JP5236427B2 - EMS - Google Patents

Description

  The present invention relates to an EMS in which a base station performs setting for wireless connection with a terminal to the base station.

  As a next-generation high-speed mobile communication system, WiMAX (Worldwide Interoperability for Microwave Access) attracts international attention, and introduction of a system using mobile IP in WiMAX has started.

  In this WiMAX, a large number of base stations to which terminals are wirelessly connected are installed. When installing this base station, it is necessary to set various parameters for each base station, and this setting is normally performed by EMS (Element Management System).

WiMAX FORUM “Recommendations and Requirements for WiMAX Network Management” June 26, 2008

  However, the parameter setting conditions of the base station differ depending on the base station depending on the number of wirelessly connected terminals, installation locations, and the like. Also, since there are many base stations to be set, the burden on the setter is large.

  The present invention has been made in consideration of the above-described problems, and an object of the present invention is to provide an EMS capable of easily setting base station parameters.

  The EMS according to the present invention is an EMS in which a base station sets a parameter for wireless connection with a terminal to the base station via a network, and the network starts from the base station activated when the power is turned on. A processing unit that performs processing based on a packet transmitted via the network, and the processing unit displays a setting screen for setting the parameter based on the packet. Thereby, the setting of the parameter of a base station can be performed easily.

  In addition, the packet includes a message indicating an operating state of the base station, a setting flag indicating a setting state of a parameter for the base station to wirelessly connect to the terminal, and an automatic operation when the base station is restarted. And an automatic wave break release flag for setting whether or not to allow easy radio wave transmission.

  Further, the processing unit shifts to a test mode in order to check the operating state of the base station after the parameter setting for the base station to establish a wireless connection with the terminal is completed.

  Furthermore, the processing unit returns the operating state of the base station to the activated state after power-on after the test mode is completed.

  According to the EMS of the present invention, the processing unit that performs processing based on the packet transmitted from the base station displays a setting screen for setting the base station based on the packet, thereby Parameters can be set easily.

  Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is an explanatory diagram of an EMS 10 according to an embodiment of the present invention and a base station 12 set by the EMS 10. FIG. 2 is an explanatory diagram of a setting of the base station 12 by the EMS 10.

  The EMS 10 is configured by a personal computer or the like, and sets parameters for the base station (BS) 12 to wirelessly connect to the terminal (MS) 14. The EMS 10 includes a processing unit 16 that mainly sets parameters of the base station 12, and a display unit 18 that displays a BS configuration screen 100, a BS control screen 200, and a test screen 300, which will be described later. The base station 12 is a wireless device for wirelessly communicating with the terminal 14, and the terminal 14 is a computer or a mobile phone having a communication function. The EMS 10 and the base station 12 are connected via a network 20 constituted by the Internet or a WAN.

  Next, parameter setting of the base station 12 by the EMS 10 will be described with reference to FIG.

  First, in the EMS 10, basic information such as the name, ID, and IP address of the base station 12 to be managed is registered (step S1), and the base station 12 is turned on and started (step S2). Then, the EMS 10 starts communication with the base station 12 (step S3). Packets are transmitted and received between the EMS 10 and the base station 12 through the network 20 at predetermined intervals, the operation state of the base station 12, the setting state of parameters for the base station 12 to wirelessly connect to the terminal 14, the base station 12 Is polled to confirm the transmission state of the radio wave transmitted to the terminal 14 (step S4). A packet transmitted from the base station 12 to the EMS 10 includes a message indicating the operation state of the base station 12, a setting flag indicating a parameter setting state for the base station 12 to wirelessly connect to the terminal 14, and the base station 12 is reset. An automatic wave break release flag for setting whether or not automatic radio wave transmission can be performed when activated is included.

  The processing unit 16 of the EMS 10 confirms the content of the packet, and when the setting flag is OFF, that is, when the base station 12 is not set to wirelessly connect to the terminal 14, the base station 12 communicates with the terminal 14 wirelessly. A BS configuration screen 100 for setting parameters for connection is displayed on the display unit 18 (step S5).

  FIG. 3 is an explanatory diagram of the BS configuration screen 100 displayed on the display unit 18. The BS configuration screen 100 is used for individually setting the BS common profile setting column 102 and the base station 12 which are parameter groups in which common values necessary for properly operating the base station 12 are set. A BS individual profile setting field 104 is provided. In the BS common profile setting field 102, a plurality of BS common profile files are set to be selectable. In the BS individual profile setting field 104, either a new BS individual profile file is created or, if a BS individual profile file has already been created, the BS individual profile file is imported. Input method selection field 106, BS individual profile file creation field 108 for creating individual BS profile files by individually selecting parameters such as frequency, File import field 110 for specifying BS individual profile files to be imported, BS individual A BS individual profile storage field 112 is provided for naming and saving the profile file.

