JP3052012U - Tuning device - Google Patents

Abstract

(57) [Summary] When an instruction of auto preset is given, the microcomputer 14 sets an initial value of the frequency f _{0 in} the latch register 16, adjusts the frequency f _0, and broadcasts at the lower end of the reception band. The station and the next broadcast station are searched (detected), and the respective channel data are preset in the memory 14a. The microcomputer 14 determines a frequency interval between successive broadcasting stations based on the detected frequencies of the two broadcasting stations.
Thereafter (after the third station), the microcomputer 14 sets the frequency f ₀ of the latch register 16 for each determined frequency interval and performs a search. In this way, the preset of the third and subsequent stations is performed, and the preset can be performed over the entire reception band. [Effect] Since the frequency interval is determined based on the two detected broadcast stations, and thereafter the preset is performed using the determined frequency interval, the preset can be performed in a short time without a channel plan.

Description

[Detailed description of the invention]

[0001]

[Industrial applications]

 The present invention relates to a tuning device, and more particularly, to a tuning device in which, for example, an automatic preset is performed by automatically searching from one end of a reception band to the other end.

[0002]

[Prior art]

 Conventionally, in this type of channel selection device, in many cases, auto preset is generally performed according to a predetermined channel plan.

[0003]

[Problems to be solved by the invention]

 For example, the PAL system is adopted in many countries, and therefore, in order to be able to preset in each country, it is necessary to store a channel plan for each country in a nonvolatile memory. For this reason, there has been a problem that the memory capacity is enlarged, and as a result, the price is high.

[0004] In addition, in the case of performing auto-preset by the voltage synthesizer method regardless of the channel plan, there is a problem that it takes time to complete the preset. Therefore, a main object of the present invention is to provide a tuning device which can be reset in a short time without a channel plan.

The inventor of the present invention has previously developed a channel selection device that can perform auto-preset in a short time without having a channel plan, and has filed an application as Japanese Patent Application No. 9-10353. Using the fact that the station and the broadcasting station are normally open at 6 MHz or more, the search is only performed by jumping over this 6 MHz, so that the shortening of the search time was still insufficient.

[0006]

Means for Solving the Problems The present invention provides a channel selection device in which auto-preset is performed by automatically searching from one end of a reception band to the other end, detection means for detecting two broadcasting stations, A channel selection device comprising: a determination unit that determines a frequency interval between consecutive broadcast stations based on a broadcast station; and a preset unit that performs auto preset using the frequency interval.

[0007]

[Action]

 When an auto-preset instruction is given, the initial value of the frequency is set, and the broadcasting station at one end (lower end) of the reception band is searched. When the first station is detected, the channel data of the first station is preset in the memory. Then, the next (second) broadcast station is detected, and the channel data is similarly preset in the memory. The frequency interval between successive broadcast stations is determined from the detected frequencies of the two broadcast stations. For example, in the channel plan of the PAL system, the frequency interval between successive broadcasting stations is 6 MHz, 7 MHz or 8 MHz (predetermined frequency interval), and these frequency intervals are held in the second holding unit in advance. The difference (frequency difference) between the detected frequencies of the two broadcasting stations is calculated by the difference detecting means, and the calculating means calculates the absolute value of the frequency difference by using one of the frequency intervals (6 MHz, 7 MHz) held in the second holding means. Or 8 MHz). The determining means determines one frequency interval based on the calculation result. Then, using the determined frequency interval (6 MHz, 7 MHz or 8 MHz), the third and subsequent broadcasting stations are searched, and if they are occupied, they are preset. In this way, the preset is performed up to the broadcasting station at the other end (upper end) of the reception band.

[0008]

[Effect of the invention]

 According to this invention, the frequency interval between consecutive broadcast stations is determined based on the two detected broadcast stations, and the third and subsequent broadcast stations are searched and preset at the frequency interval. Even if you do not, you can preset in a short time. The above and other objects, features and advantages of the present invention will become more apparent from the following detailed description of embodiments with reference to the drawings.

[0009]

【Example】

 With reference to FIG. 1, a frequency synthesizer type tuning apparatus 10 of this embodiment includes a tuning operation unit 12, and a frequency f according to a channel selected by the tuning operation unit 12.₀Is supplied from the microcomputer 14 to the latch register 16. Frequency f of selected channel₀Is stored (preset) in a memory 14 a provided in the microcomputer 14.₀And the next (other) frequency f ₀ Hold until is given. Output of the latch register 16 (frequency f₀) Is supplied to the phase detection circuit 20 via the variable frequency divider 18.

