KR0137524B1 - Optimum area judging method of an area sensing tuning system - Google Patents

Abstract

According to the present invention, in performing automatic tuning in an arbitrary area by using preset data for each region, an area detection is performed so that a preset operation can be performed in an area having more broadcasting frequencies by using the accumulation frequency of frequency data from which noise components are removed. It is to provide an optimal regional identification method of the tuning system.

To this end, the present invention comprises the first step of performing a broadcast frequency search operation for all receivable frequency bands to detect only a reception frequency that does not include a noise component among the tuned reception frequencies; By comparing and comparing the detected reception frequency with the stored broadcasting frequency data for each region, detecting and accumulating the number of indexes of region discrimination of the matched broadcasting frequency, and selecting the region with the highest accumulated number as the optimal broadcasting receiving region. Comprising a second process, the first process is a first step of detecting the same frequency by comparing the electric field sensitivity of any frequency currently received and the electric field sensitivity of each preset broadcast frequency, and the detected reception frequency After digitally converting the waveform and sampling for a predetermined time, if the signal level is constant, it is determined to be a reception frequency containing noise components and canceled. If the signal level is not constant, it is determined to be a reception frequency without noise components. The second step is to temporarily save.

Description

Optimal Regional Discrimination Method of Regional Sensing Tuning System

1 is a view for explaining the problem of the local sensing tuning system with a preset function using a conventional local telephone number,

2a to 2c is a view for explaining a problem of the preset function of the local sensing tuning system for automatic tuning of the optimal broadcast frequency at the current current position,

3 is a block diagram of an optimal area discriminating device of a regional sensing tuning system employed as an embodiment of the present invention;

4 is a frequency waveform diagram showing an example of a frequency waveform signal outputted from the search performing means shown in FIG.

5 is a flowchart for explaining an optimal area discrimination method of a regional sensing tuning system according to an embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

10: tuner 12: search performing means

14 signal conversion / sampling unit 16 station selection unit

18: Preset up / down key 20: Preset data storage

22: control unit 24: receiving frequency storage unit

26: voice muting unit

The present invention relates to an optimal area discrimination method of a regional sensing tuning system applied to a television or an audio device. In particular, the present invention relates to automatic tuning using preset data (broadcast frequency of each of a plurality of broadcast stations existing in a certain area) in an arbitrary area. The present invention relates to an optimal area discrimination method of an area sensing tuning system that enables a tuning operation by more accurate optimal area discrimination when performing auto tuning.

In general, a television or audio device is provided with a frequency up / down key for operating a user's operation and searching for a desired broadcasting channel. When the frequency up / down key is pressed, the frequency of the currently received broadcast channel is pressed. From now on, while searching for a broadcast channel with increasing frequency, if a broadcast signal is received at the corresponding frequency, the search for the broadcast channel is stopped and the presence of a broadcast station is notified.

However, in the above search function, when a user wants to receive a new broadcast signal, a search operation must be performed every time, and a plurality of broadcast frequencies exist between the broadcast frequency of the currently received broadcast channel and the broadcast frequency of the desired broadcast channel. In this case, it is very troublesome as well as accurate tuning because it operates to reach the broadcasting frequency of the desired broadcasting channel after searching a plurality of broadcasting frequencies sequentially from the broadcasting frequency of the broadcasting signal currently received through the searching operation. Grabbing has become an inconvenient problem.

Therefore, conventionally, a memory is provided in a television or an audio device, and the broadcasting frequency data (i.e., preset data) of each broadcasting station is stored in a predetermined position in the memory in advance, and the user can enter a numeric key (0-9) or preset up. A preset memory / preset recall function has been proposed that reads a stored broadcast frequency using the / down key to tune the read frequency.

However, according to the preset memory / preset recall function, when a user first purchases a television or an audio device equipped with a preset memory / preset recall function or moves to a region where a broadcast listening or broadcasting viewing area is different from the current region, or If the vehicle is mounted on an object moving to another area such as a car (for example, a car stereo), the preset data are different for each area. Therefore, the memory must be reset at each time. If you don't know it, you can't use the preset memory / preset recall function properly.

For that reason, in order to secure the preset memory / preset recall function, it is possible to search from the lowest frequency band to the highest frequency band or from the current reception frequency band to the highest frequency band, and then receive the current signal at the lowest frequency band again. It automatically searches the entire frequency band up to the current frequency band and automatically saves the corresponding frequency data sequentially whenever a frequency over a certain electric field sensitivity is received and the user selects the numeric keys (0 ~ 9) or presets. An automatic memory function has been proposed to read a stored broadcast frequency by using the up / down keys to read the stored broadcast frequency.

