TWI512316B - Remote monitoring and measuring method and the apparatus thereof - Google Patents

Description

Remote monitoring measurement method and device thereof

The invention relates to a measuring device for non-free radiating electromagnetic wave signals, in particular to a remote monitoring measuring method and device thereof.

In recent years, due to the advancement of sensing technology, research on military, optoelectronic, biological, chemical, medical equipment applications, and environmental research projects has been able to move toward more elaborate fields. Therefore, high-tech sensing technology The development of development and its application technology has become a project for countries to compete for research and development. For example, Narda has introduced an instrument that measures the intensity of radiation signals in an environment. It can be used to measure, calculate, and compare the radiation signals that are present in the environment, and whether the intensity can cause harm to the human body. Among them, the measurement instrument introduced by Narda belongs to the measurement of the radiation signal intensity in real time measurement. In addition, there is another way to measure the intensity of the radiation signal, that is, to display the spectrum and intensity of the radiation signal through a spectrum analyzer.

However, no matter which method is used to measure the intensity of the radiation signal in the environment, the monitoring personnel must place the measuring instrument at the designated location and manipulate the measuring instrument to perform the measurement for a period of time. Then, the monitoring personnel Bring the measuring instrument and related measurement data back to the laboratory for subsequent data analysis and research. However, as we all know, some specific measurement locations are Unreachable by humans; for example, mountains, forests, disaster sites, chemically contaminated areas, or high-radiation contaminated areas. Among them, the most obvious example is the 311 earthquake in Japan, the Fukushima nuclear power plant suffered severe damage, resulting in the nuclear disaster in Fukushima; at that time, the monitoring personnel refused to enter the Fukushima nuclear power plant for power plant repair and radiation energy measurement, etc. Therefore, the government has been unable to effectively grasp the intensity of radiant energy leaked from nuclear power plants.

Therefore, through the above, we can know that the measuring instrument for the intensity of the radiation signal currently in use still has obvious shortcomings and shortcomings, that is, the measurement of the intensity of the radiation signal cannot be performed in the form of remote monitoring; in view of this, the present case The inventors worked hard to study and create, and finally developed a remote monitoring measurement method and device to overcome the defects of the conventional radiation signal intensity measuring instrument.

A first object of the present invention is to provide a remote monitoring and measuring method and a device thereof, which are a non-free radiating electromagnetic wave signal in an environment by a monitoring host connecting through an Ethernet network and commanding a spectrum analyzer. Perform remote monitoring and measurement, and immediately calculate and compare the maximum allowable exposure specifications of the non-free radiated electromagnetic wave signal, and then determine whether the strength of the non-free radiated electromagnetic wave signal measured by the system is safe, alert, or not The scope of safety.

A second object of the present invention is to provide a remote monitoring and measuring method and a device thereof, which are connected by a monitoring host through an Ethernet network and command a frequency. The spectrum analyzer further performs remote monitoring and measurement of the non-free radiated electromagnetic wave signals in the environment, and the monitoring personnel can also measure and store the non-free radiated electromagnetic wave signals through the remote monitoring and measuring system. Export to a specific statistical software file, such as: Microsoft® Excel file or OriginLab® Origin file, for the monitoring personnel to carry out comprehensive information through professional engineering and scientific application drawing software. Chart analysis and research.

Therefore, in order to achieve the above object of the present invention, the inventor of the present invention proposes a remote monitoring and measuring device comprising: a spectrum analyzer having an antenna for receiving non-free radiated electromagnetic wave signals from the environment; a monitoring host having at least one computer host, a display and a data input device group, the monitoring host being connected to the spectrum analyzer through an Ethernet network; wherein the monitoring host is connected by a network The line object can establish a connection and communicate with the spectrum analyzer, so that the monitoring host can command the spectrum analyzer to perform measurement of the non-free radiated electromagnetic wave signal in the environment; wherein, after obtaining the non-free radiated electromagnetic wave signal, The monitoring host can calculate and compare the maximum exposure specifications of the non-free radiated electromagnetic wave signals according to the different frequency values of the non-free radiated electromagnetic wave signals and according to the provisions of IEEE Std C95.1 (Maximum Permissible Exposure) , MPE), and then determine the non-free radiated electromagnetic wave signal Whether the strength is safe, alert, or unsafe.

Moreover, in order to achieve the above object of the present invention, the inventor of the present invention further proposes a remote monitoring measurement method, which comprises the following steps: step (000), operating a monitoring host to select the following in a screen of a display (100) The steps of ~(600) are performed; in step (100), a monitoring host is connected to a spectrum analyzer via an Ethernet network, and the following steps (200) to (600) are selected to be performed; (200), manipulating the monitoring host to monitor the non-free radiated electromagnetic wave signal in the environment through the spectrum analyzer, and selecting to perform the following steps (300) to (600); and performing step (300) through the spectrum analysis The instrument measures the non-free radiated electromagnetic wave signal in the environment in a single sampling manner, and immediately calculates the intensity of the non-free radiating electromagnetic wave signal in a safe, warning or dangerous range, and chooses to perform the following (400)~( Step 600 or step (200) is performed; step (400), measuring the non-free radiated electromagnetic wave signal in the environment by using the spectrum analyzer in multiple sampling, and immediately counting The intensity of the non-free radiated electromagnetic wave signal is in a safe, alert or dangerous range, and is selected to perform the following steps (500) to (600) or the above steps (200) and (300); and step (500) Controlling the monitoring host to store the non-free radiated electromagnetic wave signals measured in the above step (300) or step (400) as a specific statistic The applicable file of the software is selected and executed by performing the following steps (600) or the above steps (200) to (400).

In order to more clearly describe a remote monitoring measurement method and apparatus thereof according to the present invention, an embodiment of the present invention will be described in detail below with reference to the drawings.

