KR100965083B1 - Apparatus and method for down-link power control for preventing up-link failure in mobile telecommunication system - Google Patents

Abstract

The present invention relates to a downlink power control apparatus and method for preventing uplink failure in a mobile communication system. By increasing the downlink transmission power of the base station, it is possible to enable the mobile terminal to quickly exit the transmission interruption state due to the deterioration of the downlink, thereby reducing the call disconnection due to the uplink failure.

To this end, the present invention is a device for controlling the power of the downlink to prevent uplink failure in a mobile communication system, comprising: reverse signal receiving means for receiving a reverse signal transmitted from a mobile terminal; Terminal state analysis means for confirming a transmission state of the mobile terminal through the power of the received reverse signal; And a power control means for increasing downlink transmission power to the mobile terminal when the mobile terminal is in a transmission stop state.

Mobile communication, power control, downlink, terminal transmission status, transmission interruption status

Description

Downlink power control device and method for preventing uplink failure in mobile communication system {APPARATUS AND METHOD FOR DOWN-LINK POWER CONTROL FOR PREVENTING UP-LINK FAILURE IN MOBILE TELECOMMUNICATION SYSTEM}

The present invention relates to a power control apparatus and a method thereof in a mobile communication system, and more particularly, to enable a mobile terminal to quickly escape from a transmission interruption state (Tx_off) due to a deterioration of a downlink, and thus to the uplink radio. The present invention relates to a downlink power control apparatus and method for preventing uplink failure in a mobile communication system, which can reduce call disconnection due to a link failure.

A dedicated physical channel (hereinafter referred to as "DPCH") synchronization provided by 3rd generation partnership project (3GPP) TS.214 will be described.

The mobile terminal and the WCDMA system transmit a DPCH calculated by Open Loop Power Control, and after measuring a signal-to-interference ratio (SIR) of this power, If it is, the synchronization is acquired.

This synchronization acquisition method is a basic procedure in all coherent communication methods, and may be classified into an acquisition procedure in a 'mobile terminal' and an acquisition procedure in a 'WCDMA system'.

First, a downlink synchronization acquisition procedure in a 'mobile terminal' will be described.

The first phase (1 ^st phase) begins with the higher layers setting up the dedicated physical channel and ends 160 ms after the dedicated physical channel is established.

Looking at the criteria of this physical channel setting, if the physical dedicated channel establishment is initiated by the user terminal (UE), the user terminal (UE) starts timer T312 and N312 in-sync from L1 Wait for the in_synch_indicator to occur. Here, the in-sync indicator (in_synch_indicator) occurs when the Dedicated Physical Control Channel (hereinafter, referred to as “DPCCH”) quality is better than Q _{in for the} last 40 ms.

If the N312 in-sync indicator (in_synch_indicator) is not received until the timer T312 expires, the user terminal UE considers that the physical channel setup has failed. Otherwise, when receiving the N312 in-sync indicator (in_synch_indicator), the physical channel is considered to be set, and the timer T312 is stopped and reset.

In this step, the L1 of the UE does not generate an out-of-sync indicator (out_of_synch_indicator).

On the other hand, the second phase (2 ^st phase) starts when 160ms have elapsed since the dedicated physical channel is established, and look at the "out_of_synch" reporting criteria, the quality of the DL DPCCH for the last 160ms is worse than Q _out , or not Out-of-sync indicator (out_of_synch_indicator) when all 20 recently received transport blocks for all transport channels using non-zero length cyclic redundancy check (CRC) are incorrect CRC ).

Looking at the in_synch reporting criteria, the quality of the downlink (DL) DPCCH for the last 160ms is better than Q _in and at least one for all transport channels using non-zero length CRC. Generates an in-sync indicator when the transport block of is received at the end of the TTI with an incorrect CRC.

Looking at the Radio Link Failure criterion in 25.331, we run T313, which would have generated as many N313 out-of-synch out of Layer 1 as in the Cell_DCH state, and T313 terminated. After RL failure occurs, the mobile terminal releases all physical resources and transmits a cell update to the WCDMA system. If T313 receives in-sync (In_synch) consecutively from N315 while N313 is running, it terminates the running T313.

Hereinafter, a procedure for acquiring UL synchronization in 'Node B' will be described.

Synchronization Primitives for Dedicated Channels indicate the synchronization status of the radio links. Of the criteria for in_synch / out_of_synch_primitive, it is specified in the specification (3GPP TS 25.214) for downlink (DL), but the exact criteria for uplink (UL) are not specified. not. In most manufacturers, each in-sync indicator (in_synch_indicator) has a pilot bit energy of DPCCH and uplink data transmitted from a mobile terminal, and compares it with a threshold determined in a WCDMA system with a performance of CRC of data. ) And out-of-sync indicators.

3GPP TS 25.214 only stipulates that L1 of Node B should check the synchronization status for all Radio Link Sets every Radio Frame period (e.g. 10ms). Is left as an implementation issue.

Hereinafter, a general transmission power control pattern TPC01 will be described.

After receiving the RRC connection setup message (RRC connection setup MSG) from the mobile station, the mobile station performs a DL synchronization procedure and then initializes an initial DPCCH through an open loop power control algorithm. The power is calculated and transmitted to the base station at that power.

If the base station fails to acquire UL synch due to insufficient power of the DPCCH, the base station makes a request for power increase to the mobile terminal using the TPC01 pattern. Currently, DL power control mode of WCDMA is divided into two types, and power control is performed by transmitting TPC bits downlink in every slot or every 3 slots. For example, if the TPC01 pattern is set to "5" and the base station fails to acquire UL synch, the Power Control Bit is changed to "01 01 01 01 01 1". After transmitting five "01" patterns, it sends a "1" at the end to increase the power of the mobile terminal. Here, "0" means power down and "1" means power up.

If uplink synchronization (UL synch) cannot be obtained even when the transmission power of the mobile station is increased according to the TPC power control of the base station, the power control process is repeated to eventually acquire the uplink synchronization from the base station. .

The foregoing has described the downlink (DL) synchronization acquisition procedure and the uplink (UL) synchronization acquisition procedure, among which an uplink (UL) synchronization failure (ie, an UL radio link failure). Looking at the occurrence of, can be divided into the following two cases.

The first is when the power transmitted by the mobile terminal causes uplink (UL) out-of-sync, which causes the radio link failure time to expire, resulting in radio link failure. The second case is a case where the downlink signal quality is deteriorated and a transmission interruption state (Tx_off) occurs in the mobile terminal, which causes the uplink to fail.

In particular, in the second case, there is no transmission of an uplink pilot signal (reverse pilot signal) because the mobile terminal is in a transmission stop state, which causes the base station to stop responding and eventually fails to establish a radio uplink. There is a problem that the call (call) of the mobile terminal is disconnected occurs.

In order to prevent such a call disconnection phenomenon, the mobile terminal should be induced to quickly exit the transmission interruption state.

In the prior art as described above, when the mobile station is in the transmission stop state (Tx_off) due to deterioration of the downlink, a call drop occurs due to a failure of the uplink radio link. It is a subject of the present invention.

The objects of the present invention are not limited to the above-mentioned objects, and other objects and advantages of the present invention which are not mentioned can be understood by the following description, and will be more clearly understood by the embodiments of the present invention. Also, it will be readily appreciated that the objects and advantages of the present invention may be realized by the means and combinations thereof indicated in the claims.

In order to solve the above object, the present invention checks the transmission state of the mobile terminal through power detection of the reverse pilot signal, and increases the downlink transmission power of the base station when the mobile terminal is in the transmission stop state (Tx_off). It is done.

More particularly, the present invention provides an apparatus for controlling downlink power to prevent uplink failure in a mobile communication system, comprising: reverse signal receiving means for receiving a reverse signal transmitted from a mobile terminal; A terminal state analysis step for confirming a transmission state of the mobile terminal through the power of the received reverse signal; And power control means for increasing downlink transmission power to the mobile terminal when the mobile terminal is in a transmission stop state.

In addition, the present invention, in the method for controlling the power of the downlink in order to prevent the uplink failure in the mobile communication system, the terminal transmission status checking step of confirming the transmission status of the mobile terminal by detecting the power of the received reverse signal ; And a power control step of increasing downlink transmission power to the mobile terminal when the mobile terminal is in a transmission stop state.

As described above, the present invention checks the transmission state of the mobile terminal through power detection of the direction pilot signal, and controls the downlink (DL) transmission power of the base station to control the downlink (DL) transmission power when the mobile terminal is in the transmission stop state. It is possible to quickly exit the transmission interruption state due to the link deterioration, and also to prevent the call disconnection due to the uplink (UL) failure of the mobile terminal.

The foregoing and other objects, features and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings, in which: There will be. In addition, in describing the present invention, when it is determined that the detailed description of the known technology related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a diagram illustrating a network configuration of a mobile communication system to which the present invention is applied and schematically illustrates a configuration of a general packet radio service (GPRS) network.

