KR20100068937A - Method for expanding channel capacity and mobile telecommunication system for the same - Google Patents

Abstract

PURPOSE: A method for expanding channel capacity and a mobile telecommunication system for the same are provided to expand the capacitance of a wireless channel by sharing channel occupation information between a base station and a terminal. CONSTITUTION: A base station(30) receives a channel occupation failure message, and transmits to an adjacent base station a handover guide message which requests the information on whether or not handover is possible. In response to the handover guide message, the base station receives the handover enable message from the first and/or second terminals. The base station hands over the response terminal to the adjacent base station.

Description

Channel Capacity Expansion Method and Mobile Communication System for It {METHOD FOR EXPANDING CHANNEL CAPACITY AND MOBILE TELECOMMUNICATION SYSTEM FOR THE SAME}

The present invention relates to a mobile communication system, and more particularly, to a channel capacity expansion method and a mobile communication system for expanding a wireless channel (especially a call channel) capacity by exchanging channel occupancy information between a base station and a terminal. .

Digital Enhanced Cordless Telecommunication (DECT) is a digital cordless communication technology mainly used in Europe. It is a home DECT system used in homes and a private exchange that can accommodate a large number of users in an office. / PBX) DECT system.

The DECT system for a private exchange consists of an IP keyphone device (KTS / PBX), at least one base station (BS), and a plurality of handsets (DECT terminals) that communicate wirelessly with the base station. TDMA (Time Division Multiple Access) is used for access multiplexing between networks, and TDD (Time Division Duplex) is used as a duplexing scheme.

Looking at the frame structure according to the DECT protocol, one frame includes 24 time slots. 12 timeslots out of 24 timeslots are downlink intervals for the base station to transmit data to the terminal, and the remaining 12 timeslots are uplink for the terminal to transmit data to the base station. It is a section. Thus, an uplink or downlink radio channel can use up to 12 timeslots as a radio channel physically per frequency.

The terminal searches for RSSI (Received Signal Strength Indication) of the timeslot to which the terminal intends to occupy. At this time, the RSSI search is performed in odd-numbered timeslots, and the odd-numbered timeslots are called blind slots. The UE takes a long time to search for the RSSI in advance and does not use an odd timeslot named as a blind slot. Therefore, actually available wireless channels are six timeslots per frequency, and the terminal selects a specific timeslot determined to be an unused timeslot and uses it as a wireless channel.

However, the base station periodically transmits dummy bearer information to the terminal for synchronization information with the terminal, identification information (ID information) of the base station to which the terminal can access, and paging signal transmission for the terminal call. The base station always occupies one radio channel per frequency in order to transmit dummy bearer information. Occupancy of the timeslot for transmitting the dummy bearer information of the base station reduces the available radio channel to be used by the actual terminal. Therefore, a radio channel that can be provided per frequency in a radio cell coverage area of one specific base station is a maximum of 5 timeslots.

DECT systems for private exchanges must provide voice calls to multiple users in environments such as offices. However, if the number of simultaneous calls that the base station can handle per frequency is limited to five calls (up to five timeslots), and five terminals occupy the radio channel within the cell coverage of the same base station. From the remaining sixth terminal, there is a problem in that it cannot occupy the wireless channel until the call of the terminal in the call ends. For example, when six terminals (terminals # 1 to terminal # 6) are located in the cell coverage of the base station # 1 and the terminals # 1 to terminal # 5 are all in a call as shown in FIG. 1, the terminal # 6 is the terminal # 1 to the terminal. At least one of # 5 may not be able to answer the incoming call and the incoming call until the call is terminated and an available wireless channel is created.

An object of the present invention is to provide a channel capacity expansion method and a mobile communication system therefor that can expand radio channel (especially call channel) capacity by exchanging channel occupation information between a base station and a terminal.

According to an aspect of the present invention, a channel capacity expansion method capable of expanding channel capacity and a mobile communication system therefor are disclosed. According to this method, a base station receives a channel occupancy failure message from a first terminal not occupying a channel, and transmits a channel occupancy failure message to at least one second terminal currently occupying a channel or to a second terminal including the first terminal, the neighboring base station. Sends a handover induction message requesting whether handover is possible. Upon receiving a handover capable message from at least one of the first and second terminals in response to the handover induction message, the base station hands over the responding terminal to the neighbor base station. The mobile communication system includes: a first terminal not occupying a channel; At least one second terminal currently occupying a channel; And upon receiving the channel occupancy failure message from the first terminal, transmits a handover induction message requesting whether a handover is possible to the neighboring base station to the second terminal or the second terminal including the first terminal, And receiving a handover capable message from at least one response terminal among the first and second terminals in response to the over induction message, and including the base station for handing over the response terminal to the neighbor base station.