Before describing the remote monitoring measurement method of the present invention, a remote monitoring measurement device of the present invention must be described. Please refer to the first figure, which is a structural diagram of a remote monitoring and measuring device according to the present invention. The remote monitoring and measuring device 1 of the present invention mainly includes a spectrum analyzer 12, an antenna 121 and a monitoring host 11. As shown in the first figure, there is a radiation source RS (Radiation Source) in the environment, and a control region CR (Control Region) and a non-control region NCR (Non-Control) can be defined around the radiation source RS. Region). It is known that the radiation source RS emits a non-free radiating electromagnetic wave signal, and the spectrum analyzer 12 of the remote monitoring and measuring system 1 of the present invention measures and receives non-free radiated electromagnetic wave signals from the environment through the antenna 121.

In the above, via an Ethernet 13 (which may be a wired Ethernet or a wireless Ethernet network), the monitoring host 11 can be connected to the spectrum analyzer 12 with a specific IP address, thereby further The end control spectrum analyzer 12 performs the measurement of the non-free radiated electromagnetic wave signals of the radiation source RS. Moreover, in the remote monitoring and measuring system 1 of the present invention, the monitoring host 11 has a computer The host 111, a display 112 and a data input device group 113, wherein the data input device group 113 is a mouse and a keyboard; thus, the monitoring personnel can monitor a connected object in the host 11 and analyze the spectrum. The instrument 12 establishes a connection and communicates with each other; further, after the connection between the monitoring host 11 and the spectrum analyzer 12 is established, the monitoring personnel can instruct the spectrum analyzer 12 to perform non-free radiation in the environment through the monitoring host 11. The measurement of the electromagnetic wave signal, in this way, completes the remote monitoring and measurement of the non-free radiated electromagnetic wave signal emitted by the radiation source RS.

In particular, the technical feature of the remote monitoring and measuring system 1 of the present invention is that the spectrum analyzer 12 can selectively measure the non-free radiated electromagnetic wave signals in the environment in the form of single sampling or multiple sampling; After obtaining the data of the non-free radiated electromagnetic wave signal, the monitoring host 11 can calculate and compare the non-free values according to the different frequency values of the non-free radiated electromagnetic wave signals and according to the provisions of IEEE Std C95.1. The Maximum Permissible Exposure (MPE) of the radiated electromagnetic wave signal, thereby determining the strength of the measured non-free radiated electromagnetic wave signal for the control area CR and the non-control area NCR (Non-Control Region) personnel In other words, it is a range of safety, warning, or unsafe, and at the same time, a green light, a yellow light or a red light is displayed correspondingly with one warning light; thus, the monitoring personnel can pass the green light, the yellow light or the red light light. The police immediately learned whether the strength of the non-free radiated electromagnetic wave signal in the current control area CR and the non-control area NCR will be on the body. To harm, but to have Effectively prevent monitoring personnel from exposure to radiation risks.

In the technology of the remote monitoring and measuring system 1 of the present invention, after obtaining the data of the non-free radiating electromagnetic wave signal in the environment, the monitoring host 11 can automatically store the non-free radiating electromagnetic wave signal and instantaneously transmit the data. The display 112 displays the data of the non-free radiated electromagnetic wave signal; at this time, the monitoring personnel can control the monitoring host 11 to sort the data of the non-free radiated electromagnetic wave signal displayed on the display 112 by frequency magnitude or amplitude. Conduct preliminary data research and analysis. Moreover, in addition to the function of automatically storing the data of the non-free radiating electromagnetic wave signal, the monitoring host 11 can also export the data of the non-free radiating electromagnetic wave signal to a suitable file of a specific statistical software, for example, an application file of Microsoft® Excel or OriginLab®'s Origin file; this is more conducive to the monitoring and research of comprehensive data by monitoring personnel through professional engineering and scientific application drawing software.

Thus, the above is a complete and clear description of the architecture of the remote monitoring and measuring apparatus of the present invention and the functions provided thereto; and then, a remote monitoring and measuring method of the present invention will be further described below. Please refer to the second figure, which is a flowchart of the main method of the remote monitoring measurement method of the present invention; and, please refer to the third to third J diagrams at the same time, which is the execution screen of the remote monitoring measurement method of the present invention. Figure. As shown in the second figure, the remote monitoring measurement method of the present invention includes (S000), (S100), (S200), (S300), (S400), and (S500) the main method steps; These method steps are exactly The remote monitoring measurement method execution screens shown in the third to third J diagrams are presented.

First, at the time of step (S000), the monitoring personnel can see the screen as shown in FIG. 3A on the display 112 of the monitoring host 11; at this time, the monitoring personnel can control the monitoring host 11 and display the farness on the display 112. The step of performing the monitoring (S100)~(S600) is performed in the interface of the end monitoring measurement system, thereby completing the remote monitoring measurement method of the present invention. For example, when the monitoring personnel wants to connect the monitoring host 11 to the spectrum analyzer 12 via the Ethernet 13, as shown in the third B, the monitoring personnel can click the file (F) menu and further select the connection (C). The instructions are such that the step (S100) can be performed such that the monitoring host 11 is connected to the spectrum analyzer 12 via the Ethernet 13.

In the above, the step (S100) includes a plurality of detailed execution steps. Please refer to FIG. 4A and FIG. 4B, which are flowcharts of detailed execution steps of step (S100). As shown in FIG. 4A and FIG. 4B, the detailed execution steps of step (S100) are as follows: First, the system Performing step (S101), via the Ethernet 13, the monitoring host 11 is connected to the spectrum analyzer 12 by a specific IP address; then, performing a step (S102) to determine whether to monitor the host 11 and spectrum analysis There is a connection object between the instruments 12, if not, step (103) is performed to monitor the host 11 to establish the connection object, and then continue to perform the step (S104) to determine whether the connection object is successfully established, and if not, Then, the step (S105) is performed to cause the display 112 of the monitoring host 11 to display a connection error message. Here, when When the display 112 displays the connection error message, the screen display is as shown in the third C. At this time, the monitoring host 11 cannot be normally connected to the spectrum analyzer 12, and the monitoring host 11 and the spectrum analyzer must be inspected by the engineering personnel. 12 The reason why the connection could not be established.

