TWI559130B - Data processing system, data processing method and power management system - Google Patents

Description

Data processing system, data processing method, and power management system

The present invention relates to a monitoring technique, and more particularly to a data processing system, a data processing method, and a power management system that integrate an environmental floor plan.

With the global population booming, the energy crisis has been a topic of great concern to countries in recent years. In addition, with the advancement of technology, people have applied a large number of electronic products in their daily lives. Therefore, how to balance energy conservation and maintain the convenience and comfort of life is still a dilemma.

Here, if you want to save energy and maintain the convenience and comfort of life, you must be able to effectively control the operation of the surrounding electronic products, or instantly discover the abnormal operation of electronic products. However, monitoring the large number of electronic products around by traditional manual methods is not effective, and lacks the immediacy of monitoring.

In the practice of the conventional monitoring interface, when the sensor configuration information is combined with the interior design drawing, the interior design drawing is only regarded as a simple image background. That is to say, when the manager pulls the icon of a sensor into an interior design drawing (for example, a certain room), the system does not analyze/detect the process of the configuration, but simply corresponds to The connection between the sensor of the icon and a position of the interior design map is established. However, in such a design, if the tube If the operator incorrectly configures the sensor icon in an unreasonable area (such as a two-room wall), the system will not be able to recognize the error immediately, so that the user can obtain the reading through the sensor icon in the future (for example) At temperature/humidity, it is not possible to know exactly which room/area reading corresponds to it.

The invention integrates the sensing result of the sensor and the environment plan, analyzes and debugs the configuration process of the sensor icon, avoids the error of the subsequent information interpretation, and also solves the unsuitable benefit and lack of the traditional way of monitoring the electronic product. Immediacy issues.

The present invention provides a data processing method suitable for a plurality of sensors, each sensor being disposed in at least one physical area, and the data processing method includes the following steps. Read the environmental plan. Generating a plurality of first virtual sensors, each of the first virtual sensors being associated with one of the plurality of sensors, and configuring the plurality of first virtual sensors to the environment plan according to the first configuration signal Multiple first configuration locations on. The sensing results from the plurality of sensors are received, and the sensing results are displayed through the plurality of first virtual sensors. Determine if the sensing result is normal. When the sensing result is not normal, the first warning message is sent.

In an embodiment of the present invention, a plurality of second virtual sensors are generated, and the plurality of second virtual sensors are disposed in a plurality of second configuration positions on the environment plan according to a second configuration signal. The measurement result is used to generate the simulation data, and the plurality of first simulation results are obtained according to the simulation data and the plurality of second configuration positions to display the corresponding plurality of first simulation results through the plurality of second virtual sensors.

In another embodiment of the present invention, a plurality of boundaries in the environment plan are read, the plurality of boundaries dividing the environment plan into at least one virtual area, the at least one virtual area corresponding to at least one real field, and according to the plurality of boundaries and at least A virtual area is used to determine whether the plurality of first configuration locations and the plurality of second configuration locations are normal.

In another embodiment of the present invention, determining whether the plurality of first configuration locations are located on a plurality of boundaries, and when the plurality of first configuration locations are located on the plurality of boundaries, issuing a second alert message and determining a plurality of second The configuration location is located on multiple boundaries, and when multiple second configuration locations are located on multiple boundaries, a third alert message is sent.

In another embodiment of the present invention, determining whether the plurality of first configuration locations are located in the at least one virtual area, and when the plurality of first configuration locations are not located in the at least one virtual area, issuing a fourth alert message, and determining Whether the second configuration location is located in the at least one virtual area, and when the plurality of second configuration locations are not located in the at least one virtual area, the fifth alert message is sent.

In another embodiment of the present invention, it is determined whether the environment plan has a completely closed block composed of a plurality of boundaries, and when the environment plan has a completely closed block, the completely closed block is determined as a virtual area.

In another embodiment of the present invention, it is determined whether there is a partial open block in the environment plan view, the partial open block has a gap, and the ratio of the gap to the boundary to which the gap belongs is less than a critical value, and the local open block in the environmental plan view When the local open block is determined as a virtual area.

