KR100813046B1 - method for frequency scanning of mobile terminal - Google Patents

Abstract

The present invention relates to a communication method of a mobile terminal, and more particularly, to a frequency scan method performed by a mobile terminal to search for a cell.

In a method of scanning a frequency according to an embodiment of the present invention, in a method of searching for a specific cell by scanning a predetermined frequency band, a frequency band of an arbitrary first bandwidth is scanned, but any Performing a scan repeatedly according to the first raster of the first raster; Scanning a frequency band equal to an arbitrary second bandwidth for at least one or more frequency bands in which the strength of a received signal is largely measured among the plurality of frequency bands in which the scan is performed, and repeatedly scanning according to an arbitrary second raster step; And finding a cell providing a normal service according to a result of performing the scan, wherein the second raster is smaller than the first raster.

Frequency Scan, Repeat, Raster, High Speed

Description

Frequency scanning method of a mobile terminal {method for frequency scanning of mobile terminal}

1A and 1B are flowcharts illustrating a frequency scan method according to an embodiment of the present invention.

2A is a diagram illustrating the concept of the frequency scan of the first step according to the present embodiment.

2B is a diagram illustrating the concept of the frequency scan of the second step according to the present embodiment.

2C is a diagram illustrating a concept of frequency scanning in a third step according to the present embodiment.

3 is a block diagram illustrating an embodiment of a mobile terminal to which a frequency scan method according to an embodiment of the present invention can be applied.

The present invention relates to a communication method of a mobile terminal, and more particularly, to a frequency scan method performed by a mobile terminal to search for a cell.

In order for a mobile terminal to be booted and receive normal service from a network, a mobile terminal must search and find a cell. In addition, to find the cell, a channel for the cell must be searched. Thus, to find the cell, a frequency scan is needed to find the channel.

One of several methods of performing the frequency scan is as follows.

A mobile terminal performing a frequency scan receives a Public Land Mobile Network (PLMN) ID from a non-access stratum (NAS) of a network, and a UTRAN Absolute Radio Frequency Channel Number (UARFCN) corresponding to the PLNM ID is assigned to the mobile terminal. Check if it is stored in RRC (Radio Resource Control) database. The NAS refers to a set of control plane protocols that control communication between a terminal and a core network of a universal mobile telecommunication system (UMTS). The PLMN ID includes a mobile network code (MNC) for identifying a network and a mobile country code (MCC) for identifying a country, and performs a function of identifying a service provider that provides a communication service. Whether there is a UARFCN corresponding to the PLNM ID is determined by searching an ACQ.DB (ACQuisition Database) of the RRC.

If there is a UARFCN corresponding to the PLMN ID, a fast scan is performed. Through the fast scan, the mobile station performs an acquisition scan for searching for a cell using a channel number indicated by the UARFCN.

If the UARFCN corresponding to the PLMN ID does not exist, such a fast scan may not be performed. In this case, the mobile terminal. A full band scan that performs a frequency scan for all bands should be performed.

The full band scan method according to the prior art has the following problems.

First, the scan method according to the prior art has a problem that it takes a long time to perform a frequency scan because it performs a frequency scan for all bands. If a large amount of time is required to perform the frequency scan, the mobile terminal may take a long time to receive a normal service from the network. For example, the conventional scanning method scans the entire band according to the raster of 200Khz in performing the full band scan. In this case, a frequency band of several tens of MHz is scanned, and it takes a very long time to receive the normal service. If the normal service is not received, the mobile terminal stays in the No Service state that does not receive the telephone service, and thus there is a problem that a normal call cannot be made.

Second, the scan method according to the prior art has a problem that the reliability of the frequency scan is inferior by performing one scan for a specific band.

The present invention has been proposed to solve the above problems, and an object of the present invention is to provide a scanning method capable of scanning the entire band at a high speed.

It is still another object of the present invention to provide a scanning method for increasing reliability while scanning the entire band at a high speed.

In a method of scanning a frequency according to an embodiment of the present invention, in a method of searching for a specific cell by scanning a predetermined frequency band, a frequency band of an arbitrary first bandwidth is scanned, but any Performing a scan repeatedly according to the first raster of the first raster; Scanning a frequency band equal to an arbitrary second bandwidth for at least one or more frequency bands in which the strength of a received signal is largely measured among the plurality of frequency bands in which the scan is performed, and repeatedly scanning according to an arbitrary second raster step; And finding a cell providing a normal service according to a result of performing the scan, wherein the second raster is smaller than the first raster.