In the above, if the judgment formula of the foregoing step (S104) determines that the monitoring host 11 and the spectrum analyzer 12 have successfully established the connection, then the step (S106) is performed to call the connected object to communicate the monitoring host 11 with the The spectrum analyzer 12; next, in the step (S107), the monitoring host 11 can write an object through a command to transmit an identification code acquisition command to the spectrum analyzer 12; after that, in step (S108), it is determined whether The command of the monitoring host 11 has been successfully transmitted to the spectrum analyzer 12, and if so, steps (S109) and steps (S110) are performed, the spectrum analyzer 12 transmits an identification code back to the monitoring host 11, and the display 112 displays the The identification code and a connection success message (the screen display is as shown in Figure 3B). However, if the result of the judgment of the step (S108) is NO, it indicates that the command of the monitoring host 11 cannot be transmitted to the spectrum analyzer 12, and the display 112 of the monitoring host 11 also displays a connection error message (ie, As shown in FIG. 3C, it indicates that the monitoring host 11 still cannot be properly connected to the spectrum analyzer 12, and the reason why the monitoring host 11 cannot smoothly transmit the command to the spectrum analyzer 12 must be checked by the engineering personnel.

After establishing the connection relationship between the monitoring host 11 and the spectrum analyzer 12 through the step (S100), the monitoring or measurement of the non-free radiated electromagnetic wave signals in the environment can be started. For example, as shown in the third D, The monitoring personnel can select the measurement (M) menu and further select the monitoring instruction, so that the step (S200) can be executed to control the monitoring host 11, and then the spectrum analyzer 12 can monitor the non-free radiation in the environment. The electromagnetic wave signal; wherein the step (S200) also includes a plurality of detailed execution steps. Please refer to FIG. 5A, which is a flowchart of detailed execution steps of step (S200). As shown in FIG. 5A, the detailed execution steps of step (S200) are as follows: First, it is determined in step (S201) whether the monitoring host is 11 has indeed been connected to the spectrum analyzer 12, and if not, the step (S202) is performed to display the unconnected message by the display 112, and the last screen returns to the display of the step (S000) (ie, Third A)). Conversely, if the monitoring host 11 has indeed connected to the spectrum analyzer 12, then step (S203) is performed, and the monitoring host 11 starts a first timer inside the spectrum analyzer 12 to calculate a first of the monitoring signals. time interval. If yes, step (S204) and step (S205) are performed, and the monitoring host 11 obtains the amplitude unit size, the starting frequency and the cutoff frequency currently set by the spectrum analyzer 12, and obtains one of the presets of the spectrum analyzer 12, etc. The frequency interval is divided into 551 aliquots. Finally, in step (S206), the monitoring host 11 displays the non-free radiated electromagnetic wave signals in the environment received by the spectrum analyzer 12 through an antenna 121 for display on the display 112. Among them (the screen is displayed as shown in the third E picture).

Please refer to FIG. 5B continuously, which is a detailed execution step flow chart of step (S203), wherein, as shown in FIG. 5B, detailed execution of step (S203) The steps are as follows: First, in the step (S203.1), the monitoring host 11 obtains the data of the spectrum analyzer 12 for one of the non-free radiated electromagnetic wave signals every time the first time interval (500 ms) is passed (trace Then, in step (S203.2), the monitoring host 11 decodes the captured data; finally, in step (S203.3), the host 11 monitors the screen of the display 112 to transmit non-free radiated electromagnetic waves. The captured information of the signal is displayed on the display 112.

In the above, when the monitoring personnel immediately monitors the non-free radiated electromagnetic wave signal in the environment for a period of time through the step (S200) and feels that the non-free radiating electromagnetic wave signal has stabilized, as shown in the third F, the monitoring personnel The measurement (M) menu can be clicked, and the single sampling instruction is further selected, so that the step (S300) can be performed to perform the non-environment in the environment by the spectrum analyzer 12 in a single shot (One Shoot) manner. The measurement of the free-radiation electromagnetic wave signal and immediately calculate the intensity of the non-free-radiating electromagnetic wave signal in a safe, warning or dangerous range. Wherein, the step (S300) also includes a plurality of detailed execution steps, refer to the sixth A diagram and the sixth B diagram, which are flowcharts of detailed execution steps of the step (S300), as shown in the sixth A diagram and the sixth B diagram. The detailed execution steps of the step (S300) are as follows: First, in the step (S301), the monitoring host 11 turns off the first timer, and instructs the spectrum analyzer 12 to measure non-free radiation in the environment in a single sampling manner. The electromagnetic wave signal; next, in the step (S302) and the step (S303), the monitoring host 11 obtains the amplitude unit size, the starting frequency and the cutoff frequency currently set by the spectrum analyzer 12, and obtains the spectrum analyzer 12 The interval frequency of a specific halving currently set (551 aliquots). After the monitoring host 11 obtains all the current settings of the spectrum analyzer 12, the step (S304) is continuously performed to obtain the trace data of the spectrum analyzer 12 for one of the non-free radiated electromagnetic wave signals; and then, in step (S305) The monitoring host 11 decodes the captured data and automatically stores the captured data of the non-free radiated electromagnetic wave signal.

The step (S305) also includes a plurality of detailed execution steps. Please refer to the seventh figure, which is a detailed execution step flowchart of the step (S305). As shown in the seventh figure, the detailed execution steps of the step (S305) are as follows: First, the step (S305.1) is performed to preset the energy unit of the non-free radiated electromagnetic wave signal to be stored as mW/m2, and add an index number field (Index), an amplitude field (Amp), and a The amplitude unit field (AmpUnit), a frequency field (Freq), and a frequency unit field (FreqUnit); then, the step (S305.2) is performed to determine whether the non-free radiated electromagnetic wave signal to be stored has been If yes, the step (S305.3) is performed, and if not, step (305.4) is performed. Wherein, in the step (S305.3), the data of the existing non-free radiated electromagnetic wave signal is updated, and then the step is performed (S306); and, in the step (S305.4), the file is stored one by one. Information on all non-free radiated electromagnetic signals.