In another embodiment of the present invention, the interpolation algorithm is executed according to the sensing result, thereby generating the simulation data, and marking at least one contour on the environmental plan corresponding to the simulation data.

In another embodiment of the present invention, the corresponding second simulation result is displayed according to the simulation data and the cursor position.

The invention provides a data processing system comprising a plurality of sensors and an information processing device. The information processing device includes a reading unit, a building unit, a processing unit, and a comparison unit. Wherein each sensor is disposed in at least one physical area. The reading unit is used to read the environmental plan. The establishing unit is coupled to the reading unit, and configured to generate a plurality of first virtual sensors, each of the first virtual sensors being associated with one of the plurality of sensors, and according to the first configuration signal The plurality of first virtual sensors are disposed in a plurality of first configuration locations on the environmental floor plan. The processing unit is coupled to the reading unit and the building unit, and configured to receive sensing results from the plurality of sensors and display the sensing results through the plurality of first virtual sensors. The comparison unit is coupled to the reading unit, the setting unit and the processing unit, and is used to determine whether the sensing result is normal. When the sensing result is abnormal, the first warning message is sent.

The invention provides a power management system, which comprises an environment control device, an air conditioner, a coordinator, a central host, an energy management host and a terminal device. The environmental control device includes one or more sensors, one or more meters, and a first wireless node device. The sensor senses the live environment and communicates the information to the first wireless node device. The meter communicates the power usage information to the first wireless node device. The air conditioning device includes one or more frequency converters, a program logic controller, and a second wireless node device. The coordinator receives information from the first wireless node device and the second wireless node device and controls the first wireless node device and the second wireless node device. The central host receives information from the coordinator and controls the coordinator. The energy management host collects and analyzes the information received from the central host, and issues management commands to the central host according to the analysis result, and the central host manages the environmental sensing device or the air conditioning device through the coordinator. The terminal device receives the information of the central host and the energy management host and displays it on the screen.

As described above, the present invention monitors the corresponding sensor in the physical area by configuring the first virtual sensor in the environment plan, and displays the corresponding information by configuring the second virtual sensor in the environment plan. Simulation results. When the sensing result is abnormal, a corresponding warning message may be issued. During the configuration process of the first virtual sensor and the second virtual sensor, when the corresponding configuration location is unreasonable, another corresponding alert message may be sent. Thereby, the user's misconfiguration of the virtual sensor can be eliminated, and the surrounding environment state can be monitored and simulated effectively and instantly.

The above description of the present invention and the following description of the embodiments are intended to illustrate and clarify the spirit and principles of the invention and to provide further explanation of the scope of the invention.

100‧‧‧Data Processing System

101~120, 11‧‧‧ sensor

200‧‧‧Information processing device

210‧‧‧Reading unit

220‧‧‧Building unit

230‧‧‧Processing unit

240‧‧‧ comparison unit

10‧‧‧Environment sensing device

12‧‧‧Electric meter

13‧‧‧First wireless node device

20‧‧‧Air conditioning unit

21‧‧‧Inverter

22‧‧‧Program Logic Controller

23‧‧‧Second wireless node device

30‧‧‧ Coordinator

40‧‧‧Center host

50‧‧‧Energy Management Host

60‧‧‧ Terminal equipment

S310~S350‧‧‧Steps of data processing method

1 is a block diagram of a data processing system in accordance with an embodiment of the present invention.

2 is a system architecture of a power management system according to an embodiment of the present invention Figure.

3 is a flow chart of a data processing method in accordance with an embodiment of the present invention.

The detailed features of the present invention are described in the following description, which is sufficient for any skilled person to understand the technical contents of the present invention and to implement it, and according to the contents disclosed in the specification, the patent application scope and the drawings, any familiarity The related objects and advantages of the present invention will be readily understood by those skilled in the art. The following examples are intended to further illustrate the invention, but are not intended to limit the scope of the invention.

