WO2016074488A1 - Temperature processing method and device, and temperature display method and device for data center - Google Patents

Abstract

A temperature processing method and device, and a temperature display method and device for a data center. The temperature processing method for a data center comprises: acquiring, in real time, temperature data collected by multiple temperature sensors, the multiple temperature sensors being disposed in the data center (S102); and generating a temperature chart of the data center according to the temperature data collected by the multiple temperature sensors and the positions of the multiple temperature sensors (S104). The problem that internal temperature distribution of a micromodule data center cannot be intuitively displayed in the prior art is solved, and accordingly, internal temperature distribution and abnormal information of the micromodule are intuitively displayed in the form of a temperature cloud chart, so it is more convenient to locate an anomaly and conduct maintenance.

Description

Data center temperature processing method, device and temperature display method and device Technical field

The present invention relates to the field of communications, and in particular, to a temperature processing method and apparatus for a data center, and a temperature display method and apparatus.

Background technique

With the development of data center technology, the construction of large data center equipment rooms and the deployment of a large number of IT equipment, the monitoring and management of real-time data in the data center equipment room has received more and more attention, especially after the deployment of a large number of IT equipment. The high heat dissipation of IT equipment such as servers and blades causes the local or overall temperature of the data center to be too high. Too high a temperature will affect the performance of IT devices such as servers and blades, which will further affect the normal operation of related deployment services. Monitoring of temperature data is critical in the management and operation of data centers. In order to monitor the data center equipment environment parameters, a large number of temperature sensors are deployed inside each micro-module data center to monitor environmental data. O&M personnel need to view and abnormally locate a large number of temperature sensor data. If the temperature sensor position and temperature value of the entire data center room cannot be displayed visually, the workload of the operation and maintenance personnel will be greatly increased.

For the related technology, the problem of the internal temperature distribution of the micro-module data center cannot be visually displayed, and an effective solution has not been proposed.

Summary of the invention

The embodiment of the invention provides a temperature processing method and device for a data center, and a temperature display method and device, so as to at least solve the problem that the internal temperature distribution of the micro-module data center cannot be intuitively displayed in the related art.

According to an aspect of the embodiments of the present invention, a temperature processing method for a data center is provided, including: acquiring temperature data collected by a plurality of temperature sensors, wherein the plurality of temperature sensors are disposed in a data center; The temperature data collected by the temperature sensors and the locations of the plurality of temperature sensors generate a temperature map of the data center.

Further, generating a temperature map of the data center according to temperature data collected by the plurality of temperature sensors and positions of the plurality of temperature sensors includes: for each region, a temperature collected according to a plurality of temperature sensors in the region The data and the locations of the plurality of temperature sensors generate a matrix corresponding to the region, wherein the data center is divided into a plurality of regions; and a temperature map of the data center is generated according to a matrix corresponding to each of the regions.

Further, generating a temperature map of the data center according to the matrix corresponding to each region includes: performing bilinear interpolation on the number of reservations for the matrix corresponding to each region; and generating the matrix according to the bilinear interpolation The temperature map of the data center.

Further, generating a temperature map of the data center according to the matrix corresponding to each of the regions includes: generating a temperature map corresponding to the region according to the matrix corresponding to each region; generating a temperature map according to each region The temperature map of the data center.

Further, after generating the temperature map of the data center according to the temperature data collected by the plurality of temperature sensors and the locations of the plurality of temperature sensors, the method further includes: generating the data center according to the type of the data center a three-dimensional model; combining the temperature map of the data center with the stereo model and displaying.

Further, combining the temperature map of the data center with the stereo model and displaying comprises: using different colors in the temperature map of the data center to correspond to different temperature value ranges.

Further, combining the temperature map of the data center with the stereo model and displaying further includes displaying an alert indication when a temperature value of one or more regions of the data center exceeds a predetermined temperature value range.

According to another aspect of the embodiments of the present invention, a temperature display method is further provided, comprising: acquiring temperature data; displaying a temperature map according to the acquired temperature data, wherein the temperature map comprises: displaying each area according to the area The temperature plot, the temperature plot for each of the zones shows one or more temperature values in the zone.

Further, displaying the temperature map includes displaying the temperature map in a three-dimensional model, wherein the three-dimensional model is generated according to an entity of the temperature data source.

Further, displaying the temperature map includes: using different colors in the temperature map corresponding to different temperature value ranges.