After the process of automatically storing the data in step (S305) is completed, then in step (S306), the monitoring host 11 updates the display content of the display 112 (as shown in the third G diagram). Then, in step (S307), the monitoring host 11 will take The obtained non-free radiated electromagnetic wave signals are sorted according to the signal intensity, and the first 21 non-free radiated electromagnetic wave signals with the strongest signal strength are taken out. As shown in the third G diagram, after sorting, the monitor can clearly know from the interface of the remote monitoring measurement system displayed on the display 112 that the index of the non-free radiated electromagnetic wave signal index (Index) with the highest intensity is 275 non-free radiated electromagnetic wave signal, and the amplitude field (Amp) shows that the amplitude of the signal is 0.7886785 mW/m2, and the frequency field (Freq) shows that the frequency is 1840 MHz.

According to the above, in the step (S308), according to the different frequency values of the 21 non-free radiated electromagnetic wave signals, the monitoring host 11 respectively separates the 21 pens according to the provisions of IEEE Std C95.1. The radiant electromagnetic wave signal is divided by its Maximum Permissible Exposure (MPE); then, in step (S309), the 21 non-free radiated electromagnetic wave signals are respectively divided by the cumulative value of the maximum allowable exposure specification, and The accumulated value is displayed on the display 112 (as in the control area average MPE and the non-control area average MPE values shown in the third H picture). Then, it is determined in step (S310) whether the cumulative value obtained in the foregoing step (S309) is less than 0.001, and if yes, the step (S311) is performed to determine that the intensity of the non-free radiated electromagnetic wave signal is within a safe range, and the monitoring host 11 controls One of the warning lights displays a green light, and returns to the step (S000); otherwise, if not, the step (S312) is performed to determine whether the cumulative value obtained in the foregoing step (S309) is greater than or equal to 0.001 and less than 1, and if so, Then performing step (S313) to determine non-free The intensity of the radiated electromagnetic wave signal is within the warning range, the monitoring host 11 controls the warning light to display a yellow light, and returns to the step (S000); if not, the step (314) is executed to determine the intensity of the non-free radiated electromagnetic wave signal. The system is in danger and the monitoring host 11 controls its warning light to display a red light, and returns to this step (S000).

In addition, when the monitoring personnel immediately monitors the non-free radiated electromagnetic wave signal in the environment for a period of time through the step (S200), and feels that the non-free radiating electromagnetic wave signal has stabilized, as shown in the third figure, the monitoring personnel can Clicking the measurement (M) menu and further selecting the instruction for multiple sampling, so that the step (S400) can be performed to perform non-free radiation in the environment by the spectrum analyzer 12 in a plurality of sampling manners (Sampling). The measurement of the electromagnetic wave signal and immediately calculate the intensity of the non-free radiated electromagnetic wave signal in a safe, warning or dangerous range. Wherein, the step (S400) also includes a plurality of detailed execution steps, please refer to the eighth A diagram and the eighth B diagram, which are flowcharts of the detailed execution steps of the step (S400), as shown in the eighth A diagram and the eighth B diagram. The detailed execution steps of the step (S400) are as follows: First, in the step (S401), the monitoring host 11 starts a second timer to time a second time interval, and performs measurement of a plurality of samples of a specific number of times. Then, in step (S402), the monitoring host 11 commands the spectrum analyzer 12 to measure the non-free radiated electromagnetic wave signals in the environment in the form of multiple samples during the measurement time of the multiple sampling. After the step (S402) is completed, in the step (S403) and the step (S404), the monitoring host 11 takes The amplitude unit size, the starting frequency and the cutoff frequency currently set by the spectrum analyzer 12 are obtained, and a specific interval interval frequency set by the spectrum analyzer 12 is obtained.

Please refer to the eighth C diagram, which is a flowchart of the detailed execution steps of the step (S401), wherein, as shown in the eighth C diagram, the detailed execution steps of the step (S401) are as follows: first, the step (S401.1) is performed. Each time the second time interval (500 ms) elapses, the monitoring host 11 obtains the captured data of the spectrum analyzer 12 for the non-free radiated electromagnetic wave signal; and then performs the step (S401.2) to calculate and display the multiple sampling amount. The number of measurements. Then, in step (S401.3) and step (S401.4), the monitoring host 11 decodes the captured data, and updates the screen of the display 112 to display the captured data of the non-free radiated electromagnetic wave signal on the display. 112. Continuing, in step (S401.5), it is determined whether the number of times of sampling measurement has reached the specified number of times, and if so, the step is executed (S402), and if not, the step is repeated (S401.1).