However, according to the above-described automatic memory function, there is a case where the electric field sensitivity is weak and it cannot be discriminated as the broadcast frequency despite the broadcast frequency, and the noise signal of the strong electric field is incorrectly identified as the broadcast frequency and stored.

Thus, in order to solve the problem of the automatic memory function, a preset function using the area code of the phone number has been proposed. The operation of the preset function using the phone number for each area will be described as follows.

First, the broadcasting frequency data of each region (for example, by administrative region or telephone number) can be distinguished and stored, but the telephone area code of the region in each broadcasting frequency data can be identified to identify the corresponding region of each stored broadcasting frequency data. After adding and storing (DDD), if the user inputs the telephone area code, the broadcasting area number of the corresponding telephone area code will be tuned by comparing the telephone area code entered by the user with the telephone area code stored in the memory. To help.

In other words, as shown in Table 1, when the user enters the Seoul telephone area code 02 while storing each broadcasting frequency according to the corresponding phone area code, the FM station 87.8MHz, FM 89.1MHz, and FM 91.9 MHz, FM only 93.1MHz broadcasting frequency can be tuned, and when the user presses the M1 button after entering the Seoul telephone area code (02), the broadcasting frequency of FM 87.8MHz, which is the corresponding broadcasting frequency, is tuned. .

In addition, whenever a user inputs a Seoul telephone area code (02) and presses a preset up / down key, FM 87.8 MHz, FM 89.1 MHz, FM 91.9 MHz, and FM 93.1 MHz are sequentially selected.

However, if a television or audio device having a preset function using the telephone area code is mounted on a moving object such as a vehicle, the user must memorize the telephone area code of the corresponding area every time the area moves, and the corresponding area and actual There was a problem in broadcasting frequency tuning because the broadcasting areas were not matched according to the receiving sensitivity of broadcasting frequencies.

That is, even though the area is divided into area A and area B according to the telephone area code division as shown in FIG. If it belongs to the A region on the boundary of the broadcasting area according to the reception sensitivity of the frequency, it is confusing to the user when the broadcasting frequency is tuned.

Therefore, in order to solve the problem of the preset function using the telephone area code, a preset function of the local sensing tuning system which can automatically tune the optimal broadcasting frequency at the current position has been proposed. The function distinguishes and stores broadcasting frequency data (preset data) for each region in the memory where data can be stored, but each broadcasting frequency can be identified to identify the data corresponding to the broadcasting station name of each broadcasting frequency and the corresponding region of each broadcasting frequency data. Presets stored in the memory by comparing the frequency data detected by the search execution means for searching for broadcast signals with a predetermined electric field sensitivity and the preset data for each region stored in the memory by adding and storing an index of the corresponding area to the data. Each frequency detected by the search performing means in the data. After detecting the index of the region with the most frequency data matched with the data, it is possible to accumulate the regional discrimination index by classifying each region and calculate the ratio of the accumulated count of the regional discrimination index to the number of broadcasts in each region. The region with a high calculated ratio is identified as an optimal broadcasting frequency receiving region (region sensing preset operation) so that only the broadcasting frequency data of the determined region can be tuned.

For example, if the broadcasting frequencies for each region as shown in Table 2 are stored in the memory, the control unit compares the broadcasting frequency data output from the searching unit with the broadcasting frequency data of Table 2, respectively.

Therefore, if the current location is Busan, the search means must output data corresponding to FM 88.9 MHz, FM 92.7 MHz, FM 97.1 MHz, and FM 107.7 MHz.

However, due to the reception sensitivity and noise of the used area (Busan), the electric field sensitivity of the broadcasting frequency of 92,7MHz is weak and the searching means cannot detect it, whereas the electric field of FM 95.3MHz, the noise signal of the strong electric field, is detected. If the sensitivity exceeds the preset value and is incorrectly detected as the broadcast frequency, the actual search means outputs data corresponding to FM 88.9 MHz, FM 95.3 MHz, FM 97.1 MHz, and FM 107.7 MHz.

Therefore, the control means compares the FM 88.9 MHz, the FM 95.3 MHz, the FM 97.1 MHz, and the FM 107.7 MHz output from the search performing means with the broadcasting frequencies for each region shown in Table 2, respectively.

As a result of comparison, Seoul and Gwangju areas do not have the same frequency at all, and Busan area has three broadcasting frequencies (FM 88.9MHz, FM 97.1MHz, FM 107.7MHz), and Daegu area has one broadcasting frequency (FM 95.3). Since only MHz) coincides, it can be seen that the Busan region has the highest abundance of the same frequency.

Therefore, the control means determines that each broadcast frequency data of the Busan area is the optimal broadcast frequency that can be received at the current location so that only each broadcast frequency of the Busan area can be tuned.

