JP6403708B2 - Broadcast receiving apparatus and broadcast receiving method - Google Patents

Description

  The present invention relates to a broadcast receiving apparatus and a broadcast receiving method having a scan function for sequentially checking whether or not each channel can be received.

  When receiving broadcast waves such as terrestrial digital broadcasting, broadcast stations differ depending on the reception area. For this reason, when a broadcast receiver is installed, it is generally set by scanning receivable channel information (a function for determining whether a signal exists in all channels).

  Also, it has a function to check reception of channels in order, and search channel selection for viewing as it is in a channel where receivable broadcasts are found, or register a receivable channel found in search channel selection to a preset button. There is also a broadcast receiver.

  However, in the scan or search channel selection, since reception confirmation is performed for a plurality of channels, it takes a long time for the broadcast receiver to start receiving the broadcast. In addition, terrestrial digital broadcasting requires more time than analog broadcasting because OFDM (orthogonal wave frequency division multiplexing) frame synchronization takes time.

  In particular, mobile broadcast receivers (such as mobile terminals compatible with terrestrial digital broadcasting and in-vehicle broadcast receivers) that have become popular in recent years are expected to be used across broadcast areas, so scans are frequently performed. It is necessary to reduce the time required for scanning.

  Therefore, a method of shortening the total scan time by omitting the operation of confirming whether or not unnecessary channels can be received and reducing the number of channels for performing reception availability confirmation is disclosed. For example, Patent Document 1 describes a method for determining the presence / absence of an adjacent channel signal based on the control amount of an amplifier.

Japanese Patent No. 4957029 (paragraphs 0046 to 0048, FIG. 4, etc.)

  However, in the method described in Patent Document 1, the control amount of the amplifier can take various values depending on the level ratio of the received signal and the adjacent channel signal, and therefore, accurate determination cannot be made only with the control amount of the amplifier.

  In view of the above, an object of the present invention is to make it possible to shorten the scan time by accurately determining the presence / absence of a signal of a target channel and stopping processing of unnecessary channels.

  The broadcast receiving apparatus according to an aspect of the present invention includes a bandpass filter that allows a signal having a frequency corresponding to a target channel to pass as a channel selection intermediate frequency signal from the received radio signal, and the target channel that has passed through the bandpass filter. The broadcast signal of the broadcast program assigned to the target channel is included in the target channel by calculating the power of the channel selection intermediate frequency signal and comparing the calculated power with a first threshold value. And a control unit that controls whether or not to stop subsequent scan processing in the target channel based on the determination result, and the control unit includes a first unit adjacent to the target channel. The first leakage power leaking into the target channel from the power of one adjacent channel is calculated, and the first leakage power is calculated according to the calculated magnitude of the first leakage power. The first adjacent channel is a channel that has been scanned before the target channel scan process, and the power of the first adjacent channel is changed during the scan process of the first adjacent channel. It is calculated from the channel selection intermediate frequency signal that has passed through the band pass filter.

  The broadcast receiving method according to one aspect of the present invention calculates a power of the channel selection intermediate frequency signal of the target channel by passing a signal of a frequency corresponding to the target channel as a channel selection intermediate frequency signal from the received radio signal. Then, by comparing the calculated power with a first threshold value, it is determined whether or not a broadcast signal of a broadcast program assigned to the target channel is included in the target channel, and the determination result is A broadcast receiving method for controlling whether or not to stop subsequent scan processing in the target channel based on the first leakage power leaking into the target channel from a first adjacent channel adjacent to the target channel And the first threshold is changed according to the calculated magnitude of the first leakage power, and the first adjacent channel is scanned by the target channel. The power of the first adjacent channel is calculated from the channel selection intermediate frequency signal that has passed through the band-pass filter during the scan processing of the first adjacent channel. It is characterized by that.

  According to one embodiment of the present invention, the scan time can be shortened by accurately determining the presence / absence of a signal of a target channel and stopping processing of unnecessary channels.