According to the present invention, when the base station can no longer provide a communication channel to the terminal, the base station and the terminal in the overlapping area by inducing a handover to the neighboring base station, the advantage that can extend the simultaneous call channel capacity of the terminal have.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description, well-known functions or constructions will not be described in detail if they obscure the subject matter of the present invention.

2 is a diagram schematically illustrating a configuration of a DECT system according to an embodiment of the present invention.

Referring to FIG. 2, the DECT system includes an IP keyphone device 10, a wireless terminal interface board (WTIB) 20, a base station (BS) 30, and a terminal (DECT terminal) 40.

The IP keyphone device 10 has an internal switching for extension calls between the terminals 40 and the terminal 40 is connected to an external network such as an Integrated Services Digital Network (ISDN) 1 and a Public Switched Telephone Network (PSTN) 2. It enables access and provides DECT service.

The WTIB 20 is a board for interfacing the base station 30 with the IP keyphone device 10. The WTIB 20 collects signals transmitted from the plurality of base stations 30 at regular intervals and transmits the signals to the IP keyphone device 10, and transmits the signals (for example, 2.048 Mbps) transmitted from the IP keyphone device 10 to each base station ( 30 is converted into a receivable signal (eg, 64 kbps) and transmitted to the corresponding base station 30. An incoming call to the terminal 40 received by the IP keyphone device 10 via the ISDN 1 or the PSTN 2 is transmitted to the base station 30 through the WTIB 20 and an outgoing signal from the terminal 40. Is transmitted to the ISDN 1 or the PSTN 2 via the IP keyphone device 10 through the base station 30 and the WTIB 20.

The DECT system uses a time division multiple access (TDMA) scheme for access multiplexing between the base station 30 and the plurality of terminals 40, and the base station 30 and the terminal 40 form a plurality of times that constitute a frame in communication. One of the slots is selected as a wireless channel to transmit and receive a signal through the corresponding wireless channel.

3 shows a DECT frame structure for transmitting and receiving signals between the base station 30 and the plurality of terminals 40.

One DECT frame includes 24 timeslots. A timeslot refers to a data group determined for temporal division such as character-to-character, character-group, and channel-to-channel data. Generally, individual timeslots are assigned to individual timeslots. Twelve timeslots (eg, timeslots 0-11) of the 24 timeslots (channels) are downlink intervals for the base station 30 to transmit data to the terminal 40, and the remaining 12 timeslots. For example, timeslots 12 to 23 are uplink intervals for the terminal 40 to transmit data to the base station 30. Thus, uplink or downlink radio channels use up to 12 radio channels per frequency.

The terminal 40 searches in advance the RSSI of the corresponding timeslot that it can occupy. The RSSI search is performed in odd-numbered timeslots and does not use odd-numbered timeslots, which are called blind slots. The terminal 40 selects one of the even-numbered timeslots, which is not occupied by the other terminal 40 (ie, unused timeslots), and uses it as a wireless channel. In one embodiment, one DECT frame is 10 ms long and consists of 24 timeslots. Since the DECT system uses a time division duplex (TDD) scheme as a duplexing scheme, 12 timeslots of 24 timeslots are used as a wireless channel for downlink transmission (for example, timeslots 0 to 11), and the remaining 12 Use timeslots as radio channels for uplink transmissions (eg timeslots 12-23). Odd-numbered timeslots (e.g. timeslots 1,3,5,7,9,11,13,15,17,19,21,23) in uplink and downlink radio channels are used for RSSI discovery (blind Slots), even-numbered timeslots of the downlink channel (e.g. timeslots 0,2,4,6,8,10) and even-numbered timeslots of the uplink channel (e.g. timeslots 12,14,16,18, 20,22 are used as available wireless channels. In communication between the base station 30 and the terminal 40, the base station 30 transmits voice or / and data to the terminal 40 through the downlink channel, and the terminal 40 transmits the base station 30 through the uplink channel. Transmit voice or data.

