit 504 is configured to receive temperature data from the plurality of temperature measurement sensors and send the temperature data and target position data corresponding to the temperature data.

By using the temperature data processing device provided by the embodiment of the present application, temperature data of different positions (which may be positions where preset temperature measurement points are located) in a target temperature measurement region can be accurately obtained, and the temperature data can be used as environmental temperature data corresponding to the target temperature measurement region (temperature field data of the target temperature measurement region), or interpolation calculation is further performed based on the temperature data (for example, interpolation calculation is performed based on a predetermined linear relationship, which may be a linear relationship between a position in the target temperature measurement region and a temperature), so as to obtain temperature field data corresponding to the target temperature measurement region.

In the embodiments described above, a temperature data processing method and a temperature data processing apparatus are provided, and in addition, a sixth embodiment of the present application also provides an electronic device, which is basically similar to the method embodiment and therefore is described relatively simply, and the details of the related technical features may be obtained by referring to the corresponding description of the method embodiment provided above, and the following description of the electronic device embodiment is only illustrative. The embodiment of the electronic equipment is as follows:

please refer to fig. 6 for understanding the present embodiment, fig. 6 is a schematic view of an electronic device provided in the present embodiment.

As shown in fig. 6, the electronic device provided in this embodiment includes: a processor 601 and a memory 602; the memory 602 is used for storing computer instructions for data processing, which when read and executed by the processor 601, perform the following operations: acquiring pose data of a target carrier in a target temperature measuring area, wherein a plurality of temperature measuring sensors are fixedly arranged in the target temperature measuring area corresponding to the target carrier; obtaining position relation data of the plurality of temperature measuring sensors relative to the target carrier; obtaining target position data of the temperature measuring sensors in the target temperature measuring area according to the pose data and the position relation data; and receiving temperature data from the plurality of temperature measuring sensors, and sending the temperature data and the target position data corresponding to the temperature data.

By using the electronic device provided by this embodiment, temperature data of different positions (which may be positions where preset temperature measurement points are located) in the target temperature measurement region can be accurately obtained, and the temperature data can be used as environmental temperature data corresponding to the target temperature measurement region (temperature field data of the target temperature measurement region), or further, interpolation calculation is performed based on the temperature data (for example, interpolation calculation is performed based on a predetermined linear relationship, which may be a linear relationship between a position in the target temperature measurement region and a temperature), so as to obtain temperature field data corresponding to the target temperature measurement region.

In the above embodiments, a temperature data processing method, a temperature data processing apparatus, and an electronic device are provided, and furthermore, a seventh embodiment of the present application also provides a computer-readable storage medium for implementing the temperature data processing method. The embodiments of the computer-readable storage medium provided in the present application are described relatively simply, and for relevant portions, reference may be made to the corresponding descriptions of the above method embodiments, and the embodiments described below are merely illustrative.

The present embodiments provide a computer readable storage medium having stored thereon computer instructions that, when executed by a processor, perform the steps of:

acquiring pose data of a target carrier in a target temperature measuring area, wherein a plurality of temperature measuring sensors are fixedly arranged in the target temperature measuring area corresponding to the target carrier;

obtaining position relation data of the plurality of temperature measuring sensors relative to the target carrier;

obtaining target position data of the temperature measuring sensors in the target temperature measuring area according to the pose data and the position relation data;

and receiving temperature data from the plurality of temperature measuring sensors, and sending the temperature data and the target position data corresponding to the temperature data.

By executing the computer instructions stored on the computer-readable storage medium provided in this embodiment, temperature data of different positions in the target temperature measurement region (which may be positions where preset temperature measurement points are located) can be accurately obtained, and the temperature data can be used as environmental temperature data corresponding to the target temperature measurement region (temperature field data of the target temperature measurement region), or interpolation calculation is further performed based on the temperature data (for example, interpolation calculation is performed based on a predetermined linear relationship, which may be a linear relationship between a position in the target temperature measurement region and a temperature), so as to obtain temperature field data corresponding to the target temperature measurement region.

The above fourth embodiment provides a data transmission method, and correspondingly, the eighth embodiment of the present application also provides a data transmission apparatus, since the apparatus embodiment is basically similar to the method embodiment, so that the description is relatively simple, and the details of the related technical features need to be referred to the corresponding description of the method embodiment provided above, and the following description of the apparatus embodiment is only illustrative.