Further, displaying the temperature map in the stereo model includes displaying an alarm indication when a temperature value displayed by the temperature map exceeds a predetermined temperature value range.

According to another aspect of the embodiments of the present invention, a temperature processing apparatus for a data center is provided, including: an obtaining module configured to acquire temperature data collected by a plurality of temperature sensors in real time, wherein the plurality of temperature sensors are disposed at a first generation module configured to generate a temperature map of the data center according to temperature data collected by the plurality of temperature sensors and locations of the plurality of temperature sensors.

Further, the first generation module includes: a first generation unit configured to generate, for each region, the temperature data collected by the plurality of temperature sensors in the region and the locations of the plurality of temperature sensors to generate the region a corresponding matrix, wherein the data center is divided into a plurality of regions; and the second generating unit is configured to generate a temperature map of the data center according to the matrix corresponding to each of the regions.

Further, the second generating unit includes: an interpolating subunit, configured to perform bilinear interpolation of the number of reservations for the matrix corresponding to each region; and the first generating subunit is set to perform bilinear interpolation according to The resulting matrix generates a temperature map of the data center.

Further, the second generating unit further includes: a second generating sub-unit, configured to generate a temperature map corresponding to the region according to the matrix corresponding to each region; and a third generating sub-unit, configured to The temperature map corresponding to the region generates a temperature map of the data center.

Further, the device further includes: a second generating module, configured to generate a stereo model of the data center according to a type of the data center; and a display module configured to set a temperature map of the data center and the stereo The models are combined and displayed.

Further, the display module is further configured to use different colors in the temperature map of the data center to correspond to different temperature value ranges.

Further, the display module is further configured to display an alarm indication when a temperature value of one or more regions of the data center exceeds a predetermined temperature value range.

According to another aspect of the embodiments of the present invention, there is further provided a temperature display device comprising: an acquisition module configured to acquire temperature data; and a display module configured to display a temperature map according to the acquired temperature data, wherein the temperature The diagram includes a temperature map for each region displayed by region, the temperature graph for each of the regions showing one or more temperature values in the region.

Further, the display module is further configured to display the temperature map in a stereo model, wherein the stereo model is generated according to an entity of the temperature data source.

Further, the display module is further configured to use different colors in the temperature map to correspond to different temperature value ranges.

Further, the display module is further configured to display an alarm indication when the temperature value displayed by the temperature diagram exceeds a predetermined temperature value range.

According to the embodiment of the present invention, the temperature data collected by the plurality of temperature sensors is acquired in real time, wherein the plurality of temperature sensors are disposed in the data center; and the data center is generated according to the temperature data collected by the plurality of temperature sensors and the positions of the plurality of temperature sensors Temperature map. Resolving the micro-module data center that cannot be intuitively displayed in the prior art The problem of internal temperature distribution, and thus the temperature distribution and abnormal information of the micro-module is visually displayed in a temperature cloud diagram, which is more convenient for abnormal positioning and maintenance.

DRAWINGS

The drawings described herein are intended to provide a further understanding of the invention, and are intended to be a part of the invention. In the drawing:

1 is a flow chart of a temperature processing method of a data center according to an embodiment of the present invention;

2 is a block diagram showing the structure of a temperature processing device of a data center according to an embodiment of the present invention;

3 is a structural block diagram 1 of a temperature processing apparatus of a data center according to an embodiment of the present invention;

4 is a structural block diagram 2 of a temperature processing apparatus of a data center according to an embodiment of the present invention;

5 is a structural block diagram 3 of a temperature processing apparatus of a data center according to an embodiment of the present invention;

6 is a structural block diagram 4 of a temperature processing apparatus of a data center according to an embodiment of the present invention;

7 is a flow chart of a temperature display method according to an embodiment of the present invention;

8 is a structural block diagram 5 of a temperature processing apparatus of a data center according to an embodiment of the present invention;

9 is a flowchart of a micro-module data center temperature cloud map calculation method according to an embodiment of the present invention;

FIG. 10 is a schematic diagram showing functions and processing procedures of various modules of a micro-module data center temperature cloud map display system according to an embodiment of the present invention.

detailed description

The invention will be described in detail below with reference to the drawings in conjunction with the embodiments. It should be noted that the embodiments in the present application and the features in the embodiments may be combined with each other without conflict.

