KR20220086834A - method for controlling the operation of portable signal analyzing apparatus - Google Patents

Abstract

The present invention relates to a method for controlling the operation of a portable signal analysis device capable of controlling the operation of a portable signal analysis device that analyzes a spectrum of a radio signal or a performance test of a mobile communication system in the vicinity of a mobile communication base station by means of a voice command. .
In the method of controlling the operation of a portable signal analysis device of the present invention, a portable signal analysis device performing a function test or spectrum analysis of a mobile communication system is connected to a smart device by short-range wireless communication, and the smart device commands a command through a wired/wireless communication network (a) of determining whether an arbitrary voice command is input after performing a wake-up when the smart device receives a wake-up voice command while being connected to the analysis server; (b) of converting the inputted voice command into a voice file when an arbitrary voice command is input in step (a) and transmitting the inputted voice command to a command analysis server; The smart device determines whether a text command is received from the command analysis server and, if received, determines whether a valid command is a valid command in steps (c) and (c). It is made including the step (d) of controlling the operation of the signal analysis device by transmitting.
As a result of the determination in step (c), if it is not a valid command, the step (e) of notifying the field personnel that the recognition of the voice command has failed is further provided.
The command analysis server automatically converts the voice file received in step (b) into text by ASR technology, analyzes the meaning of the text by NLU technology, and converts the meaning of the command in the voice file into text commands. and then transferred to the smart device.

Description

Method for controlling the operation of portable signal analyzing apparatus

The present invention relates to a method for controlling the operation of a portable signal analysis device, and in particular, it is possible to control the operation of a portable signal analysis device that analyzes a spectrum of a radio signal or a performance test of the mobile communication system in the vicinity of a mobile communication base station by a voice command. It relates to a method for controlling the operation of a portable signal analysis device.

1 is a diagram for explaining the structure of a cloud radio access network. As shown in FIG. 1 , a general Cloud Radio Access Network (C-RAN) includes a Radio Unit (RU) 100 , a Digital Unit (DU) cloud 200 and a fronthaul network 300 . is composed of

In the above configuration, the RU 100 is a device that is installed in each cell site to perform wireless communication with the mobile communication terminal 20 located in the cell site, and basically transmits and receives radio signals with the mobile communication terminal 20 and It performs RF signal processing functions such as filtering, amplification, analog/digital conversion, and digital/analog conversion of transmitted and received radio signals. In this way, a plurality of RUs 100 installed in the cell site are connected to the DU cloud 200 located at a remote location through the fronthaul network 300 , and the digital signal processed by the RF signal is transmitted to the DU cloud through the fronthaul network 300 . 200) is exchanged for

The DU cloud 200 is connected to a plurality of RUs 100 through the fronthaul network 300 , and is connected to the core network 500 of the mobile communication system through the backhaul network 400 , and is connected to the RU 100 . data traffic between the mobile communication terminal 20 and the core network 500 is processed.

The core network 500 is a configuration for performing signaling control and data traffic routing in a mobile communication system, and may be, for example, an Evolved Packet Core (EPC) or a 5G core defined in LTE. The fronthaul network 300 is a transmission network for transferring data between a plurality of RUs 100 and the DU cloud 200. Based on optical fibers or microwaves, the fronthaul network 300 may be constructed in various structures such as stars, trees, chains, or rings. As the communication interface, Common Public Radio Interface (CPRI) and Open Baseband Remote Radiohead Interface (OBSAI) are used.

On the other hand, the portable signal analysis apparatus is used to test the performance of the mobile communication system or to analyze the spectrum of a radio signal in the vicinity of a mobile communication base station. FIG. 2 is a functional block diagram of a conventional portable signal analysis apparatus.

As shown in FIG. 2, the conventional portable signal analysis device includes a control unit 11 that collectively controls the operation of the device, an input UI (User Interface) 12 used to input various operation commands or settings of the device, and the like; An output UI 13 that visually/auditively displays the current operating state or result of the device, for example, a frequency spectrum analysis screen, a USB interface 14 that is wired to exchange data with an external device, and an external device WiFi communication unit 15 that wirelessly communicates with and exchanges data with, spectrum analyzer (S/A) that analyzes the frequency spectrum around the base station, LTE-TDD, LTE-FDD, WCDMA and 5G NR (New Radio) It may include a signal analysis unit 16 and other functional units 17 for performing performance tests of various mobile communication systems, such as.

In the above configuration, the input UI 12 may be implemented as a keypad or a graphical user interface (GUI). The output UI 13 may be implemented as an LCD panel or the like.

3 is a diagram for explaining an example of use of a conventional portable signal analysis device. As shown in Figure 3, conventionally, a field agent climbs directly to the base station pylon or the roof railing of a building and connects the corresponding port of the portable signal analysis device to the output port of the base station antenna (RU) with a cable, or the receiving antenna of the portable signal analysis device It was necessary to operate the input UI of the portable signal analysis device while pointing it toward the radio base station antenna (RU) to be measured.