In addition, the mobile terminal according to an embodiment of the present invention, a frequency scan module for repeatedly scanning a frequency band by any bandwidth, according to any raster (raster); And controlling the frequency scan module to perform a frequency scan according to a frequency band equal to an arbitrary first bandwidth and an arbitrary first raster, and then the strength of the received signal is increased according to a result of the scan. A control module for controlling at least one frequency band to be largely measured according to a frequency band equal to an arbitrary second bandwidth and an arbitrary second raster smaller than the first raster Characterized in that it comprises a.

The construction, operation and other features of the present invention will become apparent from one preferred embodiment of the present invention described with reference to the accompanying drawings.

1 is a flowchart illustrating a frequency scan method according to an embodiment of the present invention.

The frequency scanning method according to an embodiment of the present invention is for the mobile terminal to find a specific cell after booting. The mobile terminal finds a base station (eg, node B) of a network after booting, and after searching for the base station, performs a procedure for searching for the cell, and after finding the cell, locates the mobile terminal. Location registration will be performed. Hereinafter, a frequency scan method according to an embodiment of the present invention will be described with reference to FIGS. 1A and 1B.

As described above, the mobile terminal obtains a Public Land Mobile Network (PLMN) ID from the non-access stratum (NAS) (S101). In addition, a step of determining whether to perform a fast scan or a full band scan to find a cell is performed (S102). Through the above steps, it is determined whether a UARFCN corresponding to the PLMN ID exists, and if a UARFCN corresponding to the PLMN ID exists, a fast scan as described above is performed to find a cell at high speed (S103). . If there is no UARFCN corresponding to the PLMN ID, the mobile station performs a full band scan.

A full band scan according to an embodiment of the present invention performs a full band scan through at least two steps. For example, when the full band scan is performed in two steps, the full band scan of the first step performs only an approximate scan. By using the result of the coarse scan, that is, the cell power of the cell received through the scanned frequency band, the frequency band having the large magnitude of power is selected, and the detailed scan of the selected frequency band is performed again. Run (scan). The cells continuously transmit a constant signal through a specific channel of an arbitrary frequency. The mobile station measures the power of a received signal received through the channel, and receives RSSI (Received Signal) for the received signal. Strength Indication) may be used to select a frequency band having a large amount of power.

The scan of the first step calculates the power of the received signal separately for a specific frequency band, so that a plurality of received signal powers are calculated. In this case, it is desirable to align the plurality of received signal powers using a specific alignment algorithm. There is no limit to the sorting algorithm. For example, a quick sort algorithm, an insert sort algorithm, a bubble sort algorithm, a selective sort algorithm, and a heap sorting algorithm are possible. However, since the frequency scan requires a high speed, it is more preferable that the alignment algorithm uses a quick alignment algorithm. The quick sort is a sorting method with good average performance. In the case of bubble sorting or selective sorting, the data next to each other is compared and exchanged. This method is inefficient as the farther from the data is finally sorted. Quick sort improves this inefficiency by exchanging distant data with each other. Quick alignment is a method of setting an arbitrary value called a pivot and then searching from both ends of the array to find a value larger and smaller than the pivot value and replacing it with each other.

The frequency band in which the frequency scan of the first step is performed is aligned according to the power magnitude of the received signal. An upper specific frequency band is selected from the aligned frequency bands, and detailed scan is again performed on the selected frequency band. One embodiment of the present invention, through this at least two or more steps of scanning and the alignment, allows a very fast frequency scan.

As described above, the frequency scanning method according to an embodiment of the present invention performs at least two steps of scanning, and FIG. 1 illustrates a frequency scanning method including three steps. There is no limitation that the scan has several steps, and the example described below is only one embodiment of the present invention.

First, the mobile station performs a first step frequency scan according to a bandwidth of 5 MHz and a raster of 3 MHz (S104). The 5Mhz bandwidth and the 3Mhz raster are only numerical values according to an embodiment of the present invention, and the present invention is not limited to these numerical values. The raster is preferably smaller than the bandwidth. This is because when the raster is larger than the bandwidth, a specific frequency band is not scanned, and a specific channel is missing from the scan. Preferably, the raster value is larger than a conventional frequency scan. Since the frequency scan of the first step is not the final frequency scan, it is desirable to increase the raster value in order to increase the speed of the overall frequency scan.