In this embodiment, a temperature processing method of a data center is provided. FIG. 1 is a flowchart of a temperature processing method of a data center according to an embodiment of the present invention. As shown in FIG. 1, the process includes the following steps:

Step S102, acquiring temperature data collected by a plurality of temperature sensors, wherein the plurality of temperature sensors are disposed in the data center;

Step S104, generating a temperature map of the data center according to the temperature data collected by the plurality of temperature sensors and the positions of the plurality of temperature sensors.

Through the above steps, the temperature data collected by multiple temperature sensors in each area of the data center is generated, and the temperature map of each area of the data center is generated. Compared with the related art, the operation and maintenance personnel need to view the temperature sensor data of the data center. And the abnormal positioning, the workload of the operation and maintenance personnel is heavy. The above steps solve the problem that the internal temperature distribution of the micro-module data center cannot be visually displayed in the prior art, and the internal temperature of the micro-module is visually displayed by means of the temperature cloud diagram. Distribution and exception information makes it easier to locate and maintain.

The above step S104 involves generating a temperature map of the data center according to the temperature data collected by the plurality of temperature sensors and the positions of the plurality of temperature sensors. It should be noted that the temperature data collected by the plurality of temperature sensors and the plurality of The location of the temperature sensor generates a temperature map of the data center, which is illustrated below. In an optional embodiment, the data center is divided into a plurality of regions, and for each region, a matrix corresponding to the region is generated according to temperature data collected by the plurality of temperature sensors in the region and positions of the plurality of temperature sensors, according to each The matrix corresponding to each region generates a temperature map of the data center.

In an implementation manner of generating a temperature map of a data center according to a matrix corresponding to each region, in an optional embodiment, bilinear interpolation of the number of reservations is performed for a matrix corresponding to each region, according to bilinear interpolation The matrix generates a temperature map of the data center, thereby realizing the temperature map of the data center generated according to the matrix corresponding to each region. This fills in the blank area of the temperature acquisition value between the temperature sensors.

In an optional embodiment, in the process of generating a temperature map of the data center according to the matrix corresponding to each region, the temperature map corresponding to the region is generated according to the matrix corresponding to each region, and then generated according to the temperature map corresponding to each region. The temperature map of the data center. Due to the temperature map of the data center, the temperature map corresponding to each area element included in the data center is specifically displayed. According to the alternative embodiment, the temperature map of the data center is generated according to the division of the area of the data center.

The ultimate goal of generating a temperature map of the data center is to display the temperature map. In an alternative embodiment, after generating the temperature map of the data center based on the temperature data collected by the plurality of temperature sensors and the locations of the plurality of temperature sensors, The type of data center, generating a three-dimensional model of the data center, combining and displaying the temperature map of the data center with the three-dimensional model. The temperature map of the data center can thus be displayed by a stereo model adapted to the type of data center. Among them, the data center can be divided into multiple types, such as container type, micro-modular, etc., data center cabinets have single row and multiple rows, open and closed, cooling, power distribution and other modes are different, the number of cabinets Different from the form of placement.

In order to visually display the temperature map of the data center's data center, in an alternative embodiment, different colors are used in the temperature map to correspond to different temperature value ranges. For example, blue represents the lowest temperature value and red represents the highest temperature value.

The ultimate purpose of detecting temperature data is to manage and operate the data center. In an alternative embodiment, an alert indication is displayed when the temperature value of one or more regions of the data center exceeds a predetermined temperature range. This prompts the operation and maintenance personnel to repair the data center to ensure the security operation of the data center.

A temperature processing device of the data center is also provided in the embodiment, and the device is configured to implement the above-described embodiments and preferred embodiments, and the detailed description thereof has been omitted. As used below, the term "module" may implement a combination of software and/or hardware of a predetermined function. Although the apparatus described in the following embodiments is preferably implemented in software, hardware, or a combination of software and hardware, is also possible and contemplated.

2 is a structural block diagram of a temperature processing apparatus of a data center according to an embodiment of the present invention. As shown in FIG. 2, the apparatus includes: an acquiring module 22 configured to acquire temperature data collected by a plurality of temperature sensors in real time, where multiple The temperature sensor is disposed in the data center; the first generation module 24 is configured to generate a temperature map of the data center according to the temperature data collected by the plurality of temperature sensors and the positions of the plurality of temperature sensors.