3 is a block diagram schematically showing a configuration of a broadcast receiving apparatus according to Embodiment 1 or 2. FIG. 3 is a schematic diagram for explaining a pass band of a band pass filter according to Embodiment 1. FIG. 6 is a flowchart illustrating a broadcast receivable channel confirmation method in which the control unit according to the first embodiment confirms whether or not reception is possible while changing a scan target channel. (A) And (B) is a schematic diagram for demonstrating the operation example at the time of scanning a channel with the processing flow in Embodiment 1. FIG. 10 is a flowchart illustrating a broadcast receivable channel confirmation method in which a control unit according to Embodiment 2 confirms reception acceptance while changing a scan target channel. (A) And (B) is a schematic diagram for demonstrating the operation example at the time of scanning a channel with the processing flow in Embodiment 2. FIG.

Embodiment 1 FIG.
Hereinafter, a broadcast receiving apparatus and a broadcast receiving method to which the present invention is applied will be described.

FIG. 1 is a block diagram schematically showing the configuration of the broadcast receiving apparatus 100 according to the first embodiment.
The broadcast receiving apparatus 100 includes an RF signal amplifier 110, a local oscillator (hereinafter also referred to as LO) 120, a mixer 130, a band pass filter 140, and an analog-to-digital conversion. (Analog-digital converter; hereinafter also referred to as ADC) 150, demodulator 160, and controller 170. Broadcast receiving apparatus 100 receives a radio signal (RF signal) received by an antenna (not shown) and outputs received data.

  The RF signal amplification unit 110 receives a radio signal received by the antenna, performs amplification based on the control value from the control unit 170, and outputs the amplified output radio signal to the mixing unit 130.

  The local oscillator 120 controls the frequency of the output signal so that the signal of the channel selection frequency designated by the user from the control unit 170 is converted to an intermediate frequency, and supplies the output signal to the mixing unit 130.

  The mixing unit 130 mixes the output radio signal amplified by the RF signal amplification unit 110 with the output signal from the LO 120 to convert it to an intermediate frequency, thereby converting the intermediate frequency signal (Intermediate Frequency Signal; hereinafter, IF signal). (Referred to also as “bandwidth filter”).

  The band pass filter 140 removes an unnecessary frequency signal such as an adjacent channel from the IF signal supplied from the mixing unit 130, extracts a signal of the selected frequency band, and uses the extracted signal as a channel selection IF signal. Give to ADC150.

  The ADC 150 converts the channel selection IF signal given from the band pass filter 140 into a digital signal and gives it to the demodulation unit 160. At that time, the ADC 150 amplifies the signal based on the control value from the control unit 170 up to a voltage level that can be input to the demodulation unit 160 by an IF signal amplification unit (not shown).

The demodulator 160 demodulates the digital signal given from the ADC 150, extracts the received data, and gives it to the subsequent stage.
The received data output from the broadcast receiving apparatus 100 is decoded into video or audio, and is displayed on a display unit (not shown), or audio compression is decoded by an audio reproduction unit and reproduced as an audio signal.

The control unit 170 performs overall control processing in the broadcast receiving apparatus 100 such as reception control and control during reception data generation. For example, the control unit 170 controls each unit of the broadcast receiving apparatus 100 to perform channel scanning.
In addition, the control unit 170 performs gain control so that the gains of the RF signal amplification unit 110 and the IF signal amplification unit (not shown) become voltage levels required in the subsequent stages.
Further, the control unit 170 controls the frequency of the LO 120 so that the signal of the tuning frequency is converted into an intermediate frequency.

