JP3059995U - Tuner device - Google Patents

Abstract

(57) [Summary] [PROBLEMS] To accurately fix a reception frequency to an original center frequency of a transmitting station even when an AFC level fluctuates carelessly. SOLUTION: A PLL tuning control unit 8 for controlling an oscillation frequency of a local oscillation circuit 4 performs an AFC operation after detecting a synchronization signal.
By performing the operation of detecting the level change point at twice by changing the frequency change direction, the PLL lock operation for locking the center frequency to the reception frequency is performed. At this time, of the two types of thresholds used in the first detection operation, the lower threshold is A1, the higher threshold is A2, and one type of threshold used in the second detection operation. Assuming that the value is B, in the first detection operation, after the synchronization signal detection operation, if the AFC voltage is lower than B, the PLL tuning control unit 8 decreases the frequency until the AFC voltage exceeds A2. When the AFC voltage is higher than B, the AFC voltage
The frequency is changed in the direction of increasing the frequency until it becomes 1 or less.

Description

[Detailed description of the invention]

[0001]

[Technical field to which the invention belongs]

 The present invention relates to a tuner device such as a television receiver or a cable television provided with a PLL tuning control unit for controlling the oscillation frequency of a local oscillation circuit.

[0002]

[Prior art]

 For example, a tuner device of a television receiver provided with a PLL tuning control unit performs a synchronization signal detection operation and an AFC operation during a PLL tuning operation to lock a center frequency to a reception frequency. The operation is performed (for example, see Japanese Patent Application Laid-Open No. 2-86206).

In such a tuner device, after detecting a synchronization signal (hereinafter, referred to as an SD signal) in a PLL channel selection control unit, a detection operation of an AFC level change point (hereinafter, also referred to as an AFC operation) is performed in frequency. By performing the operation twice while changing the change direction, a PLL lock operation for locking the center frequency to the reception frequency is performed.

Here, a conventional SD detection operation and AFC operation will be described. In the SD detection operation, PLL data corresponding to the frequency of the receiving station is output and the SD detection is performed. The detection procedure at this time is as follows. SD detection is performed in such an order that a frequency shifted by 3M ■ is output, a frequency shifted by -2.6M 出力 is output, a frequency shifted by +1.31 is output, and finally a center frequency is output again. It is carried out. When the SD is detected at any point, the operation shifts to the AFC operation at that point.

FIG. 2 is a graph showing a relationship between an SD signal with respect to an AFC voltage and a change point DIR (DI RECTION) of an AFC level. The width of the SD signal is 1.0 to 1.2 M ■ on the minus side and 0. 0 に on the plus side, with IF (45.75 M ■) as the center value. 4 to 0.7 M ■, which is a total of 1.4 to 1.9 M ■. The DIR uses, for example, A / D conversion of AFC input to set “L” for 2.5 (V) or less and “H” for 2.5 (V) or more.

In the AFC operation, the DIR of the AFC is searched by changing the frequency, for example, in three steps (one step is 27.965 K ■). In this case, the AFC voltage is 2. If the AFC voltage is lower than 5 (V) (for example, the position indicated by reference numeral 81 in FIG. 2), the PLL is reduced in the frequency decreasing direction (IF (-) direction) until the AFC voltage exceeds 2.5 (V). Change the data. On the other hand, when the AFC voltage is higher than 2.5 (V) (for example, at a position indicated by reference numeral 82 in FIG. 2), the AFC voltage becomes 2. The PLL data is changed in the direction of increasing the frequency (IF (+) direction) until the voltage becomes 5 (V) or less. This is the first operation (operation 1). That is, the threshold value at this time is 2.5 (V).

Next, when a change point of the DIR of the AFC is found, the frequency is changed one step at a time in a direction opposite to the direction of the operation 1 until the AFC voltage exceeds 2.5 (V). Alternatively, the PLL data is changed until the AFC voltage becomes 2.5 (V) or less, and a change point of the DIR is searched. This is the second operation (operation 2). That is, the threshold value at this time is 2.5 (V), which is the same as in the operation 1. Then, when the change point of the DIR of the AFC is found, the frequency is fixed, the SD detection is performed again, and a series of channel selection operations ends. If the above operation is performed normally, the frequency is fixed at the final tuning point (indicated by reference numeral 83 in FIG. 2) shown in FIG.

[0008]

[Problems to be solved by the invention]

 That is, in the conventional AFC operation, the threshold value for detecting the change point of the DIR of the AFC is set to the same 2.5 (V) in both the operation 1 and the operation 2. However, the AFC level may fluctuate carelessly regardless of the frequency controlled by the PLL tuning control unit. For example, when the frequency actually transmitted from the station deviates from the center frequency of the receiving station based on the PLL data output from the PLL channel selection control unit (for example, -0.5 M ■). A), the AFC level fluctuates carelessly. This is considered to be partly due to the fact that the ripple generated inside the PLL rides on the frequency.