In the above, then, in step (S405) and step (S406), the monitoring host 11 obtains trace data of the spectrum analyzer 12 for one of the non-free radiated electromagnetic wave signals, and obtains the non-free radiated electromagnetic wave signal. The captured data is decoded and subjected to an average value operation, wherein the so-called average value calculation sums the acquired non-free radiated electromagnetic wave signals by the extracted data, and then divides by the specific number of times, for example, multiple sampling The number of measurements is 60, divided by 60. Continuing, in step (S407) and steps (S408), the monitoring host 11 automatically stores the data of the non-free radiated electromagnetic wave signal and updates the display content of the display 112. Therefore, it must be particularly noted that the automatic data storage operation performed in the step (S408) also has many detailed execution steps, and the detailed execution steps are exactly the same as the four shown in the seventh figure. In the steps, the engineering personnel who implement the invention can refer to and implement it. Next, in step (S409), the monitoring host 11 sorts the non-free radiated electromagnetic wave signals obtained by the average value according to the signal intensity, and extracts the first 21 non-free radiated electromagnetic wave signals with the highest signal intensity. After the step (S409) is completed, the step (S410) is followed. According to the different frequency values of the 21 non-free radiated electromagnetic wave signals, the monitoring host 11 respectively treats the 21 non-standards according to the IEEE Std C95.1. The free-radiation electromagnetic wave signal is divided by its maximum allowable exposure specification (MPE); in accordance with the above, the step (S411) is continuously performed, and the 21 non-free radiated electromagnetic wave signals are respectively divided by the cumulative value of the maximum allowable exposure specifications, and The accumulated value is displayed on the display 112 (such as the control area average MPE and the non-control area average MPE value shown in the third H picture); then, in step (S412), it is determined whether the cumulative result of the foregoing step (S411) is obtained. The value is less than 0.001. If yes, the step (S413) is performed to determine that the intensity of the non-free radiated electromagnetic wave signal is within a safe range, and the monitoring host 11 controls a warning light to display a green light, and returns to the step (S000); If no, step (S414) is performed to determine whether the cumulative value obtained in the foregoing step (S411) The system is greater than or equal to 0.001 and less than 1, and if yes, step (S415) is performed to determine that the intensity of the non-free radiated electromagnetic wave signal is within the warning range, and the monitoring host 11 controls the warning light to display a yellow light, and returns to the step ( S000); if not, step (S416) is performed to determine that the intensity of the non-free radiated electromagnetic wave signal is within the dangerous range, and the monitoring host 11 controls its warning light to display a red light, and returns to the step (S000).

In addition, it must be specifically noted that, in the detailed step (S308) of the single sampling procedure described above, a plurality of detailed steps are further included, and the steps are used to obtain the 21 non-free radiated electromagnetic waves obtained. The maximum allowable exposure specifications corresponding to the signals are separately found, and each non-free radiated electromagnetic wave signal is divided by its maximum allowable exposure specification; of course, these steps are also applicable to the steps of the above multiple sampling procedure (S410). Please refer to the ninth A diagram, the ninth B diagram and the ninth C diagram, which are flowcharts of detailed execution steps of the step (S308), as shown in the ninth A diagram, the ninth B diagram and the ninth C diagram, the step (S308) The detailed execution steps are as follows: First, in step (S308.1), it is determined whether the frequency value of the non-free radiated electromagnetic wave signal is less than 1 MHz, and if so, the step (S308.2) is performed to apply the non-free radiated electromagnetic wave. The amplitude value of the signal is divided by 9000, and then the step is performed (S309); if not, the step (S308.3) is performed to determine whether the frequency value of the non-free radiated electromagnetic wave signal is greater than or equal to 1 MHz and less than 30 MHz, and if so, Then performing the step (S308.4) to multiply the amplitude value of the non-free radiated electromagnetic wave signal by the square value of the frequency value, and divide by 9000, and Then, the step (S309) is performed; if not, the step (S308.5) is performed to determine whether the frequency value of the non-free radiated electromagnetic wave signal is greater than or equal to 30 MHz and less than 300 MHz, and if yes, the step (S308.6) is performed. Dividing the amplitude value of the non-free radiated electromagnetic wave signal by 10, and then performing the step (S309); if not, performing step (S308.7) to determine whether the frequency value of the non-free radiating electromagnetic wave signal is greater than or equal to 300 MHz, and If it is less than 3000 MHz, if yes, perform step (S308.8) to multiply the amplitude value of the non-free radiated electromagnetic wave signal by 30, and divide by the frequency value thereof, and then perform the step (S309); if not, execute the step ( S308.9), determining whether the frequency value of the non-free radiating electromagnetic wave signal is greater than or equal to 3000 MHz, and if yes, performing step (S308.10) to divide the amplitude value of the non-free radiating electromagnetic wave signal by 100, and then performing the step ( S309).

Thus, after the calculation of the above steps (S308.1) to (S308.10), the corresponding maximum exposure specifications of the 21 non-free radiated electromagnetic wave signals obtained from the environment are found one by one, and the The 21 non-free radiated electromagnetic wave signals are also respectively divided by their maximum exposure specifications; afterwards, these values are facilitated in the step (S309), and then the above steps (S310) and steps (S312) can be immediately determined. It is known that the intensity of the non-free radiated electromagnetic wave signals belongs to the safety range, the warning range or the dangerous range for the person currently in the control area CR; as shown in the third H diagram, if the result of the instant judgment is safe Then, the interface of the remote monitoring measurement system displayed on the display 112 is immediately displayed, so that the monitoring personnel can immediately It is known that the intensity of the non-free radiated electromagnetic wave signals is safe for the person currently in the control area CR and does not cause harm to the human body.

Furthermore, in the detailed step (S308) of the single sampling procedure described above, another set of detailed steps is additionally included, and the steps are for using the 21 non-free radiated electromagnetic wave signals obtained from the environment. The corresponding maximum exposure specifications are separately found, and each non-free radiated electromagnetic wave signal is divided by its maximum allowable exposure specification; of course, these steps are also applicable to the steps of the above multiple sampling procedure (S410). Please refer to FIG. 10A, FIG. 10B and FIG. 10C, which are another set of detailed execution steps of the step (S308), as shown in FIG. 10A, FIG. 10B and FIG. Another detailed execution step of the step (S308) is as follows: First, in the step (S308.1'), it is determined whether the frequency value of the non-free radiated electromagnetic wave signal is less than 1.34 MHz, and if yes, the step is performed (S308. 2'), dividing the amplitude value of the non-free radiated electromagnetic wave signal by 1000, and then performing the step (S309); if not, performing the step (S308.3') to determine whether the frequency value of the non-free radiating electromagnetic wave signal is It is greater than or equal to 1.34 MHz and less than 30 MHz. If yes, step (S308.4') is performed to multiply the amplitude value of the non-free radiated electromagnetic wave signal by the square value of the frequency value, and divide by 1800, and then perform the step ( S309'); if not, performing step (S308.5') to determine whether the frequency value of the non-free radiated electromagnetic wave signal is greater than or equal to 30 MHz and less than 400 MHz, and if so, performing step (S308.6') to the non- Free radiation electromagnetic wave signal The amplitude value is divided by 2, and then the step is performed (S309); if not, the step (S308.7') is performed to determine whether the frequency value of the non-free radiated electromagnetic wave signal is greater than or equal to 400 MHz and less than 2000 MHz, and if so, Performing step (S308.8') to multiply the amplitude value of the non-free radiated electromagnetic wave signal by 200, and dividing by the frequency value thereof, and then performing the step (S309); if not, performing the step (S308.9') And determining whether the frequency value of the non-free radiating electromagnetic wave signal is greater than or equal to 2000 MHz, and if yes, performing step (S308.10') to divide the amplitude value of the non-free radiating electromagnetic wave signal by 10, and then performing the step (S309).