  For example, the control unit 170 calculates the power of the channel selection IF signal that has passed through the band-pass filter 140, and compares the calculated power with a threshold value, thereby broadcasting the broadcast program assigned to the selected target channel. It is determined whether the signal is included in the selected target channel. When the control unit 170 determines that the target channel includes a broadcast signal, the control unit 170 continues the scan process for the target channel and determines that the target channel does not include a broadcast signal. Stops the subsequent scan processing of the target channel. Here, the control unit 170 calculates the leakage power that leaks into the target channel from the adjacent channel that has been scanned, and changes the threshold according to the magnitude of the calculated leakage power. The threshold value used here is also referred to as a first threshold value. An adjacent channel that has been scanned is also referred to as a first adjacent channel, and leakage power that leaks from the first adjacent channel into the target channel is also referred to as first leakage power.

FIG. 2 is a schematic diagram for explaining the passband of the bandpass filter 140.
It is desirable that the pass band of the band pass filter 140 is configured to be only the selected target channel. However, as shown in FIG. 2, generally, the pass characteristic 2a of the bandpass filter is affected by the influence 2b of the adjacent channel signal to some extent.
However, the pass characteristic of the band pass filter is uniquely determined by the broadcasting system (for example, channel interval and channel bandwidth). Therefore, if the power of the adjacent channel signal is known, the amount affected by the influence 2b (leakage power) can be calculated.

More specifically, the power is actually calculated only for the signal of the frequency to be scanned, but due to the characteristics of the channel scan, the frequency (adjacent channel) of the frequency scanned before the current scan target channel is calculated. By maintaining the power for the signal, the leakage power can be calculated from the ratio corresponding to the area of the influence 2b in FIG. 2 from the channel spacing, the channel bandwidth, and the pass characteristics of the band pass filter.
Here, the leakage power increases as the power of the signal calculated when the band-pass filter 140 passes a signal having a frequency corresponding to the adjacent channel increases.

FIG. 3 is a flowchart illustrating a broadcast receivable channel confirmation method in which the control unit 170 confirms whether or not reception is possible while changing the scan target channel.
The flowchart of FIG. 3 is started, for example, when a scan start button (not shown) is pressed, and is executed for the number of scan channels. 3 includes a scan start step S10, a scan target channel change step S11, an adjacent channel validity determination step S12, a leakage power calculation step S13, a first power threshold determination step S14, and a first power threshold determination step S14. Threshold setting step S15, second threshold setting step S16, power calculation step S17, second power threshold determination step S18, channel signal validity determination step S19, channel signal invalidity determination step S20, and synchronization acquisition processing Step S21 and scan end step S22 are included. When performing the scan process for the next channel, the process returns to the scan start step S10 and is repeated thereafter.

  In the scan start step S10, the control unit 170 executes a process when, for example, a scan start button is pressed, and also executes a process when there is an unscanned channel even when the scan end step S22 of the target channel is reached. To do.

  In the scan target channel changing step S11, the control unit 170 adds (subtracts) the scan target frequencies one by one.

In the adjacent channel validity determination step S12, the control unit 170 performs the scanning process immediately before from the power of the channel subjected to the scanning process immediately before the scanning target channel set in the scanning target channel change step S11. Determine whether the active channel was valid. If it is determined to be valid (Yes in S12), the process proceeds to leakage power calculation step S13. If it is determined to be invalid (No in S12), the process proceeds to the second threshold setting step S16. For example, if the current channel is k, the channel subjected to the scanning process immediately before the scan target channel is the (k−1) channel.
Here, for determining whether or not the channel is valid from the power, for example, the result determined in the second power threshold determination step S18 of the channel for which the scan process was performed immediately before the channel to be scanned is controlled. The unit 170 may store the result in a memory or register in the broadcast receiving apparatus 100 (not shown), and read and use the result. As another example, the control unit 170 may make a determination by comparing a reference value given from the outside or held in advance as a fixed value with its power. In such a case, the control unit 170 stores the power calculated in step S17 in a memory or a register (not shown).
Note that the above memory or register is preferably the storage unit 170 a provided in the control unit 170.