One of the even-numbered timeslots (eg, timeslots 0, 2, 4, 6, 8, 10) of the downlink channel is used by the base station 30 to broadcast the dummy bearer information to the terminal 40. In one embodiment, timeslot 0 is used to transmit dummy bearer information. The dummy bearer information includes synchronization information with the terminal 40, ID information of the base station 30 to which the terminal 40 can be connected, a paging signal for calling the terminal 40, and message exchange with the terminal 40. As a signal including information, the base station 30 periodically broadcasts to the terminal 40 every frame (10 ms). For example, the terminal # 1 40A synchronizes with the base station # 1 30A by using the dummy bearer information broadcasted by the base station # 1 30A at a predetermined period (10 ms), and the ID information of the base station # 1 30A. Attempt to make a call by confirming the access authority, or the like and remain in the standby mode until the call is made from the base station # 1 30A. When UE # 1 40A in the idle mode receives the dummy bearer information and recognizes that it is called, UE # 1 40A receives an unused time out of even-numbered timeslots of the uplink channel every frame (10ms). It occupies one of the slots (time slots 2, 4, 6, 8, 10 except time slot 0) and transmits a call response signal to the base station # 1 30A through the corresponding wireless channel. In an embodiment, the terminal # 1 40A uses timeslot 2 as a wireless channel. In addition, the remaining terminals # 2 to # 5 (40B to 40E) may use timeslots 4, 6, and 8 as wireless channels, respectively. However, when the terminals # 1 to terminal # 5 (40A to 40E) occupy all the radio channels, at least one of the terminals # 1 to terminal # 5 (40A to 40E) ends from the terminal # 6 (40F). It must wait until an available wireless channel is created. This is because the blind slot type DECT base station 30 is limited to five simultaneous call radio channels that each of the terminal 40 can provide. In one embodiment, when base station # 1 30A no longer provides a call radio channel, base station # 1 30A is adjacent to a terminal (eg, 40A) in an overlapping area with neighbor base station # 2 30B. # 2 (30B) induces inter-cell handover to extend the simultaneous call radio channel.

4 is a flowchart illustrating a channel capacity expansion process according to an embodiment of the present invention. 5 is an explanatory view showing a radio channel operating method of the DECT system according to an embodiment of the present invention.

In the present invention, the handover is performed when the serving base station ((base station # 1) 30A) to which terminals # 1 to 5 (40A to 40E) are currently communicating can no longer provide a call radio channel. A terminal (for example, 40A) in an overlapping area with a neighboring base station establishes a communication path (base station ↔ terminal communication path) at the serving base station 30A to a target base station (one of the neighboring base stations (here, base station # 2 (30B))). Means to change. In addition, when the terminal # 6 (40F) that failed to occupy the channel exists in the overlapping area, the terminal # 6 (40F) includes switching the base station to the base station # 2 (30B). Hereinafter, base station # 1 30A is referred to as a 'serving base station' of terminals # 1 to 5 (40A to 40E), and base station # 2 30B is referred to as a 'target base station' of terminal # 1 40A.

If the terminal # 6 40F attempts to occupy the channel for the outgoing call and the channel occupancy fails because there is no available wireless channel of the base station # 1 30A, the terminal # 6 40F may occupy the base station # 1 30A. A channel occupancy failure message (NO_CHANNEL_IND) indicating that there is no channel is transmitted (401). In one embodiment, the channel occupancy failure message is sent over the uplink interval (eg, timeslot 12) of the dummy bearer channel.

If the serving base station 30A receives the channel occupancy failure message from the terminal # 6 40F, whether the serving base station 30A can handover to the neighboring base station # 2 30B neighboring the terminals # 1 to 5 (40A to 40E) currently occupying the channel. A handover induction message (HANDOVER_IND) requesting whether or not is transmitted (402,404). In this case, the handover induction message may be transmitted only to the terminals # 1 to 5 (40A to 40E) that currently occupy the channel of the serving base station 30A, or may be transmitted to the terminal # 6 (40F) that have failed to occupy the channel. .