However, the above-described preset function of the regional sensing tuning system uses the broadcasting frequency including the noise component as one data. As shown in FIG. 2A, the broadcasting frequencies that can be received in the region A are five, and FIG. As shown in Fig. 2, when the number of broadcast frequencies that can be received in area B is eight, autotuning is performed in area C, which is the border area between area A and B, and the tuning results as shown in FIG. Pre-existence rate of broadcasting by region

By the following equation, the area A is 100% and the area B is 50%. Therefore, it is determined that the current optimal reception area is area A, and the preset operation is performed using the broadcasting frequency existing in the area A. In this case, although the actual number of broadcasting frequencies (that is, broadcasting frequencies without noise components) in region B is larger than that of region A selected as an optimal receiving region, a factor that is not necessary for the region discrimination operation is used. Because there is a large number of region A data containing noise components, it is necessary to receive the broadcasting frequency of region A.

Accordingly, the present invention has been made in view of the above circumstances, and an object thereof is to provide more broadcasting frequencies by using the frequency of accumulation of frequency data from which noise components have been removed in autotuning in an arbitrary area using regional preset data. The present invention provides an optimal region discrimination method of a regional sensing tuning system to perform a preset operation in an own region.

In order to achieve the above object, the optimal area discrimination method of the regional sensing tuning system according to the present invention performs a broadcast frequency search operation on all receivable frequency bands to detect only a reception frequency that does not include noise components among the tuned reception frequencies. The first process of doing; By comparing the detected receiving frequency with the stored broadcasting frequency data distinguished by each region, detecting and accumulating the number of indexes of region discrimination of the matching broadcasting frequency, and selecting the region with the highest accumulated number as the optimal broadcasting receiving region. It consists of a second process.

According to a preferred embodiment of the present invention, the first step is a first step of detecting the same frequency by comparing the electric field sensitivity of any frequency currently received with the electric field sensitivity of each preset broadcasting frequency, and detecting the same frequency. After digitally converting the waveform of the receiving frequency and sampling for a predetermined time, if the signal level is constant, it is determined to be a reception frequency containing noise components and canceled. If the signal level is not constant, it is converted to a reception frequency without noise components. A second step of determining and temporarily storing is performed.

And, the first process is the voice muting operation if the electric field sensitivity of any frequency currently received is not the same as any electric field sensitivity of the preset broadcasting frequency of each region or if a reception frequency containing noise component is detected for a predetermined time. A third step of controlling to be performed is further provided.

According to the present invention configured as described above, during a broadcast frequency search operation for all receivable frequency bands, a reception frequency containing no noise component is compared with broadcast frequency data for each region, and only the same frequency is detected and accumulated. Since the region with the highest accumulation frequency is selected as the current optimal receiving region, the preset operation in the selected region can be performed.

Hereinafter, with reference to the accompanying drawings will be described the present invention in more detail.

3 is a block diagram of an optimal area discrimination apparatus of a regional sensing tuning system employed as an embodiment of the present invention. The tuner 10 selects a broadcast frequency of a desired channel from among broadcast signals received from an antenna and selects an intermediate frequency. Convert to (IF) signal and output.

The search performing means 12 performs a search function while circulating all provided frequency bands, and detects the same frequency as the electric field sensitivity of the broadcasting frequency of each region stored in the preset data storage unit 20 to convert the signal into a signal / The data is transmitted to the sampling unit 14 and the control unit 22.

The signal conversion / sampling unit 14 digitally converts the frequency waveform signal detected by the search performing unit 12 at a predetermined time interval under the control of the control unit 22 to discriminate the noise in the control unit 22. Output as a dragon signal.

The tuning unit 16 has a predetermined tuning key to input the broadcast frequency tuning request signal to the control unit 22.

The preset up / down key 18 is a user key for inputting a signal for requesting performing a search operation to the controller 22.

The preset data storage unit 20 stores the preset data (broadcast frequency) for each region in advance, and additionally stores an area index of each preset data so as to identify a corresponding region of each stored preset data. The nonvolatile memory (eg, EEPROM) may be configured as a ROM of the controller 22 such that region-specific preset data is not lost even when the power is turned off.

In the figure, the control unit 22 includes a noise component when the output signal of the signal conversion / sampling unit 14 is applied while maintaining a constant level for a predetermined time with respect to the frequency applied from the search performing means 12. The voice muting section 26 is controlled to perform the voice muting operation in the current frequency band, and the signal conversion / sampling section 14 of the signal conversion / sampling section 14 is applied to the frequency applied from the search performing means 12. If the output signal is not applied for a predetermined time, it determines that the noise component is not included and controls the voice muting operation to be released. The current reception frequency is stored in the reception frequency storage unit 24 including a buffer. Save it temporarily.