3 is a structural block diagram of a temperature processing apparatus of a data center according to an embodiment of the present invention. As shown in FIG. 3, the first generation module 24 includes: a first generation unit 242, configured for each area, according to the area The temperature data collected by the plurality of temperature sensors and the position of the plurality of temperature sensors generate a matrix corresponding to the region, wherein the data center is divided into a plurality of regions; and the second generating unit 244 is configured to generate a data center according to the matrix corresponding to each region Temperature map.

4 is a structural block diagram 2 of a temperature processing apparatus of a data center according to an embodiment of the present invention. As shown in FIG. 4, a second generating unit 244 includes: an interpolation sub-unit 2442 configured to reserve a matrix corresponding to each area. The bilinear interpolation of the number of times; the first generation subunit 2444 is set to generate a temperature map of the data center according to the matrix after the bilinear interpolation.

5 is a structural block diagram 3 of a temperature processing apparatus of a data center according to an embodiment of the present invention. As shown in FIG. 5, the second generating unit 244 further includes: a second generating sub-unit 2446, which is set according to a matrix corresponding to each area. The temperature map corresponding to the generated area is generated; the third generating sub-unit 2448 is configured to generate a temperature map of the data center according to the temperature map corresponding to each area.

6 is a structural block diagram of a temperature processing apparatus of a data center according to an embodiment of the present invention. As shown in FIG. 6, the apparatus further includes: a second generation module 26 configured to generate a stereoscopic data center according to a type of the data center. A display module 28 is configured to combine and display a temperature map of the data center with the stereo model.

In an alternate embodiment, display module 26 is also arranged to use different colors for different temperature value ranges in the temperature map of the data center.

In an alternate embodiment, display module 26 is further configured to display an alert indication when the temperature value of one or more regions of the data center exceeds a predetermined range of temperature values.

In this embodiment, a temperature processing method of a data center is also provided. FIG. 7 is a flowchart of a temperature display method according to an embodiment of the present invention. As shown in FIG. 7, the flow includes the following steps:

Step S702, acquiring temperature data;

Step S704, displaying a temperature map according to the acquired temperature data, wherein the temperature map comprises: temperature maps of the respective regions displayed according to the regions, and the temperature graph of each region displays one or more temperature values in the region.

Through the above steps, the temperature of each area is displayed through the temperature map. Compared with the related art, the operation and maintenance personnel need to view and abnormally locate a large number of temperature data, and the workload of the operation and maintenance personnel is heavy, and the above steps are solved. In the prior art, the problem of regional temperature distribution cannot be displayed intuitively, and the temperature distribution and abnormality information are visually displayed in a temperature map manner, which is more convenient for abnormal positioning and maintenance.

The temperature map described above can be displayed in a variety of ways. In an alternative embodiment, the temperature map is displayed in a three-dimensional model, wherein the solid model is generated from the entity from which the temperature data is derived.

In order to make the displayed temperature map more intuitive, in an alternative embodiment, different colors are used in the temperature map to correspond to different temperature value ranges. For example, blue represents the lowest temperature value and red represents the highest temperature value.

The ultimate goal of detecting temperature data is to manage and operate the data center. In an alternative embodiment, the alarm flag is displayed when the temperature value displayed by the temperature map exceeds a predetermined temperature range. This prompts the operation and maintenance personnel to repair the data center to ensure the security operation of the data center.

8 is a block diagram 5 of a structure of a temperature processing device of a data center according to an embodiment of the present invention. As shown in FIG. 5, the device includes: an obtaining module 82 configured to acquire temperature data; and a display module 84 configured to obtain according to the obtained The temperature data displays a temperature map, wherein the temperature map includes: temperature maps for the various regions displayed by the regions, and the temperature graph for each of the regions displays one or more temperature values in the region.

In an alternative embodiment, display module 84 is further configured to display the temperature map in a three-dimensional model, wherein the solid model is generated from an entity of the temperature data source.

In an alternate embodiment, display module 84 is also arranged to use different colors in the temperature map to correspond to different ranges of temperature values.

In an alternative embodiment, display module 84 is further configured to display an alert indication when the temperature value displayed by the temperature map exceeds a predetermined range of temperature values.

It should be noted that each of the above modules may be implemented by software or hardware. For the latter, the foregoing may be implemented by, but not limited to, the foregoing modules are all located in the same processor; or, the above modules are respectively located. In the first processor, the second processor, and the third processor.