In the leakage power calculation step S13, since it is determined that the channel scanned immediately before the scan target channel in the adjacent channel validity determination step S12 is valid, the control unit 170 performs the previous scanning process. The leakage power (TH _leak ) is calculated from the power of the other channels (adjacent channels) and the pass characteristics of the band pass filter 140. More specifically, multiplying the power of the channel that has been previously scanned by an area ratio (coefficient) that can be calculated from the channel spacing, the channel bandwidth, and the pass characteristics of the bandpass filter. To get leakage power. For example, the area ratio is calculated in advance and is stored in the storage unit 170a of the control unit 170.

In the first power threshold determination step S14, the control unit 170 compares the leakage power TH _leak calculated in the leakage power calculation step S13 with the power TH _n due to the influence of noise or the like that can be assumed in advance as the reception system. If the leakage power TH _leak is larger than the power TH _n (Yes in S14), the process proceeds to the first threshold setting step S15, and if the leakage power TH _leak is _{equal to} or less than the power TH _n (No in S14). The process proceeds to the second threshold setting step S16. Here, the power TH _n may be given from the outside, for example, or may be held in advance as a fixed value.

In the first threshold setting step S15, the control unit 170 sets the leakage power TH _leak as the reference value TH in the second power threshold determination step S18.
In the second threshold setting step S16, the control unit 170 sets the power TH _n as the reference value TH in the second power threshold determination step S18.
The reference value TH is a threshold value for determining whether or not a valid signal is included in the channel.

In power calculation step S17, the control unit 170 calculates the power (reception power) _Pk of the signal output from the ADC 150 of the scan target channel.
In the second power threshold determination step S18, the control unit 170 uses _Pk calculated in the power calculation step S17 and the reference value TH set in the first threshold setting step S15 or the second threshold setting step S16. Compare. If the power P _k is greater than the reference value TH (Yes in S18), the process proceeds to a channel signal validity determination step S19, and if the power P _k is equal to or less than the reference value TH (No in S18). The processing proceeds to channel signal invalidity determination step S20.

In the channel signal validity determination step S19, the control unit 170 determines that the power of the scan target channel is valid (there is a signal in the scan target channel) from the determination result of the second power threshold determination step S18.
In the channel signal invalidity determination step S20, the control unit 170 determines that the power of the scan target channel is invalid (no signal in the scan target channel) from the determination result of the second power threshold determination step S18.
The determination result (determination value) here is stored in a memory or register in the broadcast receiving apparatus 100 (not shown) when used in the adjacent channel validity determination step S12 of the next scan channel. If the determination result is valid, the power calculated in step S17 is also stored. If it is determined in the channel signal invalidity determination step S20 that the scan target channel power is invalid, the subsequent scan process is skipped, in other words, the scan process in the target channel is stopped, and the process ends in the scan end step S22. Proceed to

  In the synchronization acquisition processing step S21, the control unit 170 determines that the scan target channel is valid in the channel signal validity determination step S19, and therefore continues the subsequent scan processing on the scan target channel. For example, the control unit 170 performs a synchronization acquisition process in order to obtain detailed information of the scan target channel. Here, the detailed information of the channel to be scanned includes, for example, the affiliation of the broadcast station and the broadcast standard to be compliant.

  In this way, the control unit 170 performs reception confirmation while changing the scan target channel, so that when the determination result from the signal presence determination step (second power threshold determination step S18) is no signal. Thus, it is possible to change the scan target to the next channel without performing the subsequent scan processing of the scan target channel.

4A and 4B are schematic diagrams for explaining an operation example when channel scanning is performed in the processing flow of FIG.
Here, the channel scan is performed from the lower frequency to the higher frequency, and as shown in FIG. 4A, the channels CH1 to CH3 and the channel CH5 have broadcast signals, and the channel It is assumed that there is no broadcast signal on CH4.

In this case, as shown in FIG. 4B, leakage power TH _leak <power TH _n is satisfied in channels other than channel CH4. For this reason, as in the conventional method, the channel signal validity determination is performed based on the power TH _n due to the influence of noise or the like that can be assumed in advance as a receiving system. However, regarding the channel CH4, the leakage power of the channel CH3 is considered, and the leakage power TH _leak > power TH _n is _satisfied . For this reason, channel CH4 can be determined to be an invalid channel.