The network to which the present invention is applied includes 2G (Global System for Mobile Communications) GSM (Radio Access) networks, 2.5G GSM and Code Division Multiple Access (CDMA) networks, 3G UMTS (Universal Mobile) Telephone system and wideband code division multiple access (WCDMA) networks, other communication networks, and combinations of such networks. Since these networks are generally known, further description will be omitted. In particular, an embodiment of the present invention will be described on behalf of the case that the base station is a UMTS Terrestrial Radio Access Network (UTRAN) of the UMTS network.

As illustrated in FIG. 1, the mobile communication system 12 includes a Node B 121, a Radio Network Controller (hereinafter referred to as "RNC") 122, and a packet switching device (Serving GPRS Support Node). : "SGSN" 123, and a packet gateway device (Gateway GPRS Support Node: GGSN) 124).

The mobile communication network shown in FIG. 1 is a network structure that complies with the general standard, and the Node-B 121 and the RNC 122 are provided in a wireless section that can guarantee free space movement of the mobile terminal (MS) 10. In general, a wired interval GPRS (General Packet Radio Services) internal network 'SGSN' 123 to select a specific GGSN among a plurality of GGSN 124 and act as a switch, an external packet network (PDN: Public Data Network) 'GGSN' (124) serving as a gateway of the user), SGSN (123) for managing the location information of the user's mobile terminal 10, and the like.

Here, the Node-B 121 and the RNC 122 correspond to a radio access network area. In this radio access network area, the Node-B 121 and the RNC 122 efficiently use limited radio resources to provide high-speed packet data services and provide various QoS of a multimedia system. (Quality of Service) Performs the function that satisfies the requirements.

The SGSN 123 and the GGSN 124 correspond to a packet switched core network, and provide IP based protocol interworking for accessing an existing Internet network to receive a subscriber mobile terminal 10 packet switched service.

In addition, the mobile communication system 12 may provide an AAA server for authentication / authorization / billing of a service subscriber to provide additional services, and DHCP (Dynamic) for providing a dynamic IP of an operator in addition to a static IP (Internet Protocol) for packet services. Host Configuration Protocol) server and the like.

By the interaction of the network components (component nodes) as described above, the mobile terminal 10 of the service subscriber can access various Internet servers connected to an external network. In particular, since the present invention relates to power control between the mobile terminal 10 and the Node B 121 corresponding to the base station, other components will not be described.

FIG. 2 is an explanatory diagram for switching the transmission state in the mobile terminal, in particular, showing the transmission interruption state (Tx_off) of the mobile terminal.

Judging from the quality of the DPCCH, if the quality of the DPCCH deteriorates below Q _out and the state is maintained for a predetermined time T _off , the mobile terminal enters the transmission stop state (Tx_off). That is, since the mobile terminal does not transmit the reverse signal (uplink signal), only a simple noise level is detected at the base station.

Then, if the quality (Quality) for the DPCCH rises above Q _in and this state is maintained for a predetermined time (T _on ), the state is switched back to the state (Tx_on) that can transmit the reverse signal (upward signal).

The present invention relates to a power control method for increasing the downlink transmission power of a base station so that the mobile terminal switches from the transmission interruption state (Tx_off) to the state (Tx_on) that can be transmitted quickly.

3 is a block diagram of an apparatus for controlling downlink power in order to prevent uplink failure in a mobile communication system according to an embodiment of the present invention.

As shown in FIG. 3, the power control device 30 according to the present invention includes a reverse signal receiver 31, a terminal state analyzer 32, and a power controller 33. It may be included in the base station (node B) 121 of. Each component is described as follows.

When the reverse signal receiver 31 receives the reverse signal (reverse pilot signal or reverse DPCCH signal) transmitted by the mobile terminal, the terminal state analyzer 32 transmits the mobile terminal through the power of the received reverse pilot signal. Check the status (Tx_on or Tx_off).

Thereafter, the power control unit 33 performs power control according to the analysis result of the terminal state analysis unit 32. That is, the power control unit 33 increases the downlink transmission power according to a predetermined power control pattern when the mobile terminal is in the transmission stop state Tx_off. Then, the mobile terminal gradually increases the power (uplink transmission power) of the reverse signal according to the power of the downlink. Through this process, the mobile terminal eventually exits the transmission interruption state.

4 is a flowchart illustrating a method of controlling power of a downlink to prevent uplink failure in a mobile communication system according to an embodiment of the present invention, which is performed by the power control apparatus 30 as shown in FIG. The power control method is shown.