When the entire frequency band is scanned according to the bandwidth of 5Mhz and the raster of 3Mhz as described above, the frequency scan is repeatedly performed several times, and the strength of different received signals may be calculated through each frequency scan. have. The result refers to data calculated through the scan, and represents the reception power of the received signal received in a specific frequency region in which the frequency scan is performed. If the received power is less than -100dbm, the received power value is discarded (S105). The reason why the threshold is -100 dbm is because most mobile terminals miss a cell when the cell power drops below -100 dbm. The threshold for the received power is only one example according to an embodiment of the present invention. It is apparent that the threshold may be changed by elements such as equipment or a channel environment of the communication system to which the present invention is applied. The result of the scan with the received power value exceeding the threshold is transferred to the RRC (S106). The result of the scan transmitted to the RRC is sorted in order of the received power according to the quick sorting algorithm, and the upper four frequency domains are selected (S107). The number of the selected frequency domains is not limited. If the number of the selected frequency domains is large, a more accurate scan can be performed, and the number of the selected frequency domains can be smaller and a faster scan can be performed.

The mobile station according to an embodiment of the present invention performs a more detailed second frequency scan for the frequency domain selected through the first scan of S104 to S107. The frequency scan of the second stage is performed by a smaller raster compared to the scan of the first stage. Since the frequency scan of the second stage is a frequency scan for a frequency domain that already has a large reception power, it is preferable that the raster be smaller because it needs to be performed in more detail than the second stage. In an embodiment of the present invention shown in FIG. 1, the raster is set to 2 MHz to perform a frequency scan (S108). The frequency band in which the second frequency scan is performed may be scanned using the bandwidth used in the first step frequency scan, or may be scanned using a bandwidth different from the bandwidth used in the first step frequency scan. Among the results of the second scan, when the received power is less than -100 dbm, the received power value is discarded (S109). The result of the second scan is transmitted to the RRC (S110), and the upper four frequency domains for the second frequency scan are selected by the aforementioned quick alignment algorithm (S111).

The mobile terminal according to an embodiment of the present invention performs a more detailed third frequency scan for the frequency domain selected through the second scan of S108 to S111. Since the third frequency scan is the final frequency scan, a fine frequency scan must be performed. Therefore, a frequency scan is performed with a raster of 200 Khz (S112). The third scan is a final frequency scan. In addition, the third scan may additionally scan up to 400khz band in the selected frequency domain. In the result of performing the frequency scan, when the received power is less than -100dbm, the received power value is discarded (S113). The result of the frequency scan is transferred to the RRC and sorted by the quick alignment algorithm described above (S114, S115). By performing the steps as described above to complete the work of the frequency scan to find the cell.

The mobile terminal performs a procedure of searching for a cell for the top 10 of the sorted results (S116). The RRC performs an acquisition scan to find a cell using the frequency. More specifically, the RRC may instruct to find a cell having a specific frequency obtained through the frequency scan by transmitting a specific control signal to a physical layer. The control signal is preferably transmitted in a primitive form, but there is no particular limitation. If the cell cannot be found using the frequency obtained through the frequency scan in the physical layer, the mobile station performs the above-described full band scan again. That is, the mobile terminal performs the full band scan step once more to find a cell, obtains new frequency information, and repeats the process of finding a cell using the same.

2A to 2C are diagrams for describing the concept of bandwidth and raster according to the scanning method of FIG. 1. As shown, for the entire frequency band that must be searched to find a cell, each channel is divided by frequency. The mobile terminal can scan each frequency to specify a particular channel. In addition, the mobile terminal can find a cell using the information on the channel.

Figure 2a is a diagram showing the concept of the frequency scan of the first step. As shown, the entire frequency band is scanned with a bandwidth of 5Mhz, but the frequency scan is repeatedly performed according to a raster of 4Mhz. In this case, as shown in FIG. 2A, the scan may be performed so that some of the frequency bands to be scanned overlap each other. If the size of the entire band is 56 MHz, the first frequency scan according to the embodiment is 14 times. However, if you used a 200khz raster from the start, you would need approximately 270 frequency scans.

2B is a diagram illustrating a frequency scan performed according to a raster of a smaller size in a frequency region in which the power of a received signal is largely measured according to the result of the first frequency scan. In this case as well, the scan will be performed such that some of the frequency bands to be scanned overlap each other, as shown in FIG. 2B.

2C is a diagram illustrating performing a frequency scan according to the raster of the smallest size according to the result of the second frequency scan. In this case as well, the scan will be performed such that some of the frequency bands to be scanned overlap each other, as shown in FIG. 2C. As described above, the third frequency scan is performed according to the raster of 200 kHz, so that a fine frequency scan is possible. In addition, since the cell is searched according to at least two frequency scans, a more accurate frequency scan can be performed.