1 is a block diagram of a data processing system 100 in accordance with an embodiment of the present invention. The data processing system 100 includes a plurality of sensors 101-120 and an information processing device 200. Each sensor is disposed in at least one physical area. For example, the sensors 101-120 may be temperature sensors, humidity sensors, or electric meters or other sensing devices, which are not limited herein. The number of sensors is also not limited. The physical area can be a plant space, a conference room, a classroom, or any area defined by walls, partitions, or various physical boundaries.

The information processing apparatus 200 includes a reading unit 210, a building unit 220, a processing unit 230, and a comparison unit 240. The information processing device 200 can be a desktop computer, a notebook computer, or various smart electronic devices, and is not limited herein. The reading unit 210, the building unit 220, the processing unit 230, and the comparing unit 240 may be various functional chips or microprocessors, and are not limited herein.

The reading unit 210 is configured to read an environmental plan view. In the embodiment of the present invention, the reading unit 210 can perform image recognition on a specific indoor design map, thereby converting into an environment plan, and outputting the environment plan into the monitoring interface as an image background corresponding to the monitoring environment. In another embodiment of the present invention, the reading unit 210 can perform image recognition on other types of design drawings to be converted into an environmental plan view, which is not limited herein.

The building unit 220 is coupled to the reading unit 210. In addition, the building unit 220 is configured to generate a plurality of first virtual sensors, each of which is associated with one of the plurality of sensors 101-120, and is configured according to the first configuration signal. The first virtual sensors are disposed in a plurality of first configuration locations on the environment plan. In the embodiment of the present invention, each of the first virtual sensors may be an icon corresponding to one of the specific sensors 101-120 in the monitoring interface. The first configuration signal can be various touch operations, such as drag and drop, or various touch inputs, which are not limited herein. The user can appropriately configure the plurality of first virtual sensors by inputting the first configuration signal in the environment plan in the monitoring interface. Thereby, the user can intuitively read out the actual configuration of the plurality of sensors 101-120 according to the relative positions of the first virtual sensors in the monitoring interface.

The processing unit 230 is coupled to the reading unit 210 and the building unit 220. In addition, the processing unit 230 is configured to receive sensing results from the plurality of sensors 101-120 and display the sensing results through the plurality of first virtual sensors. In the embodiment of the present invention, the sensing result of the sensors 101-120 may be temperature information, humidity information, power consumption information, or various environmental status information, which is not limited herein. Processing order The element 230 can display the sensing result on or around the first virtual sensor located at the first configuration position, or other representative locations, and is not limited herein.

The comparison unit 240 is coupled to the reading unit 210, the building unit 220, and the processing unit 230. In addition, the comparison unit 240 is configured to determine whether the sensing result is normal, and when the sensing result is abnormal, the first warning message is sent. In the embodiment of the present invention, the comparison unit 240 can determine whether the sensing result is normal according to historical operation information or information security standards. The first alert message may be a blinking signal on the corresponding first virtual sensor or another type of prompt message.

In the embodiment of the present invention, similar to the configuration of the first virtual sensor, the building unit 220 may further generate a plurality of second virtual sensors, and generate a plurality of second virtual sensations according to the second configuration signal. The detector is disposed in a plurality of second configuration locations on the environmental plan. The second virtual sensor can also be an icon. The second configuration signal can also be various touch operations, such as drag and drop, or perform various touch inputs, which are not limited herein. Unlike the first virtual sensor, the purpose of the second virtual sensor may not directly correspond to the sensing result of the sensor. The processing unit 230 may generate the simulation data according to the sensing result of the sensor, and obtain the first simulation result according to the simulation data and the plurality of second configuration positions, and display the corresponding through the plurality of second virtual sensors. The first simulation result.

In the embodiment of the present invention, the processing unit 230 may perform an interpolation algorithm according to the sensing result, so as to generate the simulation data, in addition, the processing unit 230 may mark at least the environmental simulation plan corresponding to the generated simulation data. One equivalent line. For example, if the sensors 101-110 are temperature sensors, the processing unit 230 can generate temperature-dependent analog data by performing an interpolation algorithm and mark the isotherms on the environmental plan. If the sensors 111-120 are humidity sensors, the processing unit 230 can generate humidity-related simulation data by performing an interpolation algorithm and mark the wet lines on the environmental plan. Processing unit 230 may mark its isotherms, iso-wet lines, or other contours with different colors.