Thus, after the calculation of the above steps (S308.1') to the step (S308.10'), the corresponding maximum exposure specifications of the 21 non-free radiated electromagnetic wave signals obtained from the environment are found one by one. And the 21 non-free radiated electromagnetic wave signals are also respectively divided by their maximum exposure specifications; afterwards, these values are facilitated in the step (S309), and then through the above steps (S310) and steps (S312) It is judged that the intensity of the non-free radiated electromagnetic wave signals is in a safe range, a warning range or a dangerous range for the person currently in the non-control area NCR; as shown in the third H diagram, if the result is immediately judged For security, the interface of the remote monitoring measurement system displayed on the display 112 is immediately displayed, so that the monitoring personnel can immediately know the intensity of the non-free radiated electromagnetic wave signals for the person currently in the non-controlled area NCR. It is safe and does not cause harm to the human body.

In addition, in particular, when storing all non-free radiated electromagnetic wave signals one by one, the remote monitoring measurement system displayed on the display 112 automatically edits the Index, and each Index represents a non-free radiated electromagnetic wave. The information of the signal, and the content of the data includes the amplitude, amplitude unit, frequency, and frequency unit; and, after all the data is stored, as shown in the third J, the engineer can also control the monitoring host 11 The stored data of all non-free radiated electromagnetic signals are exported to a specific statistical software file, for example, the application file of Microsoft® Excel or the application file of OriginLab® Origin; thus, it is more beneficial for engineers to use professional Engineering and scientific application of drawing software, the analysis and research of comprehensive data, is another of the biggest technical features and advantages of the present invention.

Thus, by the above description, the remote monitoring and measuring device of the present invention and the remote monitoring and measuring method of the present invention for controlling the device are both complete in structure and technical features and the functional systems provided. It is clearly disclosed; and, through the above, we have learned that the present invention has the following advantages:

1. The remote monitoring measurement method and device provided by the invention can not only apply remote monitoring and measurement of non-free radiated electromagnetic wave signals, but also can directly calculate and compare the maximum of the non-free radiated electromagnetic wave signals. Allowing to expose the specifications, and then determining the strength of the measured non-free radiated electromagnetic wave signals for the current control region CR and a non-control region NCR For personnel, it is a range of safety, warning, or insecurity.

2. In view of the above, the monitoring personnel can immediately know whether the non-free radiated electromagnetic wave signal in the control area CR and the non-control area NCR will be detected by the green light, the yellow light or the red light signal. The body causes harm and can effectively prevent the monitoring personnel from being exposed to radiation risks.

3. In addition, through the remote monitoring and measuring device provided by the present invention, the monitoring personnel can also export the data of the non-free radiating electromagnetic wave signal to a specific statistical software, for example, the application file of Microsoft® Excel or OriginLab. The application file of Origin's Origin; this is more conducive to the monitoring and research of comprehensive data by monitoring personnel through professional engineering and scientific application drawing software.

It is to be understood that the foregoing detailed description of the preferred embodiments of the invention are not intended to It should be included in the patent scope of this case.

1‧‧‧ Remote monitoring and measuring device

11‧‧‧Monitoring host

111‧‧‧Computer host

112‧‧‧ display

113‧‧‧Data input device group

12‧‧‧ spectrum analyzer

121‧‧‧Antenna

13‧‧‧Ethernet

CR‧‧‧Control area

NCR‧‧‧Uncontrolled area

RS‧‧‧radiation source

S000‧‧‧ method steps

S100‧‧‧ method steps

S200‧‧‧ method steps

S300‧‧‧ method steps

S400‧‧‧ method steps

S500‧‧‧ method steps

S101~S105‧‧‧ method steps

S106~S110‧‧‧ method steps

S201~S206‧‧‧ method steps

S301~S309‧‧‧ method steps

S203.1~S203.3‧‧‧ method steps

S309~S314‧‧‧ method steps

S305.1~S305.4‧‧‧ method steps

S401~S409‧‧‧ method steps

S410~S416‧‧‧ method steps

S401.1~S401.4‧‧‧ method steps

S308.1~S308.4‧‧‧ method steps

S308.5~S308.8‧‧‧ method steps

S308.9~S308.10‧‧‧ method steps

S308.1'~S308.4’‧‧‧ method steps

S308.5'~S308.8’‧‧‧ method steps

S308.9'~S308.10’‧‧‧ method steps

The first figure is an architectural diagram of a remote monitoring measurement device of the present invention; the second figure is a flow chart of the main method of the remote monitoring measurement method of the present invention; the third A to the third J are remote monitoring An execution screen map of the measurement method; a flowchart of detailed execution steps of the fourth A diagram and the fourth B diagram system (S100); and a flowchart of detailed execution steps of the fifth A diagram system step (S200); The fifth B diagram is a flowchart of the detailed execution steps of the step (S203); the flowchart of the detailed execution steps of the sixth A diagram and the sixth B diagram (S300); and the detailed execution procedure of the seventh diagram (S305) Figure 8 is a flow chart showing the detailed execution steps of the steps (S400) of the eighth and eighth B systems; a flow chart of the detailed execution steps of the eighth C system (S401); ninth, ninth, and A flowchart of a detailed execution step of the nine-C diagram step (S308); and a flowchart of another group of detailed execution steps of the tenth A diagram, the tenth B diagram, and the tenth C diagram-step (S308).