The following is described in conjunction with an alternative embodiment. In the alternative embodiment, the micro-module data center is taken as an example for description. In this alternative embodiment, a calculation method and a display system for a micro-module data center temperature cloud map are designed. By pre-modeling the micro-module type and the temperature sensor device, the temperature data is collected into the database in real time, and the micro-module is periodically calculated and drawn. The temperature cloud map is rendered with the micro-module 3D model to visually display and monitor the temperature distribution within the micro-module.

The optional embodiment provides a calculation method and a display system for a micro-module data center temperature cloud map, so as to realize visual display of internal temperature data and anomalies of the micro-module data center, reduce the complexity of data inspection, and improve operation and maintenance and management efficiency. The temperature cloud map here refers to the temperature data display based on the micro-module data center. The temperature cloud map described below is the temperature cloud map of the above-mentioned micro-module data center.

In this alternative embodiment, a method for calculating a micro-module data center temperature cloud map is provided, and the method includes the following steps:

Step a, adding a micro-module type and importing temperature sensor device information in the configuration management module;

Step b: Importing corresponding temperature sensor device information according to the micro-module type, wherein the temperature sensor position information is associated with the cabinet position in the micro-module, and each of the cabinets is provided with multiple sensors. The internal cabinet of the micro-module data center is divided into two rows. It is a closed modular system. In this paper, the two rows of cabinets are named as cabinet group 1, cabinet group 2, and the channels between the two rows of cabinets are called cold channels. The outer side of the hot channel 1 and the outer side of the cabinet group 2 are hot channels 2, and the temperature sensor devices in the micro module are respectively assigned to the hot channel 1, the hot channel 2, and the cold channel according to their positions;

Step c: Obtain real-time data of the temperature of the hot channel 1 temperature sensor from the database library, and combine the collected data into multi-dimensional matrix data according to the position of the temperature sensor, and name it as a hot channel 1 matrix, and similarly obtain the hot channel 2 temperature sensor. And the temperature acquisition data of the cold channel temperature sensor are combined into multi-dimensional matrix data, which are named as hot channel 2 matrix and cold channel matrix respectively.

Step d: Perform multiple (configurable) bilinear interpolation on the three sets of matrix data generated in the previous step to fill the temperature collection blank space between the temperature sensors.

Step e: Perform RGB color conversion on the three matrices to generate a color cloud map, which is named as hot channel 1 cloud map, hot channel 2 cloud map, and cold channel cloud map. In the cloud map drawing, blue represents the lowest temperature value and red represents the highest temperature value. The blue temperature threshold and the red temperature threshold are configurable, and the temperature values less than the blue temperature threshold are all displayed in blue, and the temperature values greater than the red temperature threshold are all displayed in red, and the intermediate temperature values are from blue, green, and red. The gradient color corresponds to the display.

Step f: Perform micro-module 3D modeling according to the micro-module type imported in step a to generate a micro-module 3D stereo model.

Step g: The three sets of module cloud images generated in step e and the 3D model generated in step f are mutually rendered according to the direction and position of the micromodule 3D model, thereby generating an overall cloud image display of the micromodule data center. When the local temperature inside the micro-module is too high or too low, not only the temperature map is used to visually display the abnormal area, but also the alarm indicator is displayed above the micro-module 3D model, and the temperature alarm detailed information and the alarm area can be displayed floating.

The present invention is described below with reference to the accompanying drawings. FIG. 9 is a flowchart of a method for calculating a temperature map of a data center of a micromodule according to an embodiment of the present invention. As shown in FIG. 9, the process includes the following steps:

Step S902, acquiring basic information of the sensor from the configuration management library;

Step S904, acquiring data collected by the temperature sensor in real time from the relational database;

Step S906, the device is divided into three channels according to the position information of the temperature sensor in the micro module, and the temperature values are combined into a multi-dimensional matrix according to the sensor position;

In step S908, the three-channel cloud image and the micro-module 3D model are mutually rendered, and the micro-module alarm information is displayed floating, and the micro-module data center overall cloud image is generated.