In the embodiment of the present invention, the processing unit 230 may further display the corresponding second simulation result according to the simulation data and a cursor position. For example, if the user wants to monitor a more important fixed point, a second virtual sensor can be configured on the monitoring interface to monitor the first simulation result of the fixed point. If the user wants to monitor the maneuver, the mouse cursor can be moved on the environment plan to dynamically and instantly monitor the second simulation result corresponding to the cursor position.

In the embodiment of the present invention, the reading unit 210 may further identify a plurality of boundaries in the environment plan, the plurality of boundaries dividing the environment plan into at least one virtual area, and at least one virtual area corresponding to the at least one real field. For example, the virtual area may correspond to a physical area such as a plant space, a conference room, a classroom, and the boundaries in the environmental plan may correspond to walls, partitions, or various physical boundaries used to define the physical area. In the process of defining a virtual area, a boundary may not be continuously and completely defined due to its boundary. For example, in an interior design drawing, a conference room with doors and windows may have a corresponding door. The gap with the window. In the interior design drawing, a closed basement that needs to reach its central location via an elevator, the block may have no gap.

Therefore, in the embodiment of the present invention, the reading unit 210 further determines whether the environmental plan has a completely closed block composed of a plurality of boundaries, and when the environment plan has a completely closed block, the block is completely closed. It is determined to be a virtual area. Wherein, the completely closed block may be a block without a gap. The reading unit 210 can further determine whether there is a local open block in the environment plan, and the partial open block has a gap, and the ratio of the gap to the boundary to which the gap belongs is less than a critical value. When the reading unit 210 determines a partial open block having the above condition in the environmental plan view, the partial open block is determined as a virtual area.

For example, when the ratio of the gap to the boundary to which the gap belongs is less than 1/3 (ie, a critical value), the reading unit 210 may determine that the gap should be a gap of the corresponding door or window. Thereby, in the environmental plan view, the reading unit 210 can regard the block having a relatively small gap as a virtual area. Conversely, when the ratio of the gap to the boundary to which the gap belongs is greater than or equal to 1/3, the reading unit 210 can determine that the boundary to which the gap belongs should not be sufficient as a boundary defining the virtual area. The above threshold value may be other values, which may be adjusted according to practical experience, and is not limited herein.

In addition, in an embodiment of the present invention, the comparison unit 240 may further further according to multiple boundaries and at least one, in order to prevent the user from being unreasonable in the configuration process of the first virtual sensor and the second virtual sensor. The virtual area determines whether the plurality of first configuration locations and the plurality of second configuration locations are normal.

In general, sensing or simulating environmental conditions for walls, partitions, or various physical boundaries can be determined to be meaningless operations. In other words, when the first configuration location and the second configuration location are located in the side of the environmental floor plan When it comes to the world, this may be an inaccurate configuration. Therefore, in the embodiment of the present invention, the comparing unit 240 further determines whether the plurality of first configuration positions are located on a plurality of boundaries, and when the plurality of first configuration positions are located on the plurality of boundaries, issuing a second warning message. And determining whether the plurality of second configuration locations are located on the plurality of boundaries, and when the plurality of second configuration locations are located on the plurality of boundaries, issuing a third alert message. The second warning message and the third warning message may be a blinking signal respectively on the corresponding first virtual sensor and the second virtual sensor, or other types of prompt messages.

In addition, since the sensors 101-120 are disposed in the physical area, the first virtual sensor corresponding to the sensors 101-120 is not disposed in the corresponding virtual area if the user is in the configuration process. At the time, it should be judged as an abnormal operation. Therefore, in the embodiment of the present invention, the comparing unit 240 may further determine whether the plurality of first configuration positions are located in the at least one virtual area, and when the plurality of first configuration positions are not located in the at least one virtual area, Fourth warning message.