  The BS individual profile file creation column 108 includes a “Frequency” setting column for setting a radio frequency transmitted by the base station 12, a “Tx Power” setting column for setting a radio output level transmitted by the base station 12, and a base station “Tx Antenna Gain” setting field for setting the gain of the transmitting antenna when 12 transmits, “Bs Info Individual Profile No” setting field for setting individual ID for the BS individual profile, and reception by the base station 12 "Rx Antenna Gain" setting field for setting the receiving antenna gain, and "UL Permutation Base" setting field for setting the upstream subcarrier assigned to the Zone, and setting the preamble to synchronize with the downstream frame Set the “DL preamble Id” setting field, the “Zone Index” selection field for selecting the index of the Zone table provided in the base station 12, and the number of segments for dividing the downlink subframe. “Segment Number” setting field, “DL Permutation Base” setting field for setting downlink subcarriers assigned to Zone, “Neighbor BS ID” for setting IDs of other base stations 12 adjacent to the base station 12 A setting column and a “Neighbor BS IP Address” setting column for setting an IP address of another base station 12 adjacent to the base station 12 are provided.

  The BS profile that is a parameter for the base station 12 to wirelessly connect to the terminal 14 is composed of a BS common profile and a BS individual profile file. A BS common profile is selected in the BS common profile setting field 102, and a BS individual profile file is created by the processing unit 16 when an operator inputs a parameter to the BS individual profile setting field 104, thereby creating a BS profile. (Step S6). Note that the BS individual profile file may be selected in the file import field 110 and imported by the operator without inputting the parameters and creating the BS individual profile file. Further, the created BS individual profile file may be given a name and saved by pressing the save button in the BS individual profile saving column 112, and may be an import target selected in the file import column 110.

  The created BS profile is transmitted to the base station 12 by pressing an OK button 114 set on the BS configuration screen 100 (step S7). Based on the transmitted BS profile, the BS profile of the base station 12 is transmitted. Various parameters are set (step S8).

  Further, polling is performed between the EMS 10 and the base station 12 (step S9), and the processing unit 16 of the EMS 10 confirms the content of the packet, and the setting flag is ON, that is, the parameter is set in the base station 12. If so, the BS configuration screen 100 is deleted (step S10). Next, the processing unit 16 causes the display unit 18 to display a BS control screen 200 that manages the start or stop of radio wave transmission from the base station 12 to the terminal 14 and the radio wave transmission test (step S11).

  FIG. 4 is an explanatory diagram of the BS control screen 200 displayed on the display unit 18. The BS control screen 200 includes a service mode selection field 202 for selecting a start of radio wave transmission from the base station 12 to the terminal 14, a stop (service) or a radio wave transmission test, and when the base station 12 is restarted. An automatic wave break release flag setting field 204 for setting whether or not automatic radio wave transmission is possible, a BS setting button 206 for calling the BS configuration screen 100 for resetting the BS profile, and an OK button 208 are set. ing.

  When starting transmission of radio waves from the base station 12 to the terminal 14, the operator selects “service” in the service mode selection column 202 to start transmission of radio waves, and sets an automatic stop cancellation flag setting column 204. Then, ON is selected, and transmission start data is created by the processing unit 16 (step S12). The transmission start data is transmitted to the base station 12 by pressing an OK button 208 set on the BS control screen 200 (step S13). Thereafter, polling is performed between the EMS 10 and the base station 12 (step S14), and a message indicating the operation state of the base station 12 included in the packet transmitted from the base station 12 to the EMS 10 is “service”. If this is confirmed, the BS control screen 200 is deleted (step S15). The base station 12 that has received the transmission start data transmitted from the EMS 10 starts transmission of radio waves to the terminal 14 (step S16), and the setting of the base station 12 by the EMS 10 ends.

  Note that the transmission start data created in step S12 is transmitted from the EMS 10 to the base station 12 in step S13, and the automatic wave break cancellation flag of the base station 12 is set to ON. When the automatic stop cancellation flag is set to ON, when the base station 12 is restarted for some reason, for example, due to a power failure due to lightning, during transmission of radio waves from the base station 12, radio waves are not transmitted from the base station 12. Sent. On the other hand, when the automatic stop cancellation flag is set to OFF, the radio wave is not transmitted from the base station 12 when the base station 12 is restarted.

  Next, the case of testing the base station 12 before starting transmission of radio waves from the base station 12 to the terminal 14 will be described with reference to FIG. FIG. 5 is an explanatory diagram of a test of the base station 12 by the EMS 10. Steps S1 to S11 are the same as those in FIG.

  After polling is performed between the EMS 10 and the base station 12 and the BS configuration screen 100 is erased, the BS control screen 200 is displayed on the display unit 18 (steps S9 to S11), and the operator “Test” is selected in the mode selection column 202 (step S15). When “test” is selected in the service mode selection column 202, “OFF” is automatically selected in the automatic wave break cancellation flag setting column 204.

  When “test” is selected in the service mode selection column 202 and the OK button 208 set on the BS control screen 200 is pressed (step S17), data indicating that the test mode is started is transmitted to the base station 12. When the message indicating the operation state of the base station 12 in the packet transmitted to the EMS 10 in response to the base station 12 is confirmed to be “test” (step S18), the BS control screen 200 is displayed. It is erased (step S19).