First, the power control method according to the present invention will be described generally with reference to FIG. 4.

A reverse signal (for example, a reverse pilot signal or a reverse DPCCH signal) transmitted by the mobile terminal is monitored (400) to confirm whether the reverse pilot signal is detected (402).

When the reverse pilot signal is detected as a result of checking in step 402, since the mobile terminal is in a transmittable state, a normal power control process is performed (404). Here, the normal power control refers to inner loop power control and outer loop power control.

In contrast, when it is confirmed that the reverse pilot signal is not detected, the power control device 30 operates the timer 406 to confirm whether the undetected state of the reverse pilot signal is maintained for a predetermined time (408). This is to exclude the undetected state temporarily generated due to the deterioration of the wireless channel, and to search only the undetected state caused by the transmission stop state of the mobile terminal.

As a result of checking in step 408, if the undetected state of the reverse pilot signal is not maintained for a predetermined time, in this case, since the mobile terminal is in a transmittable state (Tx_on), a normal power control process is performed (404). ).

On the contrary, if the undetected state of the reverse pilot signal is maintained for a predetermined time, in this case, the mobile terminal is in the transmission stop state (Tx_off). Downlink transmission power) is increased step by step (410). At this time, the power should be increased so as not to deviate from the maximum code power value defined for each bearer.

Hereinafter, the power control method according to the present invention described with reference to FIG. 4 will be described in more detail.

First, a DL synchronization acquisition complementary algorithm (a first control method) using a “TPC01” pattern among transmission power control patterns will be described.

When the mobile terminal has a dedicated channel (DCH), it transmits a dedicated physical control channel (DPCCH) and a dedicated physical data channel (DPDCH) to the WCDMA system. In this case, since the mobile terminal is configured to transmit the DPCCH at all times, if the base station misses synch, the above two cases (induced by the transmission power of the mobile terminal, caused by the deterioration of the downlink signal quality) ) Can be determined as one of

The present invention is to prevent the transmission interruption state (Tx_off) of the mobile terminal of the above two cases, if it is possible to eliminate the transmission interruption state of the mobile terminal, this is the call disconnection due to the radio link failure (Call drop) can be prevented. That is, the present invention, by using the TPC01 pattern used in uplink synchronization (UL synch) gradually increases (step down) the power of the base station (downstream transmission power of the base station) and transmits it downward so that the mobile terminal transmits a transmission interrupted state ( Tx_off) can be derived quickly. Here, when the TPC01 pattern is set to "5", five "01" patterns are transmitted, such as "01 01 01 01 01", where "0" means power maintenance and "1" means power up. .

Next, a DL synchronization synchronization acquisition complementary algorithm (second control method) using an arbitrary transmission power control pattern will be described.

In the present invention using the second control scheme, unlike the first control scheme, a downlink-pattern-out synch (DL_Pattern_Out Synch) may be defined to newly set a corresponding pattern (transmission power control pattern). The first control method uses a previously defined parameter, and according to the exemplary embodiment, an operator may arbitrarily define and use it. That is, various methods may exist for the transmission power control pattern definition.

For example, if "DL_pattern_out synch: 001" is defined and the number of repetitions is defined through "DL_Pattern_duration_out synch", and if the number of repetitions is defined as "3", the power control pattern will be in the form of "001 001 001". will be. If the pattern is defined as "1" and the number of repetitions as "1", the shape of "11" will be repeated.

Hereinafter, the triggering timing of the downlink-pattern-out synch (DL_Pattern_Out Synch) will be described.

Determining the conditions for UL RL failure, the number of consecutive out-of-sync indicators (Out_of_synch_ indicators) already defined in the WCDMA system and the number of out_of_synch occur When the radio link failure timer (T_RL failure timer) is driven, and the radio link failure timer (T_RL failure timer) expires (expire), the base station 121 informs the RNC 122 of the radio link failure (RL failure). You will be notified.

For example, in the case of "N_out of synch: 255, T_RL failure timer: 5sec", an out-of-sync indicator is generated continuously for 255 frames, and then an In_synch_indicator for 5 sec. ), It is determined that a radio link failure (RL failure) has occurred. That is, a RL failure occurs after 2.55 sec (1 frame = 10 msec, 255 frame is 2.55 sec) + 5 sec.

On the other hand, when describing the timing of the transmission power control (TPC) pattern triggering, the DL TPC01 pattern start timer (first control method) is set to ping pong (Ping Pong) phenomenon for the transmission state (Tx_off / on) in the mobile terminal prevent. That is, when the DL TPC01 pattern start timer expires, the downlink (DL) power of the base station is increased according to the combination of "01" of the corresponding TPC pattern. At this time, the power should be increased so as not to deviate from the maximum code power value defined for each bearer.