In this case, the frequency at the time when the SD signal is detected is at a position indicated by reference numeral 81 in FIG. At this time, if the AFC level fluctuates as shown by the broken line in FIG. 2, when the operation 1 is started from this point, the AFC level is reached at the position indicated by reference numeral 84 before reaching the original final tuning point. Exceeds 2.5 (V), and the frequency is fixed at the shifted point. In other words, there arises a problem that the receiving frequency cannot be accurately fixed to the center frequency of the transmitting station.

The present invention has been made to solve such a problem. The purpose of the present invention is to change the reception frequency even if the AFC level is inadvertently changed. It is an object of the present invention to provide a tuner device capable of terminating the tuning by accurately fixing the center frequency of the tuner.

[0011]

[Means for Solving the Problems]

 In order to solve the above problem, a tuner device according to claim 1 of the present invention includes a PLL tuning control unit that controls an oscillation frequency of a local oscillation circuit, and the PLL tuning control unit detects a synchronization signal. After the operation, the tuner device configured to perform the PLL lock operation of locking the center frequency to the reception frequency by performing the operation of detecting the level change point of the AFC twice while changing the direction of frequency change, A threshold value for detecting a change point is changed between a first detection operation for detecting a level change point of the AFC and a second detection operation.

In the tuner device according to the second aspect of the present invention, two types of threshold values having a certain width are set in the first detection operation. In the second detection operation, one type of threshold is set. Also, in the tuner device according to claim 3 of the present invention, in the device according to claim 2, the widths of the two types of thresholds used in the first detection operation include the AFC level fluctuation width. The width is set to be as wide as possible.

The tuner device according to claim 4 of the present invention is the tuner device according to claim 2 or 3, wherein the lower one of the two threshold values used in the first detection operation. Assuming that the threshold value is A1, the higher threshold value is A2, and one type of threshold value used in the second detection operation is B, the PLL tuning control unit performs the synchronization signal in the first detection operation. After the detection operation, if the AFC voltage is lower than B, the frequency is decreased until the AFC voltage exceeds A2. If the AFC voltage is higher than B, the frequency is changed until the AFC voltage becomes lower than A1. It is characterized by changing in the direction of increasing the frequency.

According to a fifth aspect of the present invention, in the tuner device according to the fourth aspect, the thresholds used in the first detection operation are A1 (V) and A2 (V), Assuming that the threshold used in the second detection operation is B (V), the value of A1 is set within the range of -0.5 (V) to -1.0 (V) of B, and A2 Is +0. Of the value of B. It is characterized in that it is set within a range from 5 (V) to +1.0 (V).

[0015]

[Embodiment of the invention]

 Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram showing an electric configuration of a television receiver provided with the tuner device of the present invention. In the figure, the output of the high-frequency amplifier 2 to which the receiving antenna 1 is connected is guided to the mixing circuit 3 to which the output of the local oscillation circuit 4 is connected, and the output of the mixing circuit 3 is Is led to. The output of the video IF amplifying circuit 5 is guided to a video signal processing circuit 6, and the output of the video signal processing circuit 6 is guided to a receiver 7 as RGB primary color signals.

A control output of a PLL tuning control unit 8 that controls an oscillation frequency is guided to the local oscillation circuit 4, and the PLL tuning control unit 8 configures a video signal processing circuit 8. As shown, the horizontal synchronization signal separated by the synchronization separation circuit is derived.

Next, a description will be given of a PLL lock operation by the PLL tuning control unit 8 configured as described above, that is, an SD detection operation and an AFC operation. The SD detection operation is exactly the same as the conventional case described above. First, a frequency shifted by -1.3 M ■ from the center frequency of the receiving station is output, and then a frequency shifted by -2.6 M ■. , Then output the frequency shifted by +1.31 and finally output the center frequency again. When the SD is detected at any point, the operation shifts to the AFC operation at that point.

Here, in the present embodiment, the operations 1 and 2 are performed in the same manner as in the above-described conventional case. In this case, the threshold of the operation 1 and the threshold of the operation 2 Is changing. That is, assuming that the thresholds used in operation 1 are A1 (V) and A2 (V) and the thresholds used in operation 2 are B (V), the value of A1 is -0.5 (V) of the value of B. To -1.0 (V), and the value of A2 is set within the range of +0.5 (V) to +1.0 (V) of the value of B. In the present embodiment, the value of A1 is 1. 5 (V), the value of A2 is 3.5 (V), and the value of B is 2.5 (V). However, the values of A1 and A2 with respect to the value of B need only be values that can substantially include the level fluctuation of the AFC (ie, values that are not substantially affected by the level fluctuation of the AFC). According to the results of the experiment, the level fluctuation range of the AFC is in the range of 2.3 (V) to 2.7 (V).