However, in the process of measuring the base station's transmitted signal, the measurement site is narrow or sufficient space necessary to operate the signal analysis device is not secured, so field personnel are constantly exposed to the risk of safety accidents, and human errors occur due to the difficulty of operating the device. As a result, there was a problem in that the measurement results were inaccurate.

Prior Art 1: 10-2083273 Registered Patent Publication (Title of the Invention: Method and Apparatus for Dynamic Configuration of Cloud Radio Access Network)

Prior Art 2: 10-2005-0122720 Unexamined Patent Publication (Title of the Invention: Mobile communication method and system providing a user interface using voice)

Prior Art 3: 10-2019-0093528 Unexamined Patent Publication (Title of the Invention: Voice processing method using artificial intelligence device)

The present invention has been devised to solve the above problems, and it is possible to control the operation of a portable signal analysis device that analyzes a spectrum of a radio signal or a performance test of a mobile communication system in the vicinity of a mobile communication base station by a voice command. An object of the present invention is to provide a method for controlling the operation of a portable signal analysis device.

In a method for controlling the operation of a portable signal analysis device of the present invention for achieving the above object, a portable signal analysis device performing a function test or spectrum analysis of a mobile communication system is connected to a smart device by short-range wireless communication, and the smart device is (a) of determining whether an arbitrary voice command is input after performing a wakeup performed in a state connected to the command analysis server through a wired/wireless communication network, when a wakeup voice command is input to the smart device; (b) of converting the inputted voice command into a voice file when an arbitrary voice command is input in step (a) and transmitting the inputted voice command to a command analysis server; The smart device determines whether a text command is received from the command analysis server and, if received, determines whether a valid command is a valid command in steps (c) and (c). It is made including the step (d) of controlling the operation of the signal analysis device by transmitting.

As a result of the determination in step (c), if it is not a valid command, the step (e) of notifying the field personnel that the recognition of the voice command has failed is further provided.

The command analysis server automatically converts the voice file received in step (b) into text by ASR technology, analyzes the meaning of the text by NLU technology, and converts the meaning of the command in the voice file into text commands. and then transferred to the smart device.

According to the operation control method of the portable signal analysis device of the present invention, for example, when measuring the antenna of the base station on the pylon, the smart device and the portable signal analysis device are put in the backpack, and the smart device and the wireless earphone are connected by Bluetooth communication by voice. Because the operation command of the portable signal analysis device can be transmitted, the hands of the field personnel on the pylon are free, and the safety and convenience of the field personnel can be secured.

In addition, by controlling the operation of the portable signal analysis device through voice commands, it can support unskilled people to easily perform even expert-level measurement tasks. Since this command can control the portable signal analysis device, the time and manpower required for measurement can be reduced.

1 is a diagram for explaining the structure of a cloud radio access network.
2 is a functional block diagram of a conventional portable signal analysis device.
3 is a diagram for explaining a use case of a conventional portable signal analysis device.
Figure 4 is a network configuration diagram in which the operation control method of the portable signal analysis apparatus of the present invention is implemented.
5 is a functional block diagram of a signal analysis device control app installed in a smart device in the method for controlling the operation of a portable signal analysis device of the present invention.
Fig. 6 is a functional block diagram of the command parsing server in Fig. 5;
7 is a flowchart for explaining the operation control method of the portable signal analysis apparatus of the present invention.
8 is a diagram illustrating an exemplary set of text commands stored in a knowledge base of a command analysis server in a method for controlling the operation of a portable signal analysis device of the present invention.

Hereinafter, a preferred embodiment of the operation control method of the portable signal analysis apparatus of the present invention will be described in detail with reference to the accompanying drawings.

4 is a network configuration diagram in which the operation control method of the portable signal analysis apparatus of the present invention is implemented. As shown in FIG. 4, the network configuration in which the operation control method of the portable signal analysis apparatus of the present invention is implemented is largely a mobile communication base station, for example, a RU of a C-RAN, an eNB, or a gNB (next generation Node B). ) in the vicinity of a portable signal analysis device 10 ′ that performs functional tests or spectrum analysis of various mobile communication systems, and short-range communication with the portable signal analysis device 10 ′, for example, WiFi wireless communication to transmit operation control commands and a smart device 20', such as a smart phone or tablet PC, which receives various data, is connected to the smart device 20' through a WiFi hotspot or mobile communication network, and is connected from the smart device 20' to the field A command analysis server ( 30) may be included.

In the configuration described above, the smart device 20' transmits the text-type command received from the command analysis server 30 to the portable signal analysis device 10' through WiFi communication, so that the portable signal analysis device 10' You can control the operation or set various necessary items. Hereinafter, the operation control command or the item setting command of the portable signal analysis device 10' is collectively referred to as an 'action control command'.

In the drawing, reference numeral 50 denotes a DU (Digital Unit) of C-RAN, 19 denotes a reception antenna connected to the portable signal analysis device 10', and 40 denotes a smart device 20 from the portable signal analysis device 10'. ') represents a cloud server that stores and manages various analysis data received.