The tuning apparatus 10 includes a reference oscillator 22, and a clock pulse generation circuit 24 generates a clock pulse based on an output (oscillation frequency) of the reference oscillator 22 and supplies the clock pulse to the microcomputer 14. The oscillation frequency from the reference oscillator 22 is frequency-divided by a fixed frequency divider 26 at a predetermined frequency division ratio, and is provided to the phase detection circuit 20. In the phase detection circuit 20, the detection output is obtained based on the frequency f ₂ given frequency f ₁ supplied from the variable frequency divider 18 from the fixed frequency divider 26. That is, the detection output when the frequency f ₁ and frequency f ₂ are equal is 0 when the frequency f ₁ is greater than the frequency f ₂ are positive detection output is obtained, the frequency f ₁ is the frequency f _If it is smaller than ₂ , a negative detection output is obtained. The low-pass filter 28 outputs a tuning voltage to the tuner 30 based on the output from the phase detection circuit 20. The oscillation frequency of the local oscillator 30a included in the tuner 30 is controlled by the tuning voltage.

In the tuner 30, a high-frequency television signal received by an antenna (not shown) is amplified by a high-frequency amplifier 30b and mixed with an oscillation frequency from a local oscillator 30a to extract a video intermediate frequency signal. This video intermediate frequency signal is amplified by a video intermediate frequency amplification circuit 32 and supplied from a terminal 34 to a video signal processing circuit (not shown). Further, the oscillation frequency from the local oscillator 30 a is divided by the pre-frequency divider 36 at a predetermined frequency division ratio, and is provided to the variable frequency divider 18. Variable frequency divider 1 8 varies the frequency dividing ratio based on the frequency f ₃ which is supplied from the preceding stage frequency divider 36, the peripheral and the wave number f ₁ and frequency f ₂ is adjusted to be equal.

The output from the video intermediate frequency amplification circuit 32 is provided to an automatic frequency adjustment (AFT) circuit 38. In the AFT circuit 38, a video carrier is extracted, and this video carrier is amplified. The amplified signal has a constant amplitude and is subjected to FM detection. Then, a change in the frequency is extracted as a change in the DC voltage. After this voltage is amplified, unnecessary components are removed and applied to the tuner 30. The local oscillation frequency is corrected by the output (AFT voltage) of the AFT circuit 38, and the intermediate frequency of the video intermediate frequency signal is made constant. The AFT voltage is supplied to the microcomputer 14, and the microcomputer 14 determines whether the setting of the frequency has been completed based on the AFT voltage. That is, when the AFT voltage is fluctuating, it is determined that the broadcasting station is being searched because the local oscillation frequency is being adjusted. On the other hand, when the AFT voltage is constant, since the local oscillation frequency is also adjusted to a constant value, it is determined that the search for the broadcast station has been completed, that is, the broadcast station has been detected.

The output of the video intermediate frequency amplification circuit 32 is provided to a synchronization separation circuit 40, and the horizontal synchronization signal (H _sync. ) _Extracted by the synchronization separation circuit 40 is provided to the microcomputer 14. The microcomputer 14 determines whether there is a video signal based on the presence or absence of the horizontal synchronization signal. That is, when there is a horizontal synchronization signal, it is determined that there is a video signal, and when there is no horizontal synchronization signal, it is determined that there is no video signal.

For example, when an instruction for auto-preset is given, channel data of two broadcasting stations is detected, and a frequency interval between successive broadcasting stations is determined based on frequencies of the two channels. The third and subsequent stations are searched and preset using the frequency interval. More specifically, when determining the frequency interval, first, an initial value of the frequency f ₀ is set. In this embodiment, the initial value of the frequency f ₀ is set to a value smaller than the frequency of the lower end of the reception band of any country. Until the (first station) broadcast station at the lower end of the reception band is detected, the frequency f ₀ is set to a large _value , for example, by 0.5 MHz, and a search for a broadcast station is performed.