  Next, when a base station to be tested is selected from a plurality of base stations displayed on the Topology screen of a base station (not shown), a test screen 300 is displayed on the display unit 18 (step S20).

  FIG. 6 is an explanatory diagram of a test screen 300 displayed on the display unit 18. In the test screen 300, the base station 12 corresponds to a test of a plurality of transmission systems, a 1 system RF test selection field 302, a transmission output (1 system RF) setting field 304, a 2 system RF test selection field 306, a transmission output. A (2-system RF) setting field 308 is provided, and a frequency setting field 310 for setting a frequency, an Apply button 312, and a test end button 314 are further provided.

  In each of the 1-system RF test selection field 302 and the 2-system RF test selection field 306, transmission patterns of CW, burst communication, reception fixed, and loop mode are usually prepared, and a transmission output (1 system RF) setting field 304, The transmission output is set in the transmission output (2-system RF) setting field 308, and the transmission frequency is set in the frequency setting field 310.

  In the test of the base station 12 by the EMS 10, the operator selects a transmission system to be tested on the test screen. For example, when selecting one system, the transmission pattern is selected in the 1-system RF test selection field 302 and By setting the transmission output in the transmission output (1-system RF) setting column 304, test condition data is created by the processing unit 16 (step S21). The test condition data is transmitted to the base station 12 by pressing the Apply button 312 and the base station 12 shifts to the test mode. When it is confirmed that the base station 12 operates normally based on the test condition data, a response message is transmitted from the base station 12 to the EMS 10 (step S22).

  After confirming that the test at the base station 12 is normal, the operator presses the test end button 314 (step S23), and thereafter the test screen 300 is erased (step S24).

  After the test screen 300 is erased, it returns to the start-up state after power-on of the base station 12 in step S1 and immediately before step S5 in the EMS 10.

  As described above, the EMS 10 is an EMS in which the base station 12 performs setting for the base station 12 to wirelessly connect to the terminal 14, and performs processing based on the packet transmitted from the base station 12. The unit 16 is provided. The processing unit 16 can easily set the parameters of the base station 12 by displaying a setting screen for setting the base station 12 based on the packet.

  The packet includes a message indicating the operation state of the base station 12, a setting flag indicating a parameter setting state for the base station 12 to wirelessly connect to the terminal 14, and an automatic operation when the base station 12 is restarted. And an automatic wave break release flag for setting whether or not to allow easy radio wave transmission.

  Further, the processing unit 16 shifts to the test mode in order to check the operation state of the base station 12 after the setting of the parameters for the base station 12 to wirelessly connect to the terminal 14 is completed, and the processing unit 16 After the test mode is completed, the operating state of the base station 12 is returned to the activated state after the power is turned on.

  It should be noted that the present invention is not limited to the above-described embodiment, and various configurations can be adopted without departing from the gist of the present invention.

It is explanatory drawing of the base station set by EMS which concerns on embodiment of this invention, and the said EMS. It is explanatory drawing of the setting of the base station by EMS. It is explanatory drawing of the base station setting screen displayed on a display part. It is explanatory drawing of the base station management screen displayed on a display part. It is explanatory drawing of the test of the base station by EMS. It is explanatory drawing of the test screen displayed on a display part.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... EMS 12 ... Base station 14 ... Terminal 16 ... Processing part 18 ... Display part 20 ... Network 100 ... BS configuration screen 102 ... BS common profile setting column 104 ... BS individual profile setting column 106 ... Input method selection column 108 ... BS Individual profile file creation field 110 ... File import field 112 ... BS individual profile storage field 114, 208 ... OK button 200 ... BS control screen 202 ... Service mode selection field 204 ... Automatic stop cancellation flag setting field 206 ... BS setting button 300 ... Test screen 302 ... 1 system RF test selection field 304 ... Transmission output (1 system RF) setting field 306 ... 2 system RF test selection field 308 ... Transmission output (2 system RF) setting field 310 ... Frequency setting field 312 ... Apply button 314 ... Test end button

Claims (3)

An EMS for setting parameters for a base station to wirelessly connect to a terminal via the network to the base station,
A processing unit that performs processing based on a packet transmitted from the base station that is activated when the power is turned on via the network;
The packet is
A message representing the operating state of the base station;
A setting flag indicating a setting state of a parameter for the base station to wirelessly connect to the terminal;
An automatic wave break release flag for setting whether or not automatic radio wave transmission is possible when the base station is restarted,
The EMS, wherein the processing unit displays a setting screen for setting the parameter based on the packet. In claim 1 Symbol placement of EMS,
The processor is
After completing the setting of parameters for the base station to wirelessly connect to the terminal,
EMS characterized by shifting to test mode in order to confirm the operation state of the base station. In the EMS of claim 2 ,
The processor is
The EMS, wherein after the test mode ends, the operation state of the base station is returned to a startup state after power-on.

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