Upon receiving the handover induction message from the serving base station 30A, the terminals # 1 to 5 (40A to 40E) or the terminals # 1 to 6 (40A to 40F) determine whether there is a neighboring base station at its corresponding location. Looking at the neighbor base station discovery process, the serving base station 30A is a neighbor advertisement message (Neighbor Advertisement) message that informs the neighbor BS information for handover of the terminal 40 (network attribute for the serving base station and neighbor base stations) Is broadcasted periodically by the serving base station). Accordingly, the terminals # 1 to 5 (40A to 40E) or the terminals # 1 to 6 (40A to 40F) may perform a task of scanning neighboring base stations and thus may know signal strengths of neighboring base stations. Since the neighbor base station discovery process may be performed according to a known technique, a detailed description thereof will be omitted.

After searching for neighboring base stations, the terminals # 2 to 5 (40B to 40E) or the terminals # 2 to 6 (40B to 40F) do not have neighboring neighboring base stations (when the signal strength of the neighboring base station is less than or equal to the handover threshold). In response to the handover inducing message, 30A), a handover impossible message (HANDOVER_NOK) is transmitted (403).

However, since terminal # 1 40A has a neighboring neighboring base station (when the signal strength of the neighboring base station is greater than or equal to the handover threshold), it is determined whether handover is possible to neighboring base station # 2 (which becomes the target base station) 30B. The handover request message (HANDOVER_REQ) is sent (405). In the neighboring base station # 2 30B, as shown in FIG. 5, three terminals # 7 to 9 (30G to 30I) are currently occupying a radio channel, and two available radio channels remain.

Upon receiving the handover request message, the target base station 30B checks whether there is an available wireless channel and transmits a handover confirmation message (HANDOVER_CFM) indicating whether the available wireless channel is available to the terminal # 1 40A (406).

Upon receiving the handover confirmation message from the target base station 30B, the terminal # 1 40A confirms that there is an available wireless channel in the target base station 30B through the handover confirmation message and then sends a handover induction message to the serving base station 30A. In response to the handover possible message (HANDOVER_OK) is transmitted (407). The terminal # 1 40A transmits a channel occupation request message CONNECT_REQ to the target base station 30B for channel occupancy for inter-cell handover (step 408). In response to this, the target base station 30B transmits a channel occupation confirmation message (CONNECT_CFM) for allowing channel occupancy to the terminal # 1 40A (409). As a result, the terminal # 1 40A occupies an available radio channel of the target base station 30B.

In addition, the terminal # 1 40A transmits an occupied channel release request message RELEASE_REQ to the serving base station 30A for channel release previously occupied by the serving base station 30A (410). 30A) transmits an occupation channel release confirmation message (RELEASE_CFM) to allow the release of the occupation channel to the terminal # 1 40A (411).

The terminal # 1 40A releases the channel occupied by the serving base station 30A and performs an inter-cell handover operation between cells moving to the wireless channel of the newly occupied target base station 30B as shown in FIG. 5. Perform 412. Since the handover process between cells can be performed according to a known technique, a detailed description thereof will be omitted. The serving base station of terminal # 1 40A is now base station # 2 30B.

The base station # 1 30A, in which one available wireless channel is generated by releasing the occupied channel of the terminal # 1 40A, transmits a channel occupancy permission message CONNECT_IND to allow the terminal # 6 40F to occupy the channel (413). .

Upon receiving the channel occupancy permission message from the base station # 1 30A, the terminal # 6 40F transmits a channel occupancy request message CONNECT_REQ to the base station # 1 30A for channel occupancy (414). The base station # 1 30A, which has received the channel occupation request from 40F, transmits a channel occupation confirmation message CONNECT_CFM to the terminal # 6 40F (415). Upon receiving the channel occupancy confirmation message from the serving base station 30A, the terminal # 6 40F occupies the radio channel of the base station # 1 30A as shown in FIG. Base station # 1 30A is now a 'serving base station' of terminals # 2 through 6 (40B through 40F).

In the above, when the channel occupancy failure message is received from the terminal # 6 40F which has failed to occupy the channel when the base station # 1 30A does not have an available wireless channel, the terminals # 1 to 5 (40A to 40E) currently occupying the channel. Alternatively, a handover induction message is transmitted to the terminals # 1 to 5 (40A to 40E) currently occupying the channel, including the terminal # 6 (40F) that has failed to occupy the channel, and the terminal # 1 (40A) located in the base station overlap region. After handing over to the base station # 2 30B, the process of releasing the radio channel occupied by the terminal # 1 40A and allocating an available radio channel due to channel release to the terminal # 6 40F has been described. However, when the terminal # 6 (40F) is in the overlapping area, the occupied channel release process of the terminals # 1-5 (40A-40E) is not necessary. In this case, the base station # 6 40F can be switched to the base station # 2 30B.