  As described above, according to the broadcast receiving apparatus 100 and the broadcast signal receiving method of the present embodiment, when determining the presence / absence of the signal of the scan target channel, the leakage power from the adjacent channel that has been scanned is taken into consideration. Thus, the presence / absence of the signal of the target channel can be accurately determined. Then, when there is no signal, the scan time can be shortened by changing the scan target to the next channel without performing the subsequent processing of the scan target channel.

In addition, JP 2010-50663 A (paragraphs 0023 to 0051, FIG. 1 and the like) adds the control for measuring the power of the adjacent channel and determining the presence / absence of the signal, thereby accurately determining the presence / absence of the adjacent channel signal. A method of determining is disclosed.
However, such a method requires a circuit for measuring the power amount of the adjacent channel and determining the presence / absence of a signal, which increases the circuit scale and power consumption.
On the other hand, this embodiment can accurately determine the presence / absence of the signal of the target channel without increasing the circuit scale.

In the embodiment described above, the presence or absence of a signal is determined using the leakage power TH _leak or the power TH _n due to noise or the like. For example, the leakage power TH _leak is added to the power TH _n due to noise or the like. The presence / absence of a signal may be determined using the obtained value as a reference value TH.

Embodiment 2. FIG.
Hereinafter, a broadcast receiving apparatus and a broadcast receiving method to which the present invention is applied will be described.

  As shown in FIG. 1, the broadcast receiving apparatus 200 according to the second embodiment includes an RF signal amplification unit 110, a local oscillator 120, a mixing unit 130, a bandpass filter 140, an ADC 150, and a demodulation unit 160. And a control unit 270. Broadcast receiving apparatus 200 according to Embodiment 2 is configured in the same manner as broadcast receiving apparatus 100 according to Embodiment 1 except for control unit 270.

  For example, the control unit 270 in the second embodiment calculates the power of the channel selection IF signal that has passed through the band-pass filter 140 and compares the calculated power with a threshold value, so that the target channel includes the broadcast signal. It is determined whether or not. If the control unit 270 determines that the target channel includes a broadcast signal, the control unit 270 continues the scan process for the target channel and determines that the target channel does not include a broadcast signal. Stops the subsequent scan processing of the target channel. Here, the control unit 270 calculates the leakage power that leaks into the target channel from the adjacent channel that has been scanned, and changes the threshold according to the calculated leakage power.

Furthermore, the control unit 270 determines the frequency of the adjacent channel that is reverse to the channel scan order of the target channel according to the magnitude of the leakage power from the maximum power of the signal assumed in the adjacent channel that is scanned after the target channel. The difference from Embodiment 1 described above is that the setting is changed, the leakage power leaking into the target channel is calculated from the power of the reverse adjacent channel, and the threshold is updated according to the calculated magnitude of the leakage power.
The updated threshold value is also referred to as a second threshold value. That is, the control unit 270 calculates the second threshold value by updating the first threshold value in the first embodiment. An adjacent channel (reverse adjacent channel) that is scanned after the target channel is also referred to as a second adjacent channel, and leakage power that leaks from the second adjacent channel into the target channel is also referred to as second leakage power.

  FIG. 5 is a process flowchart of a broadcast receivable channel confirmation method for confirming whether or not reception is possible while changing the scan target channel in the control unit 270 of the broadcast receiving apparatus according to the second embodiment. In FIG. 5, the same steps as those of the control unit 170 of the broadcast receiving apparatus according to Embodiment 1 shown in FIG.