Referring to fig. 7 to understand the embodiment, fig. 7 is a block diagram of a unit of the data transmitting apparatus provided in the embodiment, and as shown in fig. 7, the data transmitting apparatus provided in the embodiment includes:

a pose data obtaining unit 701 configured to obtain pose data of the target carrier in a target area, in which a plurality of data transceiver elements are fixedly disposed corresponding to the target carrier;

a positional relationship data obtaining unit 702 for obtaining positional relationship data of the plurality of data-transceiving elements with respect to the target carrier;

a target position data obtaining unit 703 configured to obtain target position data of the plurality of data transceiver elements in the target area according to the pose data and the position relationship data;

a target transceiving position data obtaining unit 704 configured to obtain target transceiving position data satisfying a predetermined data transceiving performance among the target position data;

a target data transceiver component determining unit 705, configured to determine a data transceiver component corresponding to the target transceiver position data among the plurality of data transceiver components as a target data transceiver component for receiving and transmitting data in the target area.

The above-mentioned target transceiving position data satisfying the predetermined data transceiving performance in the obtained target position data includes: acquiring alternative transceiving position data meeting the predetermined data transceiving performance in a target area based on offline experimental data or historical prior data, wherein the offline experimental data are data acquired after data transceiving performance tests are performed on data transceiving elements preset at different positions in the target area, and the historical prior data are statistical data of interference degrees corresponding to data transceiving processes at different positions in the target area; and determining the position data matched with the alternative transceiving position data in the target position data as the target transceiving position data.

By using the data sending device provided by the embodiment, the target data transceiving elements can be selected from the plurality of data transceiving elements for data sending based on the data transmission performance, and the target data transceiving elements with better data sending performance can be further selected in real time according to the pose data of the target carrier corresponding to the target temperature measurement area, so that the data sending process can be prevented from being interfered by the temperature measurement area, and the data sending efficiency and accuracy are improved.

In the above embodiments, a data transmission method and a data transmission apparatus are provided, and in addition, a ninth embodiment of the present application further provides an electronic device, which is basically similar to the method embodiment, so that description is relatively simple, and for details of relevant technical features, reference may be made to corresponding descriptions of the method embodiment provided above, and the following description of the electronic device embodiment is only illustrative. The embodiment of the electronic equipment is as follows: please refer to fig. 8 for understanding the present embodiment, fig. 8 is a schematic view of an electronic device provided in the present embodiment. As shown in fig. 8, the electronic device provided in this embodiment includes: a processor 801 and a memory 802; the memory 802 is used for storing computer instructions for target image acquisition, which when read and executed by the processor 801, perform the following operations:

acquiring pose data of a target carrier in a target area, wherein a plurality of data transceiving elements are fixedly arranged in the target area corresponding to the target carrier;

obtaining positional relationship data of the plurality of data-transceiving elements with respect to the target carrier;

obtaining target position data of the plurality of data transceiver elements in the target area according to the pose data and the position relation data;

obtaining target transceiving position data meeting the predetermined data transceiving performance in the target position data;

and determining a data transceiving element corresponding to the target transceiving position data among the plurality of data transceiving elements as a target data transceiving element for receiving and transmitting data in the target area.

The obtaining of the target transceiving position data meeting the predetermined data transceiving performance in the target position data includes: obtaining alternative transceiving position data which meet the predetermined data transceiving performance in the target area based on offline experimental data or historical prior data, wherein the offline experimental data are data obtained after data transceiving performance tests are carried out on data transceiving elements preset at different positions in the target area, and the historical prior data are statistical data of interference degrees corresponding to data transceiving processes at different positions in the target area; and determining the position data matched with the alternative transceiving position data in the target position data as the target transceiving position data.

By using the electronic device provided by the embodiment, the target data transceiver element can be selected from the plurality of data transceiver elements for data transmission based on the data transmission performance, and the target data transceiver element with better data transmission performance is further selected in real time according to the pose data of the target carrier corresponding to the target temperature measurement area, so that the data transmission process is free from the interference of the temperature measurement area, and the data transmission efficiency and accuracy are improved.