When the microcomputer 14 detects a horizontal synchronization signal, an AFT search is performed, for example, at 0.5 MHz intervals. That is, the microcomputer 14 monitors the AFT voltage while adding the frequency f ₀ by 0.5 MH _Z, determines the presence or absence of a broadcasting station. The microcomputer 14 is determines that Yukyoku if the AFT voltage is constant, the AFT voltage is a predetermined frequency width (in this example, 2 MH _Z) when continuing to vary beyond the be determined that no station You. If it is determined that chromatic station may presets the channel data in the memory 14a of the broadcasting station, and 6MH _Z added to the frequency f _0, the following (the two stations th) search broadcasters dividing line. In the channel plan of the PAL system, the frequency interval between broadcast stations consecutive 6 MHz, for a 7MHz or 8MH _Z, is 6MH _Z added in order to reduce the search time.

On the other hand, when a horizontal synchronization signal is detected and an AFT search is performed for a broadcasting station, but when no broadcasting is performed, that is, when an AFT search is performed over 2 MHz, it is determined that the detected horizontal synchronization signal is erroneous. I do. When two broadcasting stations are detected, the microcomputer 14 detects a frequency difference (frequency difference) between the two broadcasting stations, and sequentially calculates whether the frequency difference is an integral multiple of one of the frequency intervals. Is determined based on the above. The frequency intervals (6 MHz, 7 MHz and 8 MHz) of the PAL system are stored in the memory 14b in advance, and one frequency interval according to the channel plan is determined from the frequency intervals stored in the memory 14b. First, the microcomputer 14 divides the absolute value of the frequency difference by eight. If the calculation result (N) is an integer, the microcomputer 14 determines the frequency interval to be 8 MHz, and if not, divides the absolute value of the frequency difference again by 7. If this calculation result (P) is an integer, the frequency interval is determined to be 7 MHz, and if not, the frequency interval is determined to be 6 MHz. Then, the subsequent (third and subsequent stations) broadcast stations are searched at the determined frequency interval and preset. In this way, the preset can be performed over the entire reception band.

The operation described above is performed by the microcomputer 14 according to the flowcharts shown in FIGS. As shown in FIG. 2, when the channel preset is selected, the microcomputer 14 starts the process, and executes a process of detecting a frequency interval in step S1. In step S3, the frequency f ₀ of the second broadcast station is set, and in step S5, it is determined whether the frequency f ₀ has exceeded 900 MHz (the maximum value of the frequency band). Here, if “YES”, that is, if the channel preset has been completed over the entire reception band, the process ends. If “NO”, the frequency interval detected at the frequency f ₀ in step S7. (6 MHz, 7 MHz or 8 MHz). In step S9, it is determined whether the station is a station. If "YES", the channel data is preset in the memory 14a in step S11, and the process returns to step S5. On the other hand, if “NO” in the step S9, the process returns to the step S5 as it is.

As shown in FIG. 3, when the process of detecting the frequency interval is started, the frequency f ₀ is set to an initial value in step S 21. In the following step S23, it is determined whether or not there is a horizontal synchronization signal. If “NO” here, 0.5 MHz is added to the frequency f ₀ in step S25, and the process returns to step S23. If “YES”, the process proceeds to step S27. In step S27, an AFT search is executed, and in step S29, it is determined whether or not the station is a station. If "NO" in the step S29, it is determined whether or not the frequency width searched in the step S31 exceeds 2 MHz. Here, if “YES”, it is determined that the horizontal synchronization signal detected in step S23 is erroneous, and the process returns to step S23. If “NO”, the process returns to step S27.

On the other hand, if “YES” in the step S29, the channel data of the broadcast station detected in the step S33 is preset, and it is determined whether or not two broadcast stations are detected in a step S35. If this case, "NO", that is, if only one broadcast station not Detects returns to step S2 3 to 6MHz added to f ₀ in step S37, it detects the second broadcasting station , "YES", the absolute value of the frequency difference between the two broadcasting stations is divided by 8 in step S39. Subsequently, in a step S41, it is determined whether or not the division result (N) is an integer. Here, if "NO", the absolute value of the frequency difference is divided by 7 in step S43 shown in FIG. 4, but if "YES", the frequency interval is determined to be 8 MHz in step S45 and the routine returns. .