10 is a schematic diagram of functions and processing steps of each module of a micro-module data center temperature cloud image display system according to an embodiment of the present invention. As shown in FIG. 10, the system includes six modules, a configuration planning module, and a data acquisition module (or a temperature data acquisition module, the module implements the functions of the acquisition module 22, an alarm module (the display module 26 implements the function of the module), a 3D modeling module (or a micro-module 3D modeling module), and cloud image data. Calculation module, cloud image display module. The functions of these modules are explained below.

The configuration planning module is a preliminary plan for the micro-module data center system, including the creation of micro-modules, the import of internal devices of the micro-modules, and the introduction of relevant monitoring parameters. The relevant micro-module information and device information are imported into the configuration management database, and the relevant monitoring parameters are imported into the relational database;

The temperature data acquisition module collects the monitoring parameters of the devices in the micro module through the serial port server through the docking Modbus protocol or the Simple Network Management Protocol (SNMP) protocol, and stores the data in the database corresponding table according to the device type;

The alarm module performs an abnormal alarm on the abnormal data collected by the collection module.

The micro-module 3D modeling module performs 3D model modeling on the micro-module according to the micro-module type and related information imported by the configuration planning module to generate a 3D stereo model;

The cloud image data calculation module obtains the micro-module information and the temperature sensor device information in the micro-module by querying the configuration management database, and obtains the real-time temperature value reported by each sensor according to the temperature sensor device information query relational database, according to the position information of the temperature sensor device. The temperature values are collected to form a multi-dimensional data matrix, and the matrix is further interpolated and RGB color converted to generate three sets of module local cloud images.

The cloud image data display module renders the micro-module 3D model and the local cloud image according to the position and direction of the micro-module, and dynamically displays the abnormal alarm information to display the overall temperature cloud map of the micro-module data center.

Referring to FIG. 9 and FIG. 10, the micro-module data center cloud image calculation and display processing process includes:

Step 1: Add a model of the micromodule in the configuration planning module, where the micromodule model includes the layout, location, size, name, and rated power of each cabinet inside the micromodule.

Step 2: Import the modeling information of the temperature sensor device in the micro-module, and specify the unique identifier, name, IP address, port number, location information, micro-module alias, device protocol type, alarm threshold, etc. of the device by importing the file. Information is imported into the configuration management database.

Step 3: Import temperature sensor monitoring parameter information.

Step 4: The data acquisition module collects the monitoring parameters reported by the device by parsing the SNMP/Modbus protocol, and queries the temperature sensor device modeling information imported by the step 2 in the configuration management database, and stores the collected temperature data into the relational database. .

Step 5: The cloud image calculation generation module periodically acquires micro-module model information, temperature sensor device information, and temperature real-time data stored in the database in the configuration management database. According to the position information of the temperature sensor in the micro-module, the temperature sensor is divided into three groups, namely, hot channel 1, hot channel 2, and cold channel, and the temperature values collected by the three groups of temperature sensor devices in real time are in accordance with the micro-module. The position distribution is composed of three sets of multidimensional arrays. Bilinear interpolation is performed on the three sets of multidimensional arrays to fill the temperature values of the blanks between the temperature sensors. Perform RGB color conversion on three sets of multi-dimensional arrays based on the blue temperature threshold and the red temperature threshold set for the temperature cloud map, and generate Three sets of cloud maps exist in the local server. The setting effect means that in the multi-dimensional matrix array, when the temperature value is less than the blue temperature threshold, the color corresponds to blue, the temperature data is greater than the red temperature threshold, and the color corresponds to red. The temperature value between the blue temperature threshold and the red temperature threshold corresponds to the color converted to the gradient color gamut between blue, green, and red according to the magnitude of the value.

Step 6: The 3D modeling module performs 3D modeling on the micromodule according to the micromodule model imported in step 1, and generates a micromodule 3D stereo model.

Step 7: The cloud image display module renders the three sets of cloud images generated in step 5 and the micro-module 3D models generated in step 6 to generate an overall 3D micro-module cloud image display of the micro-module data center.

Step 8: Query the micro-module alarm information. If there is an abnormal alarm, the alarm indicator is displayed above the 3D micro-module in step 7, and the alarm detailed information and the alarm area can be displayed floating.

Among them, the micro-module data center temperature cloud diagram described in the above steps can support cloud display of various micro-module types. The import of micro-module model and device information in the example can support the import of multiple file formats such as execl file and xml file. The temperature data acquisition cycle is configurable in seconds. The cloud map calculation generation module periodically calculates the time period for drawing the cloud map in seconds.