In the above embodiments, a data transmission method, a data transmission apparatus and an electronic device are provided, and in addition, a tenth embodiment of the present application also provides a computer-readable storage medium for implementing the data transmission method. The embodiments of the computer-readable storage medium provided in the present application are described relatively simply, and for relevant portions, reference may be made to the corresponding descriptions of the above method embodiments, and the embodiments described below are merely illustrative.

The present embodiments provide a computer readable storage medium having stored thereon computer instructions that, when executed by a processor, perform the steps of:

acquiring pose data of a target carrier in a target area, wherein a plurality of data transceiving elements are fixedly arranged in the target area corresponding to the target carrier;

obtaining positional relationship data of the plurality of data-transceiving elements with respect to the target carrier;

obtaining target position data of the plurality of data transceiver elements in the target area according to the pose data and the position relation data;

obtaining target transceiving position data meeting the predetermined data transceiving performance in the target position data;

and determining a data transceiving element corresponding to the target transceiving position data among the plurality of data transceiving elements as a target data transceiving element for receiving and transmitting data in the target area.

The obtaining of the target transceiving position data meeting the predetermined data transceiving performance in the target position data includes: obtaining alternative transceiving position data which meet the predetermined data transceiving performance in the target area based on offline experimental data or historical prior data, wherein the offline experimental data are data obtained after data transceiving performance tests are carried out on data transceiving elements preset at different positions in the target area, and the historical prior data are statistical data of interference degrees corresponding to data transceiving processes at different positions in the target area; and determining the position data matched with the alternative transceiving position data in the target position data as the target transceiving position data.

By executing the computer instructions stored in the computer-readable storage medium provided by this embodiment, the target data transceiver element can be selected from the multiple data transceiver elements for data transmission based on the data transmission performance, and further, the target data transceiver element with better data transmission performance is selected in real time according to the pose data of the target carrier corresponding to the target temperature measurement area, so that the data transmission process is not interfered by the temperature measurement area, and the data transmission efficiency and accuracy are improved.

In a typical configuration, a computing device includes one or more processors (CPUs), input/output interfaces, network interfaces, and memory.

The memory may include forms of volatile memory in a computer readable medium, Random Access Memory (RAM) and/or non-volatile memory, such as Read Only Memory (ROM) or flash memory (flash RAM). Memory is an example of a computer-readable medium.

1. Computer-readable media, including both non-transitory and non-transitory, removable and non-removable media, may implement information storage by any method or technology. The information may be computer readable instructions, data structures, modules of a program, or other data. Examples of computer storage media include, but are not limited to, phase change memory (PRAM), Static Random Access Memory (SRAM), Dynamic Random Access Memory (DRAM), other types of Random Access Memory (RAM), Read Only Memory (ROM), Electrically Erasable Programmable Read Only Memory (EEPROM), flash memory or other memory technology, compact disc read only memory (CD-ROM), Digital Versatile Discs (DVD) or other optical storage, magnetic cassettes, magnetic tape magnetic disk storage or other magnetic storage devices, or any other non-transmission medium that can be used to store information that can be accessed by a computing device. As defined herein, computer readable media does not include non-transitory computer readable media (transient media), such as modulated data signals and carrier waves.

2. As will be appreciated by one skilled in the art, embodiments of the present application may be provided as a method, system, or computer program product. Accordingly, the present application may take the form of an entirely hardware embodiment, an entirely software embodiment or an embodiment combining software and hardware aspects. Furthermore, the present application may take the form of a computer program product embodied on one or more computer-usable storage media (including, but not limited to, disk storage, CD-ROM, optical storage, and the like) having computer-usable program code embodied therein.

Although the present application has been described with reference to the preferred embodiments, it is not intended to limit the present application, and those skilled in the art can make variations and modifications without departing from the spirit and scope of the present application, therefore, the scope of the present application should be determined by the claims that follow.

Claims (10)

1. A temperature measuring device, comprising: the temperature measuring device comprises a processor and a plurality of temperature measuring sensors electrically connected with the processor; the processor is used for obtaining first target position data of the plurality of temperature measurement sensors in a target temperature measurement area and obtaining temperature data which are measured by the plurality of temperature measurement sensors and correspond to the first target position data.