The flowchart shown in FIG. 5 is started, for example, when a scan start button (not shown) is pressed, and is executed for the number of scan channels.
Here, in the flowchart of FIG. 5, instead of the second power threshold determination step S18 in the flowchart of FIG. 3, an assumed maximum leakage power identification step S30, a second power threshold determination step S31, and inverse adjacent channel power calculation Step S32, reverse adjacent channel leakage power calculation step S33, threshold update step S34, and third power threshold determination step S35 are performed. When performing the scan process for the next channel, the process returns to the scan start step S10 and is repeated thereafter.
The process in step S17 in FIG. 5 is the same as that in step S17 in FIG. However, in FIG. 5, after step S17, the process proceeds to step S30.

In the assumed maximum leakage power specifying step S30, the control unit 270 performs the band passing through the maximum power (assumed maximum received power) assumed in the signal output from the ADC 150 of the channel (reverse adjacent channel) for which scanning processing is performed immediately afterward. The leakage power (TH _next ) is specified from the pass characteristic of the filter 140. For example, in the terrestrial digital broadcasting standard in Japan, it is sufficient to set the leakage power from the assumed maximum received power to −20 dBm. Here, the assumed maximum leakage power (TH _next ) may be calculated from the broadcast standard to be received, the pass characteristics of the band pass filter 140, and the like, and is calculated in advance from these, and is stored in the storage unit 270a of the control unit 270. May be stored. Here, it is assumed that the assumed maximum leakage power TH _next is stored in advance in the storage unit 270a.

In the second power threshold determination step S31, the control unit 270 determines the TH _next specified in the assumed maximum leakage power specifying step S30, and the reference set in the first threshold setting step S15 or the second threshold setting step S16. The comparison value is calculated by adding the value TH. When the power P _k is larger than the above-described comparison value (TH + TH _next ) (Yes in S31), the process proceeds to the channel signal validity determination step S19, and when the power P _k is equal to or less than the above-described comparison value ( In S31), the process proceeds to the reverse adjacent channel power calculation step S32.

In the reverse adjacent channel power calculation step S32, the control unit 270 changes the scan target channel to the next channel (k + 1ch), and calculates the power (reception power) P _{k + 1} of the signal output from the ADC 150 in the changed channel. .

In the reverse adjacent channel leakage power calculation step S33, the control unit 270 leaks from the power of the channel (k + 1ch) next to the scan target channel calculated in the reverse adjacent channel power calculation step S32 and the pass characteristic of the band pass filter 140. The electric power (TH _leak2 ) is calculated. More specifically, the control unit 270 calculates the area ratio (coefficient) that can be calculated from the channel interval, the channel bandwidth, and the pass characteristic of the bandpass filter for the channel calculated in the reverse adjacent channel power calculation step S32. Leakage power is obtained by multiplying power. For example, it is assumed that the area ratio is calculated in advance and stored in the storage unit 270a of the control unit 270.

In the threshold update step S34, the control unit 270 determines the reference value TH set in the first threshold setting step S15 or the second threshold setting step S16, and the leakage power TH _leak2 calculated in the reverse adjacent channel leakage power calculation step S33. And the reference value TH is updated to a new reference value TH #. Then, the process proceeds to a third power threshold determination step S35.
The updated reference value TH # is a threshold value for determining whether or not a valid signal is included in the channel.

In the third power threshold determination step S35, the control unit 270 compares the power P _k calculated in the power calculation step S17 with the reference value TH # updated in the threshold update step S34. If power P _k is larger than updated reference value TH # (Yes in S35), the process proceeds to channel signal validity determination step S19, and if power P _k is equal to or lower than reference value TH (S35). In No), the process proceeds to channel signal invalidity determination step S20.

  In this way, when the control unit 270 performs reception confirmation while changing the scan target channel, leakage power leaks into the target channel from the adjacent channel (the channel on which the scan process was performed immediately before) of the target channel. In addition to changing the threshold value according to the magnitude of the threshold value, the threshold value is also changed according to the magnitude of leakage power that leaks into the target channel from the channel adjacent to the target channel (the channel on which scanning processing is performed next). By doing so, the reliability of the determination result from the signal presence determination step (third power threshold determination step S35) is increased.