In addition, as described above, since the processing unit 230 can perform an interpolation algorithm according to the sensing results of the sensors 101 to 120 in the physical region, analog data is generated. Therefore, in the configuration process, when the second configuration location is not configured in the virtual region of the corresponding physical region, the result that can be represented by the corresponding simulation may have a large error. Therefore, in the embodiment of the present invention, the comparing unit 240 may further determine whether the plurality of second configuration positions are located in the at least one virtual area, and when the plurality of second configuration positions are not located in the at least one virtual area, Fifth warning message. The fourth warning message and the fifth warning message may be respectively emitting a blinking signal on the corresponding first virtual sensor and the second virtual sensor, or other types of Show message.

2 is a system architecture diagram of a power management system in accordance with an embodiment of the present invention. As shown in FIG. 2, an environment sensing device 10 includes one or more sensors 11, one or more electric meters 12, and a first wireless node device 13, and the sensor 11 senses the scene environment. After the measurement, the information is transmitted to the first wireless node device 13, the electric meter 12 transmits the power consumption information to the first wireless node device 13; and the air conditioning device 20 includes one or more frequency converters 21 and a program logic controller. 22. A second wireless node device 23; a coordinator 30, receiving information from the first wireless node device 13 and the second wireless node device 23, the coordinator 30 preferably using wireless communication technology and a wireless node The device 13 and the second wireless node device 23 communicate, and the coordinator 30 can transmit the sensor 11, the electric meter 12, the frequency converter 21 or the program logic controller through the first wireless node device 13 and the second wireless node device 23 22 is assigned, for example, requesting an instant reading or changing a set value; a central host 40 receiving information from the coordinator 30 and communicating to the coordinator 30; an energy management host 50, counting and analyzing the receipt from the middle The information of the host 40, and the management command is issued to the central host 40 according to the analysis result, the central host 40 manages the environment sensing device 10 or the air conditioning device 20 through the coordinator 30; and a terminal device 60 receives the The first information of the central host 40 and the second information from the energy management host 50 are displayed on a screen; wherein the first information is a timely reading from the sensor, the meter or the logic controller of the program The second information is an environment or electricity consumption information that has been calculated or counted.

In the embodiment of the present invention, each sensor 11 is connected to the electric meter 12 Placed in at least one physical area, and the terminal device 60 further reads the environmental plan to generate a plurality of first virtual sensors, and each of the first virtual sensors is associated with the plurality of sensors 11 and the electric meter 12 And the terminal device 60 configures the plurality of first virtual sensors to the plurality of first configuration locations on the environment plan according to the first configuration signal. The terminal device 60 further receives the sensing results from the plurality of sensors 11 and the electric meter 12, and displays the sensing results through the plurality of first virtual sensors. The terminal device 60 further determines whether the sensing result is normal. When the sensing result is abnormal, the first warning message is sent.

3 is a flow chart of a data processing method in accordance with an embodiment of the present invention. The data processing method of the embodiment of the present invention is applicable to a plurality of sensors 101-120, and each sensor is disposed in at least one physical area. The data processing method includes steps S310 to S350.

In step S310, the reading unit 210 reads an environmental plan view. In step S320, the building unit 220 generates a plurality of first virtual sensors, each of which is associated with one of the plurality of sensors, and is configured according to the first configuration signal. A virtual sensor is disposed in a plurality of first configuration locations on the environmental floor plan. In step S330, the processing unit 230 receives the sensing results from the plurality of sensors and displays the sensing results through the plurality of first virtual sensors. In step S340, the comparison unit 240 determines whether the sensing result is normal. In step S350, when the comparison unit 240 determines that the sensing result is not normal, the first warning message is issued. The details of steps S310 to S350 have been described above, and will not be described herein.