Although the present invention has been described in connection with some embodiments thereof, it should be understood that various changes and modifications may be made therein without departing from the spirit and scope of the invention as understood by those skilled in the art. something to do. It is also contemplated that such variations and modifications are within the scope of the claims appended hereto.

1 is an explanatory diagram showing a wireless channel operating method of the DECT system according to the prior art.

2 is a diagram schematically showing the configuration of a DECT system according to an embodiment of the present invention;

3 is a diagram illustrating a DECT frame structure for transmitting and receiving signals between a DECT base station and a terminal of FIG. 2;

4 is a flowchart illustrating a channel capacity expansion process according to an embodiment of the present invention.

5 is an explanatory diagram showing a radio channel operating method of a DECT system according to an embodiment of the present invention;

* Explanation of symbols for the main parts of the drawings

10: IP Keyphone Device 20: Wireless Terminal Interface Board (WTIB)

30: base station 40: terminal

Claims (11)

A channel capacity expansion method of a mobile communication base station, a) receiving a channel occupancy failure message from a first terminal not occupying a channel; b) transmitting, to at least one second terminal occupying the current channel or to the second terminal including the first terminal, a handover induction message requesting whether handover is possible to an adjacent base station; And c) when the handover capable message is received from at least one response terminal of the first and second terminals in response to the handover induction message, handing over the response terminal to an adjacent base station. . The method of claim 1, The channel occupancy failure message is transmitted through an uplink period of a dummy bearer channel. The method according to claim 1 or 2, And the responding terminal is at least one terminal of the second terminal. The method of claim 3, In step c), And receiving the handover enabled message from the answering terminal, releasing a channel occupied by the answering terminal, and allocating an available channel due to releasing the occupied channel of the answering terminal to the first terminal. The method according to claim 1 or 2, And the responding terminal is the first terminal. The method of claim 5, In step c), And receiving the handover enabled message from the first terminal, converting the first terminal to a base station from a neighboring base station. The method of claim 4, wherein C), c1) determining whether the first and second terminals or the second terminal is an adjacent base station; c2) transmitting a non-handover message to the base station by a terminal other than the response terminal; c3) the base station receiving the handover enabled message from the answering terminal and releasing a channel occupied by the answering terminal according to the occupied channel release request from the answering terminal; c4) the base station transmitting a channel occupancy grant message to the first terminal; And c5) in response to the channel occupation request from the first terminal, the base station transmitting a channel occupation confirmation message to the first terminal. The method of claim 7, wherein Step c3), When the answering terminal transmits a handover request message to the neighboring base station and receives a handover confirmation message from the neighboring base station, transmitting the handover enabled message to the base station; Transmitting, by the responding terminal, a channel occupancy request message to the neighbor base station and receiving a channel occupancy confirmation message from the neighbor base station; And And transmitting, by the base station, an occupied channel release confirmation message to the responding terminal in response to the occupied channel release request message. As a mobile communication system, A first terminal not occupying a channel; At least one second terminal currently occupying a channel; And When the channel occupancy failure message is received from the first terminal, a handover induction message is transmitted to the second terminal or the second terminal including the first terminal, requesting whether handover is possible to an adjacent base station. And a base station for handing over the response terminal to an adjacent base station when receiving a handover capable message from at least one response terminal of the first and second terminals in response to the handover induction message. 10. The method of claim 9, When the answering terminal is at least one of the second terminals, the base station releases the channel occupied by the answering terminal when receiving the handover enabled message from the answering terminal, and occupies the channel occupied by the answering terminal. Assigns an available channel due to the release to the first terminal, And when the answering terminal is the first terminal, the base station switches the first terminal to a base station when the handover available message is received from the first terminal. The method of claim 10, When the answering terminal is at least one of the second terminals, the base station receives a handover impossible message from a terminal except the answering terminal, receives the handover possible message from the answering terminal, and the response. A channel occupied by the response terminal is released according to the occupied channel release request from the terminal, and a channel occupancy permission message is transmitted to the first terminal to transmit the channel to the first terminal according to the channel occupancy request from the first terminal. A mobile communication system for transmitting an occupancy confirmation message.

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