The optional embodiment is applicable to an overall centralized display scenario of a multi-computer room and a multi-micro module data center. Multiple micro-module data centers of multiple computer rooms are respectively drawn and displayed in a single screen according to their positions.

The calculation method and display system of the micro-module data center temperature cloud map provided by the alternative embodiment have the following advantages:

1) The micro-module types in the system of the optional embodiment can be flexibly added and configured, and flexible display of multiple types of micro-module cloud images;

2) The temperature data collection reporting interval and the time interval of the cloud image drawing in the optional embodiment can be flexibly configured, and the micro-module 3D model is mutually rendered, and the internal temperature change of the micro-module data center can be displayed in real time;

3) The color of the cloud image of the alternative embodiment is represented by red, green, blue, and color gradations to represent different temperature values, and the color data values in the micro-module are displayed in a numerical interval, and the blue temperature threshold can be set. And red temperature thresholds, transforming cloud color;

4) The temperature cloud image of the alternative embodiment is related to the micro-module 3D model, the temperature sensor position, and the temperature abnormality alarm, and more intuitively displays the temperature distribution and alarm information in the micro-module, which is convenient for abnormal analysis and positioning.

In summary, in order to improve the maintenance efficiency and more intuitive display effect of the micro-module data center, through an alternative embodiment of the present invention, a technology is developed to visually display the internal temperature distribution of the micro-module data center, and the color temperature cloud map The form shows the temperature values of each area inside the micro-module. The display of the temperature cloud map is closely related to the 3D model of the micro-module, the position and acquisition data of the temperature sensor, and the temperature alarm indication, which more intuitively displays the internal temperature distribution and abnormal information of the micro-module. Convenient for abnormal positioning and maintenance. The temperature cloud map will display the temperature value of the area in the form of a color map. The internal temperature data of the micro-module data center is abnormal (too high or too low), and the operation and maintenance personnel can quickly locate the area, check the equipment, and take corresponding measures.

In another embodiment, software is also provided for performing the technical solutions described in the above embodiments and preferred embodiments.

In another embodiment, a storage medium is further provided, wherein the software includes the above-mentioned software, including but not limited to: an optical disk, a floppy disk, a hard disk, an erasable memory, and the like.

It will be apparent to those skilled in the art that the various modules or steps of the present invention described above can be implemented by a general-purpose computing device that can be centralized on a single computing device or distributed across a network of multiple computing devices. Alternatively, they may be implemented by program code executable by the computing device such that they may be stored in the storage device by the computing device and, in some cases, may be different from the order herein. The steps shown or described are performed, or they are separately fabricated into individual integrated circuit modules, or a plurality of modules or steps thereof are fabricated as a single integrated circuit module. Thus, the invention is not limited to any specific combination of hardware and software.

The above description is only the preferred embodiment of the present invention, and is not intended to limit the present invention, and various modifications and changes can be made to the present invention. Any modifications, equivalent substitutions, improvements, etc. made within the spirit and scope of the present invention are intended to be included within the scope of the present invention.

Industrial applicability

As described above, the temperature processing method and apparatus, and the temperature display method and apparatus of the data center provided by the embodiments of the present invention have the following beneficial effects: the temperature distribution and abnormal information of the micromodule can be visually displayed in a temperature cloud diagram manner. More convenient for abnormal positioning and maintenance.

Claims (22)

1. A method of temperature processing in a data center, comprising:

   Obtaining temperature data collected by a plurality of temperature sensors, wherein the plurality of temperature sensors are disposed in a data center;

   Generating a temperature map of the data center based on temperature data collected by the plurality of temperature sensors and locations of the plurality of temperature sensors.
2. The method of claim 1, wherein generating a temperature map of the data center based on temperature data collected by the plurality of temperature sensors and locations of the plurality of temperature sensors comprises:

   For each area, a matrix corresponding to the area is generated according to temperature data collected by a plurality of temperature sensors in the area and positions of the plurality of temperature sensors, wherein the data center is divided into a plurality of areas;

   A temperature map of the data center is generated according to a matrix corresponding to each of the regions.
3. The method of claim 2, wherein generating the temperature map of the data center according to the matrix corresponding to each of the regions comprises:

   Performing bilinear interpolation of the number of reservations for the matrix corresponding to each of the regions;