In summary, the present invention can convert an interior design map into an environmental plane The figure serves as the background of the monitoring interface and identifies the boundary and virtual area. In addition, the corresponding sensor in the physical area can be monitored by configuring the first virtual sensor in the environment plan, and the corresponding simulation result can be displayed by configuring the second virtual sensor in the environment plan. . The present invention can also draw contours in the environmental plan according to the simulation data. For example, the temperature and humidity data are calculated by the processing unit 230 using the internal difference method and the environmental plan recognized by the reading unit to draw the temperature, The contour of the humidity is displayed on the terminal device 60, so that the user can have a clear grasp of the temperature and humidity conditions of the building. In a preferred embodiment, different temperature and humidity regions are marked in different colors in terminal device 60. When the sensing result is abnormal, a corresponding warning message may be issued. During the configuration process of the first virtual sensor and the second virtual sensor, when the corresponding configuration location is unreasonable, another corresponding alert message may be sent. In this way, the user's improper configuration of the virtual sensor can be eliminated, and if properly configured, the relative position of the sensor can be intuitively grasped, and the surrounding environmental state can be monitored and simulated effectively and instantly. Further achieve the effect of saving energy and maintaining the convenience and comfort of life.

In addition, the present invention has a schematic/correct scale switching design. Since the environment plan used is for the convenience of the user, it is often used to represent the drawing instead of using the correct scale. Therefore, the present invention further includes a schematic/correct scale switching function. The user can switch the environment plan to the schematic mode or the correct scale mode through the terminal device 60. When currently in the schematic mode, the first virtual sensor is automatically placed in the center of the first virtual area so that the manager Quickly understand the area to which the first virtual sensor belongs. Once switched to the correct scale mode, the first virtual sensor will be accurately placed at the position specified by the first configuration signal and the isothermal/equal wet line will be automatically calculated.

In an embodiment of the present invention, there is another environmental floor plan building unit (not shown) for allowing a user to manually create an environment plan having a vector value, so that the reading unit does not need to read the environment plan. . The vector values can be used to indicate that a virtual region corresponds to the boundary of the real field region.

In an embodiment of the present invention, the plurality of sensors 101-120 have a micro-location function, and can perform indoor positioning of the mobile device according to a wireless signal sent by a mobile device (not shown). . In this way, the terminal device 60 can simultaneously display the sensing result and the mobile device on the environmental plan, so that the location of the field personnel and the temperature state perceived by the person can be accurately known.

In an embodiment of the present invention, the administrator can directly set an alarm on the sensing result by using the environment plan displayed by the terminal device 60 and directly sensing the sensing results of the plurality of sensors 101-120 displayed on the screen. The limit value, for example, if the carbon dioxide value exceeds 1%, transmits an alarm message to the terminal device 60, or activates the on-site alarm device to alert the field personnel.

Although the present invention has been disclosed above in the foregoing embodiments, it is not intended to limit the invention. It is within the scope of the invention to be modified and modified without departing from the spirit and scope of the invention. Please refer to the attached patent application for the scope of protection defined by the present invention.

S310~S350‧‧‧Steps of data processing method

Claims (16)