3 is a block diagram illustrating an embodiment of a mobile terminal to which a frequency scan method according to an embodiment of the present invention can be applied. Referring to FIG. 3, an embodiment of a mobile terminal to which a frequency scan method according to an embodiment of the present invention can be applied will be described.

The mobile terminal according to an exemplary embodiment of the present invention includes a control unit 310, a wireless unit 320, a memory 330, a voice processing unit 340, an input unit 350, and a display unit 360. The controller 310 performs an overall control operation of the mobile phone, and the wireless unit 320 controls transmission and reception of voice data and control data under the control of the controller 310. The memory 330 may include a program memory for storing program data necessary for controlling a mobile phone operation, and a data memory for storing data generated during control or during execution by a user. In addition, the voice processor 340 converts the voice data received from the wireless unit 320 into an audible sound through a speaker SPK under the control of the controller 310, and outputs a microphone (MIC). The voice signal received from the data is output to the wireless unit 320. The input unit 350 may include a plurality of numeric keys and function keys, and may output key input data corresponding to a key pressed by the user to the controller 310. The display unit 360 displays various messages and the like under the control of the controller 310.

The controller 310 may control the radio unit 320 to perform a frequency scan in at least two steps as described above. The wireless unit 320 is controlled by the controller 310 to repeatedly scan the entire frequency band according to a specific bandwidth and a raster value. The control unit 310 sorts the received signal power values according to the scan by using the above-described various sorting algorithms, and for the predetermined number of frequency bands in which a received signal having a large power level is received, the first step The frequency scan of the second stage is performed according to the small raster value compared to the frequency scan of.

Since the mobile terminal scans at least two or more frequencies according to an embodiment of the present invention, it is possible to perform a frequency scan at a higher speed in performing a full band scan, and also to receive At least two frequency scans are performed on a frequency band having a large cell power of a signal, thereby increasing reliability of the frequency scan.

Those skilled in the art through the above description can be seen that various changes and modifications can be made without departing from the spirit of the present invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification but should be defined by the claims.

The frequency scanning method according to the present invention has an advantageous effect of increasing the speed of the frequency scan by reducing the number of scans, and has an advantageous effect of improving the accuracy of the scan by scanning a specific frequency band at least twice.

Claims (7)

Scanning a frequency band by any first bandwidth, and performing a first scan that repeats according to any first raster so that a portion of the frequency bands to be scanned overlap each other; Scan at least one frequency band as much as a second bandwidth for at least one or more frequency bands of which a strength of a received signal is largely measured among the plurality of frequency bands in which the first scan is performed, and a portion of the frequency bands to be scanned overlap each other Performing a second scan, repeating according to any second raster to ensure; And And finding a cell providing a normal service according to a result of performing the second scan. And wherein said second raster is smaller than said first raster. The method of claim 1, Sorting the plurality of frequency bands on which the first scan is performed according to the strength of the received signal measured through the first scan; And Reporting, as a result of performing the first scan, a specific frequency band in which the intensity of the received signal is largely measured according to the alignment result; A frequency scan method of a mobile terminal further comprising. The method of claim 2, The sort is performed by a quick sorting algorithm. Characterized in that a frequency scan method of a mobile terminal. The method of claim 1, wherein the finding of the cell comprises: And searching for a cell using a communication channel of a frequency band in which the strength of the received signal is largely measured according to the result of the second scan. The method of claim 4, wherein if the cell is not found, Repetitively scanning the first bandwidth according to the first raster and scanning the second bandwidth according to the second raster again. Frequency scan method of the mobile terminal to. A frequency scan module which repeatedly scans a frequency band by an arbitrary bandwidth according to an arbitrary raster; And By controlling the frequency scan module, a frequency first scan is performed according to an arbitrary first raster so as to perform a scan on a frequency band equal to an arbitrary first bandwidth, but a part of the frequency bands to be scanned overlap each other. After performing the scan, the scan is performed on at least one or more frequency bands of which the intensity of the received signal is largely measured according to the result of the first scan, but smaller than the first raster so that some of the scanned frequency bands overlap each other. A control module for controlling to perform a frequency second scan according to the second raster of Mobile communication terminal comprising a. The method of claim 6, An alignment module for sorting the strength of the received signal according to the result of the first scan to determine at least one or more frequency bands in which the strength of the received signal is largely measured; A mobile communication terminal further comprising.

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