   A temperature map of the data center is generated from a matrix after bilinear interpolation.
4. The method according to claim 2 or 3, wherein generating the temperature map of the data center according to the matrix corresponding to each of the regions comprises:

   Generating a temperature map corresponding to the region according to the matrix corresponding to each region;

   A temperature map of the data center is generated according to a temperature map corresponding to each of the regions.
5. The method according to any one of claims 1 to 4, wherein, after generating the temperature map of the data center according to the temperature data collected by the plurality of temperature sensors and the position of the plurality of temperature sensors, the method further comprises:

   Generating a stereo model of the data center according to the type of the data center;

   A temperature map of the data center is combined with the stereo model and displayed.
6. The method of claim 5 wherein combining the temperature map of the data center with the stereo model and displaying comprises:

   Different colors are used in the temperature map of the data center to correspond to different temperature value ranges.
7. The method of claim 6 wherein combining the temperature map of the data center with the stereo model and displaying further comprises:

   An alert indication is displayed when the temperature value of one or more regions of the data center exceeds a predetermined temperature value range.
8. A temperature display method comprising:

   Obtain temperature data;

   Displaying a temperature map according to the acquired temperature data, wherein the temperature map includes: temperature maps of respective regions displayed according to regions, and temperature graphs of each of the regions display one or more temperature values in the region .
9. The method of claim 8 wherein displaying the temperature map comprises:

   The temperature map is displayed in a three-dimensional model, wherein the solid model is generated from an entity from which the temperature data is derived.
10. The method of claim 8 wherein displaying the temperature map comprises:

    Different colors are used in the temperature map to correspond to different temperature value ranges.
11. The method of claim 9 wherein displaying the temperature map in the stereo model comprises:

    An alarm flag is displayed when the temperature value displayed by the temperature map exceeds a predetermined temperature value range.
12. A temperature processing device for a data center, comprising:

    Obtaining a module, configured to acquire temperature data collected by a plurality of temperature sensors in real time, wherein the plurality of temperature sensors are disposed in a data center;

    The first generation module is configured to generate a temperature map of the data center according to temperature data collected by the plurality of temperature sensors and positions of the plurality of temperature sensors.
13. The apparatus of claim 12, wherein the first generation module comprises:

    a first generating unit, configured to generate, for each region, a matrix corresponding to the region according to temperature data collected by the plurality of temperature sensors in the region and the locations of the plurality of temperature sensors, wherein the data center is divided into multiple Area

    The second generating unit is configured to generate a temperature map of the data center according to the matrix corresponding to each of the regions.
14. The apparatus of claim 13, wherein the second generating unit comprises:

    Interpolating the secondary unit, configured to perform bilinear interpolation of the number of reservations for the matrix corresponding to each of the regions;

    The first generation sub-unit is configured to generate a temperature map of the data center according to the matrix after the bilinear interpolation.
15. The apparatus according to claim 13 or 14, wherein the second generating unit further comprises:

    a second generation sub-unit, configured to generate a temperature map corresponding to the region according to the matrix corresponding to each of the regions;

    The third generation subunit is configured to generate a temperature map of the data center according to the temperature map corresponding to each of the regions.
16. The device according to any one of claims 12 to 14, wherein the device further comprises:

    a second generation module, configured to generate a stereo model of the data center according to a type of the data center;

    A display module is configured to combine and display a temperature map of the data center with the stereo model.
17. The apparatus of claim 16 wherein said display module is further configured to use different colors in the temperature map of said data center to correspond to different ranges of temperature values.
18. The apparatus of claim 17 wherein said display module is further configured to display an alert indication when a temperature value of one or more regions of said data center exceeds a predetermined range of temperature values.
19. A temperature display device comprising:

    Obtain a module, set to obtain temperature data;

    a display module configured to display a temperature map according to the acquired temperature data, wherein the temperature map includes: a temperature map of each region displayed according to the region, and a temperature graph of each of the regions displays one of the regions Or multiple temperature values.
20. The apparatus of claim 19 wherein said display module is further configured to display said temperature map in a three-dimensional model, wherein said solid model is generated from an entity of said temperature data source.
21. The apparatus of claim 19 wherein said display module is further configured to use different colors in said temperature map to correspond to different ranges of temperature values.
22. The apparatus of claim 20 wherein said display module is further configured to display an alert indication when said temperature graphically displayed temperature value exceeds a predetermined temperature range.

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