A data processing system comprising: a plurality of sensors, each of the sensors being disposed in at least one physical area; and an information processing device comprising: a reading unit for reading an environmental plan; a unit, coupled to the reading unit, for generating a plurality of first virtual sensors, and a plurality of second virtual sensors, each of the first virtual sensors being associated with the sensors And configuring, according to a first configuration signal, the first virtual sensors in the plurality of first configuration locations on the environment plan, each of the second virtual sensors according to a second configuration signal a plurality of second configuration locations disposed on the environment plan; a processing unit coupled to the reading unit and the building unit for receiving sensing results from the sensors and transmitting the first The virtual sensor is configured to display the sensing result, and the processing unit further generates a simulation data according to the sensing result, and obtains a plurality of first simulation results according to the simulation data and the second configuration positions, to Through these second virtual A first sensor to show the simulation results corresponding to the plurality; and An aligning unit is coupled to the reading unit, the arranging unit and the processing unit for determining whether the sensing result is normal. When the sensing result is abnormal, a first warning message is sent. The data processing system of claim 1, wherein the reading unit further identifies a plurality of boundaries in the environment plan, the boundaries dividing the environment plan into at least one virtual area, the at least one virtual area corresponding to at least one The real field area, and the comparison unit further determines whether the first configuration locations and the second configuration locations are normal according to the boundaries and the at least one virtual region. The data processing system of claim 2, wherein the comparing unit further determines whether the first configuration locations are located on the borders, and when the first configuration locations are located on the borders, issuing a The second warning message is sent to determine whether the second configuration locations are located on the borders. When the second configuration locations are located on the borders, a third alert message is sent. The data processing system of claim 3, wherein the comparing unit further determines whether the first configuration locations are located in the at least one virtual area, and when the first configuration locations are not located in the at least one virtual area Sending a fourth warning message, and determining whether the second configuration locations are located in the at least one virtual area, and sending a fifth alert message when the second configuration locations are not located in the at least one virtual area. . The data processing system of claim 2, wherein the reading unit further determines whether the environmental plan has a fully enclosed block formed by the boundaries, when the environmental plan has the fully enclosed block And the fully enclosed block is determined as the virtual area. The data processing system of claim 5, wherein the reading unit further determines whether the environmental plan has a partial open block, the partial open block has a gap, and the gap is relative to the gap A ratio of the boundary is less than a threshold value, and when the local open block is present in the environment plan view, the local open block is determined as the virtual area. The data processing system of claim 1, wherein the processing unit further performs an interpolation algorithm according to the sensing result, thereby generating the simulation data, and marking at least one of the simulated data on the environment plan. Contour. The data processing system of claim 7, wherein the processing unit further displays a corresponding second simulation result according to the simulation data and a cursor position. A data processing method is applicable to a plurality of sensors, each of the sensors is disposed in at least one physical area, and the data processing method includes: reading an environment plan; generating a plurality of first virtual sensors and a plurality of second virtual sensors, each of the first virtual sensors being associated with one of the sensors, and configured to configure the first virtual sensors according to a first configuration signal Environmental plan a plurality of first configuration locations, each of the second virtual sensors being disposed in a plurality of second configuration locations on the environment plan according to a second configuration signal; receiving sensing results from the sensors And displaying the sensing result by using the first virtual sensors, and generating a simulation data according to the sensing result, and obtaining a plurality of first simulation results according to the simulation data and the second configuration positions. And displaying the corresponding first simulation results through the second virtual sensors; determining whether the sensing result is normal; and when the sensing result is abnormal, issuing a first warning message. The data processing method of claim 9, wherein the step of reading the environment plan further comprises: identifying a plurality of boundaries in the environment plan, the boundaries dividing the environment plan into at least one virtual area, The at least one virtual area corresponds to at least one real field area; and determining, according to the boundaries and the at least one virtual area, whether the first configuration locations and the second configuration locations are normal. The data processing method of claim 10, wherein, in the step of determining whether the first configuration locations and the second configuration locations are normal according to the boundaries and the at least one virtual region, the method includes: determining the Whether the first configuration locations are located on the borders, and when the first configuration locations are located on the borders, a second alert message is sent; Determining whether the second configuration locations are located on the borders, and when the second configuration locations are located on the borders, issuing a third alert message. The data processing method of claim 11, wherein the step of determining whether the first configuration locations and the second configuration locations are normal according to the boundaries and the at least one virtual region comprises: determining the Whether the first configuration location is located in the at least one virtual area, and when the first configuration location is not located in the at least one virtual area, sending a fourth alert message; and determining whether the second configuration location is located In at least one virtual area, when the second configuration locations are not located in the at least one virtual area, a fifth alert message is sent. The data processing method of claim 12, after the step of reading the boundaries in the environment plan, further comprising: determining whether the environment plan has a completely closed block formed by the boundaries, When the environment plan has the fully enclosed block, the fully enclosed block is determined to be the virtual area. The data processing method of claim 13, wherein after the step of reading the boundaries in the environment plan, the method further comprises: determining whether the environment plan has a partial open block, the local open block having a a gap, and a ratio of the gap to the boundary to which the gap belongs is less than a threshold value, and when the local open block is present in the environment plan view, the local open block is determined as the virtual area. The data processing method of claim 8, further comprising: performing an interpolation algorithm according to the sensing result, thereby generating the simulation data, and marking the analog data on the environment plan to mark at least one contour . The data processing method of claim 15, further comprising: displaying a corresponding second simulation result according to the simulation data and a cursor position.