1‧‧‧ Remote monitoring and measuring device

11‧‧‧Monitoring host

111‧‧‧Computer host

112‧‧‧ display

113‧‧‧Data input device group

12‧‧‧ spectrum analyzer

121‧‧‧Antenna

13‧‧‧Ethernet

CR‧‧‧Control area

NCR‧‧‧Uncontrolled area

RS‧‧‧radiation source

Claims (6)

A remote monitoring measurement method is applied to a monitoring host, so that the monitoring host can control a spectrum analyzer to monitor a non-free radiated electromagnetic wave signal emitted by a radiation source through an antenna; wherein the radiation source The surrounding system is defined as a control area and a non-control area, and the remote monitoring measurement method comprises the following steps: Step (000): Manipulating a monitoring host in a display screen to perform the following steps (100) to Step (100): performing a step (100): connecting a monitoring host to a spectrum analyzer via an Ethernet network, repeating the above step (000); and step (200): controlling the The monitoring host repeatedly performs the above step (000) by monitoring the non-free radiated electromagnetic wave signal in the environment through the spectrum analyzer; and step (300): performing non-free radiation in the environment by using the spectrum analyzer in a single sampling manner. The measurement of the electromagnetic wave signal, and immediately calculate the intensity of the non-free radiated electromagnetic wave signal is in the safe, warning or dangerous range, repeat the above steps (000); 400): measuring the non-free radiated electromagnetic wave signal in the environment by using the spectrum analyzer in multiple sampling manners, and immediately calculating the intensity of the non-free radiating electromagnetic wave signal in a safe, warning or dangerous range, and repeatedly performing The above step (000); Step (500): operating the monitoring host to store the non-free radiated electromagnetic wave signal measured in the above step (300) or step (400) as a suitable file of a specific statistical software, and repeating the above step (000); In the foregoing step (300) and the foregoing step (400), the detailed steps listed below are used to accurately determine that the intensity of the non-free radiated electromagnetic wave signal in the control region is in a safe, alert or dangerous range. Step (307): The monitoring host sorts the non-free radiated electromagnetic wave signals obtained by the spectrum analyzer according to the signal intensity, and extracts the first 21 non-free radiated electromagnetic wave signals with the strongest signal strength; step (308.1): Determining whether the frequency value of the 21 non-free radiated electromagnetic wave signals is less than 1 MHz, if yes, performing step (308.2), if not, performing step (308.3); step (308.2): applying non-free radiating electromagnetic wave signals The amplitude value is divided by 9000, and the following steps (309) are directly performed; step (308.3): determining whether the frequency value of the 21 non-free radiated electromagnetic wave signals is greater than or equal to Less than 1MHz and 30MHz, and if yes, performing step (308.4), and if not, step (308.5); Step (308.4): multiplying the amplitude value of the non-free radiated electromagnetic wave signal by the square value of the frequency value, then dividing by 9000, and directly performing the following step (309); step (308.5): determining whether the 21 non-perfects are The frequency value of the free-radiation electromagnetic wave signal is greater than or equal to 30 MHz and less than 300 MHz, and if so, step (308.6) is performed, and if not, step (308.7) is performed; step (308.6): dividing the amplitude value of the non-free radiated electromagnetic wave signal by 10, and then directly perform the following steps (309); step (308.7): determine whether the frequency value of the 21 non-free radiated electromagnetic wave signals is greater than or equal to 300 MHz and less than 3000 MHz, and if so, perform step (308.8), If not, perform step (308.9); step (308.9): multiply the amplitude value of the non-free radiated electromagnetic wave signal by 30, and divide by the frequency value, and then directly perform the following steps (309); step (308.9): judge Whether the frequency value of the 21 non-free radiated electromagnetic wave signals is greater than or equal to 3000 MHz, and if so, performing step (308.10); step (308.10): dividing the amplitude value of the non-free radiating electromagnetic wave signal by 100 Then directly performing the following steps (309); Step (309): calculating the 21 non-free radiated electromagnetic wave signals respectively divided by the cumulative value of the maximum exposure specification, and displaying the accumulated value on the display; step (310): determining whether the cumulative result of the foregoing step (309) The value is less than 0.001, if yes, step (311) is performed, if not, step (312) is performed; step (311): determining that the intensity of the non-free radiated electromagnetic wave signal is within a safe range, and the monitoring host controls one of the warning lights The number displays a green light, and returns to the step (000); the step (312): determining whether the cumulative value obtained in the foregoing step (309) is greater than or equal to 0.001 and less than 1, and if so, executing step (313), and if not, executing Step (314); Step (313): determining that the intensity of the non-free radiated electromagnetic wave signal is within the warning range, the monitoring host controls the warning light to display a yellow light, and returns to the step (000); and the step (314): Determining that the intensity of the non-free radiating electromagnetic wave signal is within a dangerous range, and the monitoring host controls the warning light to display a red light, and returns to the step (000); wherein, in the foregoing step (300) and the foregoing step (400), Through the following Further details of the steps listed accurate determination of the intensity-based non-ionizing radiation in the region of the electromagnetic control signal is in the safety, warning or danger range: Step (307): the monitoring host sorts the non-free radiated electromagnetic wave signals obtained by the spectrum analyzer according to the signal intensity, and extracts the first 21 non-free radiated electromagnetic wave signals with the highest signal strength; step (308.1') : judging whether the frequency value of the 21 non-free radiated electromagnetic wave signals is less than 1.34 MHz, if yes, executing step (308.2'), if not, performing step (308.3'); step (308.2'): not The amplitude value of the free-radiation electromagnetic wave signal is divided by 1000, and then directly performs the following step (309'); step (308.3'): determining whether the frequency value of the 21 non-free-radiating electromagnetic wave signals is greater than or equal to 1.34 MHz and less than 30MHz, if yes, perform step (308.4'), if not, perform step (308.5'); step (308.4'): multiply the amplitude value of the non-free radiated electromagnetic wave signal by the square of its frequency value, and then divide by 1800, and then perform the following steps (309'); step (308.5'): determine whether the frequency value of the 21 non-free radiated electromagnetic wave signals is greater than or equal to 30 MHz and less than 400 MHz, if Go to step (308.6'), if not, perform step (308.7'); step (308.6'): divide the amplitude value of the non-free radiated electromagnetic wave signal by 2, and then perform the following step (309'); Step (308.7'): determining whether the frequency value of the 21 non-free radiated electromagnetic wave signals is greater than or equal to 400 MHz and less than 2000 MHz, and if so, performing step (308.8'), and if not, performing step (308.9'); Step (308.8'): multiplying the amplitude value of the non-free radiated electromagnetic wave signal by 200, and dividing by the frequency value thereof, and then performing the following step (309'); step (308.9'): determining whether the 21 non-perfects are The frequency value of the free-radiation electromagnetic wave signal is greater than or equal to 2000 MHz, and if yes, step (308.10') is performed; step (308.10'): dividing the amplitude value of the non-free radiated electromagnetic wave signal by 10, and then performing the following step (309') Step (309'): calculating the 21 non-free radiated electromagnetic wave signals respectively divided by the cumulative value of the maximum exposure specification, and displaying the accumulated value on the display; step (310'): determining whether the aforementioned step (309' The cumulative value obtained is less than 0.001, if yes, step (311') is performed, if not, step (312') is performed; step (311'): determining that the intensity of the non-free radiated electromagnetic wave signal is within a safe range, The monitoring host controls a warning light to display a green light, and returns to the step (000); Step (312): determining whether the cumulative value obtained in the foregoing step (309') is greater than or equal to 0.001 and less than 1, if yes, executing step (313'), and if not, performing step (314'); step (313) '): determining that the intensity of the non-free radiated electromagnetic wave signal is within the warning range, the monitoring host controls the warning light to display a yellow light, and returns to the step (000); and the step (314'): determining the non-free radiating electromagnetic wave signal The intensity is in danger, the monitoring host controls its warning light to display a red light, and returns to this step (000); step (309'): calculates the 21 non-free radiated electromagnetic signals divided by their maximum exposure specifications. Accumulating the value, and displaying the accumulated value on the display; step (310'): determining whether the cumulative value obtained in the foregoing step (309') is less than 0.001, and if yes, executing step (311'), if not, executing the step (312'); Step (311'): determining that the intensity of the non-free radiated electromagnetic wave signal is within a safe range, and the monitoring host controls a warning light to display a green light, returning to the step (000); and step (312'): Determine if the above steps ( 309') The cumulative value obtained is 0.001 or more and less than 1, if yes, step (313') is performed, and if not, step (314') is performed; Step (313'): determining that the intensity of the non-free radiated electromagnetic wave signal is within the warning range, the monitoring host controls the warning light to display a yellow light, and returns to the step (000); and the step (314'): determining the non-free The intensity of the radiated electromagnetic wave signal is within the dangerous range, and the monitoring host controls its warning light to display a red light, and returns to this step (000). The remote monitoring measurement method according to claim 1, wherein the step (100) comprises the following detailed steps: (101) via the Ethernet, the monitoring host is connected by a specific IP address. Wire to the spectrum analyzer; (102) determine whether there is a connected object between the monitoring host and the spectrum analyzer, if yes, perform step (104), if not, perform step (103); (103) monitor the host Establishing the connection object; (104) determining whether the connection object is successfully established, if yes, performing step (106), if not, proceeding to the step (105); (105) monitoring the display of the host display a connection error Returning to the step (000); (106) calling the connected object to communicate the monitoring host with the spectrum analyzer; (107) the monitoring host writes an object through one of the commands, transmits an identification code to obtain a command to the spectrum analyzer; (108) determines whether the command to monitor the host has been successfully transmitted to the spectrum analyzer, and if so, performs step (109). If not, step (105) is performed; (109) the spectrum analyzer transmits an identification code back to the monitoring host; and (110) the display displays the identification code and a connection success message. The remote monitoring measurement method of claim 1, wherein the step (200) further comprises the following detailed steps (monitoring signal): (201) determining whether the monitoring host has been connected to the spectrum analysis. If yes, execute step (203); if not, execute step (202); (202) monitor the host to display an unconnected message, and perform the above steps (000); (203) monitor the host A first timer in the spectrum analyzer is started to calculate a first time interval; (204) the monitoring host obtains the amplitude unit size, the starting frequency and the cutoff frequency currently set by the spectrum analyzer; (205) the monitoring host obtains The spectrum analyzer presets one of the specific equally divided frequency intervals; and (206) the monitoring host displays the non-free radiated electromagnetic wave signal in the environment through the antenna through the antenna, and displays the same in the display. The remote monitoring measurement method of claim 3, wherein the step (203) further comprises the following detailed steps: (203.1) the monitoring host obtains the spectrum analyzer every time the first time interval elapses For one of the non-free radiated electromagnetic wave signals, (203.2) the monitoring host decodes the captured data; (203.3) the monitoring host updates the display of the display to capture the non-free radiated electromagnetic wave signals The data is displayed on the display. The remote monitoring measurement method of claim 3, wherein the specific equalization described in the above step (205) is 551 aliquots. The remote monitoring measurement method of claim 1, wherein the specific statistical software described in the step (500) can be any of the following: Excel of Microsoft® and Origin of OriginLab®.