2. The temperature measurement device of claim 1, further comprising: the pose detection element is arranged corresponding to the mainboard and electrically connected with the processor, and the temperature measurement sensors are fixedly arranged relative to the mainboard; the pose detection element is used for acquiring pose data of the mainboard in the target temperature measurement area and transmitting the pose data to the processor; the processor obtains first target position data of the plurality of thermometric sensors in a target thermometric area, comprising: and acquiring position relation data of the plurality of temperature measurement sensors relative to the mainboard, and acquiring first target position data of the plurality of temperature measurement sensors in the target temperature measurement area according to the pose data of the mainboard in the target temperature measurement area and the position relation data of the plurality of temperature measurement sensors relative to the mainboard.

3. The temperature measurement device of claim 1, further comprising: a data transceiver component, the processor further configured to transmit the first target location data and temperature data corresponding to the first target location data via the data transceiver component.

4. A temperature measuring device, comprising: the temperature measurement device comprises a processor, a temperature measurement sensor electrically connected with the processor, and a plurality of data receiving and transmitting elements correspondingly arranged at different positions of a target temperature measurement area; the processor is used for determining a target data transceiver element from the plurality of data transceiver elements based on the data transceiver performance of the plurality of data transceiver elements in the target temperature measuring area, and transmitting the temperature data through the target data transceiver element after receiving the temperature data measured by the temperature measuring sensor.

5. A method of processing temperature data, comprising:

acquiring pose data of a target carrier in a target temperature measuring area, wherein a plurality of temperature measuring sensors are fixedly arranged in the target temperature measuring area corresponding to the target carrier;

obtaining position relation data of the plurality of temperature measuring sensors relative to the target carrier;

obtaining target position data of the temperature measuring sensors in the target temperature measuring area according to the pose data and the position relation data;

and receiving temperature data from the plurality of temperature measuring sensors, and sending the temperature data and the target position data corresponding to the temperature data.

6. A data transmission method, comprising:

acquiring pose data of a target carrier in a target area, wherein a plurality of data transceiving elements are fixedly arranged in the target area corresponding to the target carrier;

obtaining positional relationship data of the plurality of data-transceiving elements with respect to the target carrier;

obtaining target position data of the plurality of data transceiver elements in the target area according to the pose data and the position relation data;

obtaining target transceiving position data meeting the predetermined data transceiving performance in the target position data;

and determining a data transceiving element corresponding to the target transceiving position data among the plurality of data transceiving elements as a target data transceiving element for receiving and transmitting data in the target area.

7. A temperature data processing apparatus, characterized by comprising:

the system comprises a pose data acquisition unit, a pose data acquisition unit and a pose data acquisition unit, wherein the pose data acquisition unit is used for acquiring pose data of a target carrier in a target temperature measurement area, and a plurality of temperature measurement sensors are fixedly arranged in the target temperature measurement area corresponding to the target carrier;

the position relation data acquisition unit is used for acquiring the position relation data of the plurality of temperature measurement sensors relative to the target carrier;

the target position data obtaining unit is used for obtaining target position data of the temperature measuring sensors in the target temperature measuring area according to the pose data and the position relation data;

and the data sending unit is used for receiving the temperature data from the plurality of temperature measuring sensors and sending the temperature data and the corresponding target position data.

8. A data transmission apparatus, comprising:

a pose data obtaining unit for obtaining pose data of a target carrier in a target area, the target area being fixedly provided with a plurality of data transceiving elements corresponding to the target carrier;

a positional relationship data obtaining unit for obtaining positional relationship data of the plurality of data-transceiving elements with respect to the object carrier;

a target position data obtaining unit configured to obtain target position data of the plurality of data transceiver elements in the target area according to the pose data and the position relationship data;

a target transceiving position data obtaining unit configured to obtain target transceiving position data that satisfies predetermined data transceiving performance among the target position data;

a target data transceiving element determining unit configured to determine a data transceiving element corresponding to the target transceiving position data among the plurality of data transceiving elements as a target data transceiving element for receiving and transmitting data in the target area.

9. An electronic device comprising a processor and a memory; wherein the content of the first and second substances,

the memory is to store one or more computer instructions, wherein the one or more computer instructions are to be executed by the processor to implement the method of claims 5-6.

10. A computer-readable storage medium having stored thereon one or more computer instructions for execution by a processor to perform the method of claims 5-6.

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