Here, the control unit 270 determines the maximum power assumed as the reverse adjacent channel of the target channel before calculating the leakage power that leaks into the target channel from the reverse adjacent channel of the target channel (the channel in which the scan process is performed after the target channel). When the leakage power from the power is calculated and it is determined that the influence of the leakage power of the reverse adjacent channel can be ignored by the power P _{k of the} target channel, the process of calculating the power and leakage power of the reverse adjacent channel is not performed. If it is determined that the influence of the leakage power of the reverse adjacent channel cannot be ignored by the power P _k of the target channel, the tuner frequency setting is set to the reverse adjacent channel of the target channel (the channel on which scanning processing is performed one after the target channel). The process of changing and calculating the power and leakage power of the reverse adjacent channel is performed.

FIGS. 6A and 6B are schematic diagrams for explaining an operation example when a channel scan is performed in the processing flow of FIG.
Here, the channel scan is performed from the lower frequency to the higher frequency, and as shown in FIG. 6A, broadcast signals exist in the channels CH1 to CH3 and the channel CH5, and the channel It is assumed that there is no broadcast signal on CH4.

In this case, as shown in FIG. 6B, in the channels other than the channel CH4, the channels adjacent to the target channel (CH1, CH2, CH3, and CH5) (the channel on which the scan process was performed immediately before; None, leakage power TH _leak from CH1, CH2 and CH4 <power TH _n and leakage power TH at the maximum power assumed from the reverse adjacent channel (channel to be scanned one after; CH2, CH3, CH4 and none) _{Even when next} is considered, the threshold value (TH + TH _next ) <power P _k . Therefore, it can be determined that these channels are effective channels.

However, regarding the channel CH4, the leakage power of the channel CH3 is considered, and the leakage power TH _leak > power TH _n is satisfied, but the threshold TH (= TH _leak ) <power P _k (k = 4). The validity of the channel signal is determined by the method of the first mode. Here, in the method according to the second embodiment, since the leakage power of the maximum power assumed from the channel CH5 is taken into consideration, the threshold (TH + TH _next )> power P _{k is} satisfied, and actually the power P _k (k = k = channel CH5). By calculating the leakage power amount TH _leak2 from 5) and updating the threshold value TH, the threshold value TH (= TH _leak + TH _leak2 )> power P _k (k = 4) is obtained. For this reason, channel CH4 can be determined to be an invalid channel.

  Thus, according to the broadcast receiving device 200 and the broadcast signal receiving method thereof according to the second embodiment, when determining the presence / absence of a signal of the scan target channel, not only the leakage power from the adjacent channel that has been scanned, Next, the presence / absence of the signal of the target channel can be determined with higher accuracy by considering the leakage power from the adjacent channel on which the scanning process is performed. When it is determined that there is no broadcast signal, the scan time can be shortened by changing the scan target to the next channel without performing the subsequent scan processing of the scan target channel.

  For example, in a digital terrestrial broadcast receiving apparatus in Japan, it takes about several hundred milliseconds to calculate the power of a certain channel, whereas it takes several seconds to detect loss of synchronization by the synchronization acquisition process. In the second embodiment, it takes about several hundred milliseconds more than in the first embodiment to consider the leakage power of the adjacent channel that performs the scanning process next to the target channel. However, as shown in FIG. As in the case of the existing channel CH4, it is determined to be an effective channel even though it is an invalid channel, and it takes several seconds to determine it as an invalid channel by detecting loss of synchronization by the synchronization acquisition process. That is, in the case of the channel CH4 shown in FIG. 6B, as a result, the processing time in the second embodiment can be shortened.

In the embodiment described above, the presence / absence of a signal is determined using the leakage power TH _leak , TH _leak2, or the power TH _n due to noise or the like. For example, the leakage power TH _leak , TH _leak2 is _determined as noise or the like. The presence / absence of a signal may be determined using a value added to the power TH _n as a reference value TH.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

  100, 200 broadcast receiving device, 110 RF signal amplification unit, 120 local oscillator, 130 mixing unit, 140 band pass filter, 150 analog-digital converter, 160 demodulating unit, 170, 270 control unit.