As another embodiment, when using an arbitrary power control pattern (second control method), the start time of the pattern DL_pattern_Out Synch is also set and used as described above (specific example in the second control method). Can be. At this time, the start timer (DL_pattern_Out synch start timer) can be implemented so that an operator can change it.

The factor that determines the pattern start point is the factor by the timer and the amount of energy that can be used to determine the transmission stop state (Tx_off) of the mobile station in the actual base station. Trigger through

That is, when the mobile terminal is in the transmission stop state (Tx_off), since the base station detects almost noise, the detection value may be very insignificant. In this case, a quantitative value should be defined and used by the test, and the definition of the value may use UE_Tx Off Energy (e.g., Ec / Io or SIR) of the user terminal. ) So that the operator can set it.

Accordingly, when the out_of_synch indicator is continuously received, when the UE_Tx off Energy falls below the set value during the corresponding timer operation time, the power control pattern is triggered. If the data tested for the transmission stop state (Tx_off) is defined, the value can be set as a default.

It is preferable to use the TPC01 pattern in terms of implementation simplification and function, but the present invention is not limited thereto, and various methods can be considered. In this case, "DL_pattern_out Synch", "DL_pattern_out Synch Duration", and "DL_pattern_out Synch Start timer" "And the like.

On the other hand, the method of the present invention as described above can be written in a computer program. And the code and code segments constituting the program can be easily inferred by a computer programmer in the art. In addition, the written program is stored in a computer-readable recording medium (information storage medium), and read and executed by a computer to implement the method of the present invention. The recording medium may include any type of computer readable recording medium.

The present invention described above is capable of various substitutions, modifications, and changes without departing from the technical spirit of the present invention for those skilled in the art to which the present invention pertains. It is not limited by the drawings.

1 is a network diagram of a mobile communication system to which the present invention is applied;

2 is an explanatory diagram for switching a transmission state in a mobile terminal;

3 is a block diagram of an apparatus for controlling power of a downlink in order to prevent uplink failure in a mobile communication system according to an embodiment of the present invention;

4 is a flowchart illustrating a method of controlling power of a downlink in order to prevent an uplink failure in a mobile communication system according to an embodiment of the present invention.

* Explanation of symbols on the main parts of the invention

10: mobile terminal 12: mobile communication system

121: node B 30: power control device

31: reverse signal receiver 32: terminal state analysis unit

33: power control unit

Claims (11)

In the device for controlling the power of the downlink to prevent uplink failure in a mobile communication system, Reverse signal receiving means for receiving a reverse signal transmitted from the mobile terminal; Terminal state analysis means for checking the transmission state of the mobile terminal by checking whether the undetected state of the reverse signal is maintained for a predetermined time through the power of the received reverse signal; And A power control means for increasing downlink transmission power to the mobile terminal when the mobile terminal is in a transmission stop state, And the reverse signal is a reverse pilot signal or a reverse dedicated physical control channel (DPCCH) signal for synchronization acquisition. delete The method of claim 1, The power control means, When the reverse signal is detected or the undetected state of the reverse signal is released within a predetermined time, the inner loop power control and the outer loop power control are further performed. Downlink power control device, characterized in that. The method of claim 1, The power control means, The downlink power control device, characterized in that for increasing the downlink transmission power in accordance with a predetermined power control pattern. The method of claim 4, wherein The power control means, And downlink transmission power is increased within a range of a maximum code power value defined for each bearer. In the method for controlling the power of the downlink to prevent uplink failure in a mobile communication system, A terminal transmission state checking step of checking, by the power of the received reverse signal, whether the undetected state of the reverse signal is maintained for a predetermined time to confirm a transmission state of the mobile terminal; And A power control step of increasing downlink transmission power to the mobile terminal when the mobile terminal is in a transmission stop state, And the reverse signal is a reverse pilot signal or a reverse dedicated physical control channel (DPCCH) signal for synchronization acquisition. delete The method of claim 6, As a result of checking the terminal transmission status, if the reverse signal is detected or the undetected state of the reverse pilot signal is released within a predetermined time, inner loop power control and outer loop power control Steps to follow Downlink power control method further comprising. The method of claim 6, The power control step, The downlink power control method of increasing the downlink transmission power in accordance with a predetermined power control pattern. The method of claim 9, The power control step, And downlink transmission power is increased within a range of a maximum code power value defined for each bearer. delete

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