In step S47, it is determined whether the result of the division (P) is an integer. If “YES”, the frequency interval is determined to be 7 MHz in step S49, and the process returns. If “NO”, the process returns. In step S51, the frequency interval is determined to be 6 MHz, and the process returns. According to this embodiment, the lower end of the reception band and the next broadcasting station are detected, and the frequency interval between consecutive broadcasting stations is determined based on the two broadcasting stations. Therefore, there is no PAL channel plan. You can also do presets.

Further, since the third and subsequent stations are searched at the determined frequency interval, the time required for presetting can be reduced. In this embodiment, the presetting is performed from the broadcasting station at the lower end of the receiving band. However, the presetting may be performed from the broadcasting station at the upper end of the receiving band. At this time, the determined frequency interval is subtracted from the frequency f ₀ to determine whether or not the station is a station, and preset is performed.

Further, in this embodiment, the broadcast station at the lower end of the reception band and the next broadcast station are detected to determine the frequency interval, but any broadcast station in the reception band may be detected. Good. Further, in this embodiment, the frequency synthesizer system has been described. However, the same control can be performed in the case of the voltage synthesizer system. That is, first, the tuning voltage is gradually changed to detect two broadcasting stations. Subsequently, a frequency interval between two consecutive broadcasting stations is determined based on channel data of the two broadcasting stations. Then, the tuning control circuit outputs the PWM value of the tuning voltage so as to determine whether the station is a station at each frequency interval, converts the tuning voltage into a voltage value with a D / A converter, and stabilizes with a low-pass filter. The DC voltage is applied to the tuner. In other words, presetting can be performed in a shorter time than when the tuning voltage is gradually changed.

Further, in this embodiment, the case of the PAL system has been described, but it is needless to say that the present invention can be applied to the NTSC system, the SECAM system, and the like, in which broadcast stations are provided at predetermined frequency intervals. In this embodiment, the case where one frequency interval is determined from three frequency intervals has been described. However, one frequency interval may be determined from two frequency intervals. At this time, it is calculated whether one of the two frequency intervals is an integral multiple of the frequency difference, and if it is an integral multiple, the frequency interval is determined. If not, the other frequency interval is determined.

[Brief description of the drawings]

FIG. 1 is a block diagram showing an embodiment of the present invention.

FIG. 2 is a flowchart showing a part of the processing of the microcomputer shown in FIG. 1 embodiment;

FIG. 3 is a flowchart showing a part of the processing of the microcomputer shown in FIG. 1 embodiment;

FIG. 4 is a flowchart showing a part of the processing of the microcomputer shown in FIG. 1 embodiment;

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 ... Tuning apparatus 14 ... Microcomputer 30 ... Tuner 38 ... AFT circuit

Claims (8)

[Utility model registration claims] 1. A tuning apparatus in which an auto-preset is performed by automatically searching from one end of a reception band to the other end thereof. A detecting means for detecting two broadcasting stations; A channel selection device comprising: a determination unit that determines a frequency interval between broadcast stations; and a preset unit that performs the auto preset using the frequency interval. 2. The frequency interval is a predetermined frequency interval.
The channel selection device according to claim 1. 3. The method according to claim 2, wherein the determining unit includes a difference detecting unit that detects a frequency difference between the two broadcasting stations detected by the detecting unit, and determines the frequency interval at which the frequency difference is an integral multiple. Item 3. The tuning device according to Item 1 or 2. 4. The apparatus according to claim 1, wherein said determining means further includes first holding means for holding said two frequency intervals, wherein said frequency difference is not an integral multiple of one of said frequency intervals held by said first holding means. 4. The tuning apparatus according to claim 3, wherein the other frequency interval is determined. 5. The method according to claim 1, wherein said two frequency intervals are 7 MHz and 8 MHz.
The tuning device according to claim 4, wherein the frequency is MHz. 6. The second holding means for holding three or more of the frequency intervals, and determining whether the frequency difference is an integral multiple of any of the frequency intervals held in the second holding means. 4. The tuning apparatus according to claim 3, further comprising calculating means for sequentially calculating, and wherein said one frequency interval is determined based on a calculation result of said calculating means. 7. The channel selection apparatus according to claim 6, wherein said second holding means includes three said frequency intervals, and said three frequency intervals are 6 MHz, 7 MHz and 8 MHz. 8. The preset means includes a storage means for storing channel data of a detected broadcast station, and adds the frequency interval to a frequency of the detected broadcast station. The channel selection device according to any one of claims 1 to 7, which stores the following.