Claims (9)

A bandpass filter that passes a signal of a frequency corresponding to the target channel as a channel selection intermediate frequency signal from the received radio signal;
By calculating the power of the channel selection intermediate frequency signal of the target channel that has passed through the band pass filter, and comparing the calculated power with a first threshold, the broadcast program assigned to the target channel It is determined whether or not a broadcast signal is included in the target channel, and based on the determination result, a control unit that controls whether or not to stop subsequent scan processing in the target channel, and
The control unit calculates the first leakage power leaking into the target channel from the power of the first adjacent channel adjacent to the target channel, and according to the calculated magnitude of the first leakage power, Changing the first threshold;
The first adjacent channel is a channel that has been scanned before the target channel is scanned,
The broadcast receiver according to claim 1, wherein the power of the first adjacent channel is calculated from the channel selection intermediate frequency signal that has passed through the band pass filter during the scan processing of the first adjacent channel. The broadcast according to claim 1, wherein the control unit uses the first leakage power as the first threshold when the first leakage power is larger than a predetermined value. Receiver device. 3. The control unit according to claim 2, wherein the control unit uses the predetermined value as the first threshold when the first leakage power is equal to or less than the predetermined value. 4. Broadcast receiving device. The first leakage power increases as the power of the channel selection intermediate frequency signal calculated when the band-pass filter passes a signal of a frequency corresponding to the first adjacent channel is larger. The broadcast receiving apparatus according to any one of claims 1 to 3. The control unit is a coefficient determined by the characteristics of the band pass filter in the power of the channel selection intermediate frequency signal calculated when the band pass filter passes a signal of a frequency corresponding to the first adjacent channel. The broadcast receiving apparatus according to claim 4, wherein the first leakage power is calculated by multiplying. The control unit compares the calculated power of the channel selection intermediate frequency signal of the target channel with a comparison value larger than the first threshold, and selects the channel of the calculated target channel. When the power of the intermediate frequency signal is equal to or less than the comparison value , the power of the second adjacent channel that is scanned after the target channel is calculated, and the power of the second adjacent channel is calculated from the power of the second adjacent channel to the target channel. A second leakage power that leaks is calculated, a second threshold value is calculated by adding the calculated second leakage power to the first threshold value, and the channel selection intermediate of the calculated target channel When the power of the frequency signal is compared with the second threshold value to determine whether or not the target channel includes a broadcast signal, and when it is determined that the target channel includes a broadcast signal Is The subsequent scan processing in the target channel is continued, and when it is determined that the target channel does not include a broadcast signal, the subsequent scan processing of the target channel is stopped. 6. The broadcast receiving device according to any one of 5 above. The broadcast receiving apparatus according to claim 6, wherein the comparison value is a value obtained by adding leakage power at the maximum power assumed as the second adjacent channel to the first threshold value. The control unit, when the calculated power of the channel selection intermediate frequency signal of the target channel is larger than the comparison value, continues the subsequent scan processing in the target channel. 8. The broadcast receiving device according to 7. From the received radio signal, pass the signal of the frequency corresponding to the target channel as the channel selection intermediate frequency signal,
Calculate the power of the channel selection intermediate frequency signal of the target channel,
By comparing the calculated power and the first threshold, it is determined whether the target channel includes a broadcast signal of a broadcast program assigned to the target channel,
A broadcast receiving method for controlling whether or not to stop subsequent scan processing in the target channel based on the determination result,
A first leakage power leaking into the target channel from a first adjacent channel adjacent to the target channel is calculated, and the first threshold is changed according to the calculated magnitude of the first leakage power. And
The first adjacent channel is a channel that has been scanned before the target channel is scanned,
The broadcast receiving method, wherein the power of the first adjacent channel is calculated from the channel selection intermediate frequency signal corresponding to the target channel during the scan processing of the first adjacent channel.

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