5 is a functional block diagram of a signal analysis device control app installed in a smart device in the method for controlling the operation of a portable signal analysis device of the present invention. 5, the signal analysis device control app installed in the smart device 20' in the method for controlling the operation of the portable signal analysis device of the present invention operates based on the mobile operating system, for example, the Android operating system. Signal analysis that performs performance tests of various mobile communication systems such as a spectrum analyzer that analyzes the frequency spectrum around the base station, LTE-TDD, LTE-FDD, WCDMA and 5G NR (New Radio) It can be made including a USB interface (USB) and a WiFi communication unit for wired and wireless communication with the unit, other function units (General Configuration), voice wake-up engine (Voice Wake-Up engine), portable signal analysis device (10'), respectively. have.

6 is a functional block diagram of the command analysis server in FIG. 5 . As shown in FIG. 6 , the command analysis server 30 may largely include a voice recognition unit (ASR), a voice understanding unit (NLU), and a voice synthesis unit (TTS).

In the above configuration, ASR (Automatic Speech Recognition) is a technology that automatically converts a speaker's command into a language understood by a computer (Text), and uses an artificial neural network engine to learn words and sentences.

Next, NLU (Natural Language Understanding) is a technology to understand what a given text means. to analyze In NLU, various similar patterns are learned in order to understand the intention of the speaker. Recently, as deep learning technology has been applied in earnest, understanding ability is rapidly improving.

TTS (Text to Speech) is a technology that converts text sentences into speech, and through this, speed and height can be adjusted just like a human speaks.

7 is a flowchart for explaining the operation control method of the portable signal analysis device of the present invention, which is performed mainly by the signal analysis device control app.

As shown in FIG. 7, first, in a state in which the signal analysis device control app waits for the input of the wake-up voice command in the background (step S100), in step S110, the wake-up voice command, for example, "wake up", "wake up" It is determined whether a command such as " or "call" is input. If the wake-up voice command is not input in step S110, the process returns to step S100, whereas if it is input, the process proceeds to step S120 to wait for input of an arbitrary voice command.

Next, in step S130, it is determined whether an arbitrary voice command is input. If it is not, step S130 is repeatedly performed, whereas if it is input, the process proceeds to step S140 to convert the input voice command into a voice file. It is transmitted to the command analysis server (30).

Afterwards, the command analysis server 30 automatically converts the voice file received from the signal analysis device control app into text by ASR technology, and then analyzes the meaning of the text by NLU technology to determine the meaning of the command contained in the voice file. After converting the bar into text, it is transmitted to the signal analysis device control app.

In response, the signal analysis device control app determines whether a text command has been received from the command analysis server 30 in step S150 and, if received, proceeds to step S160 again to determine whether the received command is a valid command.

As a result of the determination in step S160, if the text command is not received or the received command is not a valid command, the process proceeds to step S170 and returns to step S120 after notifying the field agent that the recognition of the voice command has failed. In the case of a valid command, the operation proceeds to step S180 to transmit the corresponding text command to the signal analysis device to control the operation.

8 is a diagram illustrating a set of text commands stored in a knowledge base of a command analysis server in the method for controlling the operation of a portable signal analysis device of the present invention, and various types of commands are recognized as one and the same command. It shows that it can be (processed).

Above, the preferred embodiment of the method for controlling the operation of the portable signal analysis apparatus of the present invention has been described in detail with reference to the accompanying drawings, but this is only an example, and various modifications and changes will be possible within the scope of the technical spirit of the present invention . Accordingly, the scope of the present invention should be defined by the description of the following claims.

Claims (3)

A portable signal analysis device that performs a function test or spectrum analysis of a mobile communication system is connected to a smart device by short-distance wireless communication, and the smart device is connected to a command analysis server through a wired/wireless communication network.
(a) determining, by the smart device, whether an arbitrary voice command is input after performing a wake-up when a wake-up voice command is input;
(b) of converting the inputted voice command into a voice file when an arbitrary voice command is input in step (a) and transmitting the inputted voice command to a command analysis server;
Step (c) of determining whether the smart device is a valid command when it is received by determining whether a text command is received from the command analysis server; and
As a result of the determination in step (c), if it is a valid command, the operation control method of a portable signal analysis device comprising the step (d) of transmitting a corresponding text command to the signal analysis device to control the operation of the signal analysis device. The method according to claim 1,
As a result of the determination in step (c), if it is not a valid command, the operation control method of a portable signal analysis device, characterized in that it further comprises the step of (e) notifying the field agent that the recognition of the voice command has failed. The method according to claim 1 or 2,
The command analysis server automatically converts the voice file received in step (b) into text by ASR technology, analyzes the meaning of the text by NLU technology, and converts the meaning of the command in the voice file into text commands. A method of controlling the operation of a portable signal analysis device, characterized in that it is then transferred to a smart device.

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