When the frequency search operation is performed by the search performing means 12, the control unit 22 stores frequency data stored in the reception frequency storage unit 24 and preset data for each region stored in the preset data storage unit 20. Are compared with each other to select the region with the most matching frequency data as the optimum broadcast receiving area, the control unit 22 is preferably composed of a microcomputer.

Referring to the apparatus configured as described above as an example, an optimal region discrimination method of the regional sensing tuning system according to an embodiment of the present invention will be described.

In the flowchart of FIG. 5, a user located in a certain area initially performs a search for a broadcast frequency for all frequency bands that can be received using the search performing means 12 (step 50).

If the same frequency as the electric field sensitivity of the broadcasting frequency for each region is set and stored in the preset data storage unit 20 in advance during the broadcasting frequency search operation (step 51), the received frequency signal is converted into a signal conversion / sampling unit. (14) and the control unit 22. The signal conversion / sampling unit digitally converts an input waveform and controls the sampled data sampled at a predetermined time interval under the control of the control unit 22. (Step 52).

Accordingly, the controller 22 determines whether a noise component is included in the currently received frequency based on the signal from the signal converter / sampling unit 14 (step 53). For example, when any frequency searched and outputted by the search performing means 12 is correctly tuned, as shown in FIG. 4A, a frequency waveform whose amplitude is not constant over time is converted into the signal conversion / sampling unit ( 14) and the digital component is sampled after the digital conversion, so that the noise component is not included. On the other hand, if the noise component is included in any frequency searched and output by the search performing means 12, As shown in the figure, a frequency waveform having a rate of change of amplitude within a few tens of KHz is inputted to the signal conversion / sampling unit 14 and sampled after digital conversion, thereby quickly indicating that a noise component is included.

When the electric field sensitivity of the received frequency is not the same as any electric field sensitivity of each preset broadcasting frequency or the noise component is detected in step 53, the controller 22 determines that the voice is The muting section 26 is controlled to perform the voice muting operation (step 54).

However, if a random component equal to the electric field sensitivity of the broadcasting frequency for each region is not detected even after a predetermined time has elapsed (step 55), the voice muting operation is canceled (step 56). Temporarily stored in the reception frequency storage section 24 (step 57).

In this way, when a search operation for all frequencies that can be received with a predetermined reception frequency (no noise component is temporarily stored in the reception frequency storage unit 24) is terminated (step 58), the controller 22 The reception frequency stored in the reception frequency storage unit 24 is compared with preset data for each region of the preset data (step 59).

As a result of the comparison, the controller 22 accumulates while detecting the number of broadcast frequencies corresponding to each region (step 60). As a result of the accumulation, the region having the largest accumulation frequency (e.g., the accumulation value of the region discrimination index) is selected as the optimal broadcasting reception region at the current location (step 61).

Although not shown in the flowchart, when the accumulation times between predetermined regions compared to select an optimal broadcasting receiving region from the current position are the same, the region having the largest number of broadcasting frequencies present in each region is presently located. It is selected as the best broadcasting reception area in.

Thereafter, the control unit 22 causes the preset operation in the selected region to be performed in accordance with the input signals from the tuning key 16 and the preset up / down key 18.

According to the present invention as described above, in order to select the optimal broadcast receiving area in the current receiving area, after performing a broadcast frequency search operation for all frequency bands, frequency data containing no noise component is detected and a voice of any area is detected. Since the region with the highest frequency of accumulation of the same frequency is selected in preparation for the same frequency as the frequency, there is an advantage in that the reliability of selecting the optimal broadcast receiving region becomes higher.

Claims (3)

Performing a broadcast frequency search operation on all receivable frequency bands to detect only a reception frequency including no noise component among the tuned reception frequencies; By comparing and comparing the detected reception frequency with the stored broadcasting frequency data for each region, detecting and accumulating the number of indexes of region discrimination of the matched broadcasting frequency, and selecting the region with the highest accumulated number as the optimal broadcasting receiving region. Optimum regional discrimination method of regional sensing tuning system, characterized in that the second process. The method of claim 1, wherein the first step is performed by comparing the electric field sensitivity of any frequency currently received with the electric field sensitivity of each preset broadcasting frequency and detecting the same frequency, and detecting the same frequency. After digitally converting the waveform and sampling for a predetermined time, if the signal level is constant, it is determined to be a reception frequency containing noise components and canceled. If the signal level is not constant, it is determined to be a reception frequency without noise components. Optimum regional discrimination method of the regional sensing tuning system, characterized in that the second step of storing. The method of claim 2, wherein the first process detects a reception frequency including a noise component for a predetermined time or the electric field sensitivity of any frequency currently received is not the same as any electric field sensitivity of the preset broadcasting frequency for each region. And a third step of controlling the voice muting operation when the voice muting operation is performed.