Further, in the present embodiment, as a result of giving a certain width to the threshold value of the operation 1, the operation 1 is slightly different from the conventional case until the change point of the DIR of the AFC is detected. This will take time. That is, the movement width in the IF (-) direction or the IF (+) direction increases. Therefore, in order to solve such a problem, the frequency which is changed by three steps in the conventional case is changed by six steps in the present embodiment. In other words, the above-mentioned inconvenience is eliminated by making the frequency change width twice as large as the conventional one. However, the number of steps is not limited to six steps, but may be, for example, five steps or seven steps.

That is, in the operation 1 of the AFC operation according to the present embodiment, the DIR of the AFC is searched by changing the frequency by six steps (one step is 27.965 K ■). In this case, when the AFC voltage is lower than 2.5 (V) (for example, the position indicated by reference numeral 81 in FIG. 2), the frequency is decreased until the AFC voltage exceeds 3.5 (V) [ IF (-) direction]. On the other hand, when the AFC voltage is higher than 2.5 (V) (for example, the position indicated by reference numeral 82 in FIG. 2), the frequency is increased until the AFC voltage becomes 1.5 (V) or less [ IF (+) direction].

Thus, even if the AFC level fluctuates as shown by the broken line in FIG. 2, this level fluctuation does not exceed 3.5 (V). However, even if there is a change point of 2.5 (V) due to, it changes in the IF (-) direction without stopping at that point. Then, when passing through the final tuning point and changing to a point exceeding 3.5 (V) (the position indicated by reference numeral 85 in FIG. 2), a change point of the DIR of the AFC is detected.

When the change point of the DIR of the AFC is detected, the operation 2 is executed next. This operation 2 is the same as the above-described conventional case. That is, the frequency is changed by one step (27.965 K ■) in the direction opposite to the direction of the operation 1 (in this case, the IF (+) direction) so that the AFC voltage becomes 2.5 (V) or less. Change the PLL data and search for the DIR change point until.

When the change point of the DIR of the AFC is found, the frequency is fixed, the SD detection is performed again, and a series of channel selection operations ends. By the above-described AFC operation, even if the level of the AFC fluctuates due to, for example, the frequency actually transmitted from the station being shifted, the received frequency can be accurately adjusted to the center frequency of the transmitting station without being affected by this. Can be fixed.

[0024]

[Effect of the invention]

 In the tuner device of the present invention, the threshold value for detecting the change point is changed between the first detection operation for detecting the level change point of the AFC and the second detection operation, and the first detection operation is performed. Sets two types of thresholds having a certain width that can include the level fluctuation range of the AFC, and sets one type of threshold in the second detection operation. As a result, even if the AFC level fluctuates carelessly, the reception frequency can be accurately fixed to the original center frequency of the transmitting station.

[Brief description of the drawings]

FIG. 1 is a block diagram showing an electrical configuration of a television receiver provided with the tuner device of the present invention.

FIG. 2 is a timing chart showing a relationship between an SD signal with respect to an AFC voltage and a change point DIR of an AFC level.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Receiving antenna 2 High frequency amplification circuit 3 Mixing circuit 4 Local oscillation circuit 5 Video IF amplification circuit 6 Video signal processing circuit 7 Receiver 8 PLL channel selection control section

Claims (5)

[Utility model registration claims] 1. A control circuit for controlling an oscillation frequency of a local oscillation circuit.
An LL tuning control unit is provided. The PLL tuning control unit performs the detection operation of the AFC level change point twice after changing the frequency change direction after the synchronization signal detection operation, thereby setting the center frequency to the reception frequency. In the tuner device configured to perform the PLL lock operation for locking the AFC, the first detection operation for detecting the level change point of the AFC and the second detection operation
A tuner device wherein a threshold value for detecting a change point is changed between the first detection operation and the second detection operation. 2. In the first detection operation, two types of thresholds having a certain width are set, and in the second detection operation, 1 threshold is set.
The tuner device according to claim 1, wherein a type of threshold is set. 3. The tuner device according to claim 2, wherein the widths of the two types of thresholds used in the first detection operation are set so as to include the range of AFC level fluctuation. . 4. The two thresholds used in the first detection operation, wherein the lower threshold is A1 and the higher threshold is A2, and one of the two thresholds used in the second detection is used. Assuming that the threshold value is B, the PLL tuning control unit changes the frequency in the first detection operation until the AFC voltage exceeds A2 if the AFC voltage is lower than B after the detection operation of the synchronization signal. 4. The tuner device according to claim 2, wherein when the AFC voltage is higher than B, the frequency is changed to increase the frequency until the AFC voltage becomes equal to or lower than A1. 5. 5. The threshold value used in the first detection operation is A
1 (V), A2 (V), and the threshold value used in the second detection operation is B (V), the value of A1 is -0.
It is set in the range from 5 (V) to -1.0 (V),
The value of A2 is from +0.5 (V) to +1.0 (V) of the value of B
The tuner device according to claim 4, wherein the tuner is set within the range of: