JP2003517235A - How to speed up search tuning in television receivers. - Google Patents

Abstract

SUMMARY The present invention relates to a method for performing search tuning in a television band of a television signal, including both analog and digital television signals. First, an analog channel search is performed to determine all receivable analog channels in the television band. Next, a digital channel search is performed. At this time, the analog channel determined in the analog channel search is skipped. By not necessarily searching for analog channels that have already been determined, considerable time is saved because the digital channel search necessarily uses frequency steps that are significantly smaller than those in the analog channel search.

Description

Detailed Description of the Invention

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to tuning a television receiver connected to a cable subscriber network, and more particularly to a tuning procedure known as "search tuning".

2. Description of Related Art With a few exceptions, television receivers for existing analog television signals can automatically scan for source signals in the frequency domain for available channels, and The signal is stored in memory for later recall. Although various frequency allocation schemes exist for cable networks, the actual situation requires a search algorithm where the amount of exceptions and deviations can look for channels at all frequencies within the band. Searching through all television coverage bands needs to be accomplished within a reasonable amount of time (typically within a minute) to avoid consumer irritation. Fast tuning is achieved by taking relatively large frequency steps at the same time and scanning the band. This is because the demodulator used for a conventional analog television system is, for example, 1000 kHz.
This is possible because it has a relatively large selection of z for false tuning. Although the tuning is not exact, the demodulator can be tuned to the signal and provide the host microcontroller with feedback information about the frequency error, improving the tuning of the tuner to the correct frequency.

[0003] DE19728765A1 automatically tunes and selects television channels in a cable television signal by sequentially outputting tuning data, and outputs tuning data when a signal is input from automatic channel setting. A method of storing a channel in a signal for a television is disclosed.

A typical search tuning system operates as follows. The system first determines if the last channel has ended. If so, the system ends the procedure. The system selects the next channel number if it has not finished.
The channel number is stored in the television receiver along with the nominal frequency of the channel. As shown in FIG. 1A, each channel has a bandwidth of 6 MHz, for example.
To search for a received television signal, the system begins with a first channel subband frequency step, which is the lowest frequency within the channel bandwidth around the nominal frequency of the particular channel, eg, a subband frequency of 1000 kHz. Scan the channel bandwidth in steps. The system then attempts to capture the next television signal. The system then determines if the next television signal has been captured. If captured, the system stores the channel-frequency data. After storing the channel-frequency data, the system returns to the first step to determine if this channel is the last channel number. If the television signal is not captured, the system determines if this is the last channel subband frequency step in the bandwidth of the particular channel. The system selects the next channel subband frequency step if it is not the last channel subband frequency and returns to the step of capturing the next television signal to capture the television signal. If it is the last channel subband frequency step in a particular channel bandwidth, the system returns to the first step to determine if it is the last channel number.

The introduction of some new digital television transmission signals on cable and on broadcast respectively creates a demand for television receivers capable of receiving both analog and digital television signals. The signals supplied to such a television receiver include conventional analog RF signals and 64/2.
It may have a mix of digital (DTV) RF signals which may be 56QAM, 8/16 VSB. However, the demodulator for the DTV has a demodulator oscillator frequency, eg, 50 to 15 of the received DTV signal, to lock the demodulator on the received DTV signal and provide feedback information about the actual carrier frequency.
It is required to be within 0 kHz. This requires that, for search tuning, the band be scanned in significantly smaller steps than used when scanning an analog television channel (eg, 125 kHz, see FIG. 1B),
This considerably increases the search tuning time.

SUMMARY OF THE INVENTION The present invention seeks to minimize the time required to search for tuning for all available television signals in a network carrying a mixture of analog and digital television signals. To do.

To this end, the invention provides the search tuning described in the independent paragraph. The dependent term is
Clarify advantageous embodiments.

Since the DTV signal is not broadcast on the same channel / frequency as the analog television signal, the television receiver does not have to search the entire television frequency to determine the available DTV signal. By first performing an analog television signal search, which may be done relatively quickly, the television receiver may eliminate the determined channel-frequency position of the analog television signal. The television receiver needs to search / scan only at those channel-frequency positions that are not occupied by the analog television signal.

Brief Description of the Drawings In view of the additional objects and advantages described above and below, the present invention will be described with reference to the accompanying drawings.

Description of the Preferred Embodiment FIG. 2 is a block diagram illustrating a television receiver capable of receiving both analog and digital television signals. The television signal is supplied to the television receiver via the antenna 30. While the antenna 30 is shown, it should be understood that the television signal may alternatively be provided by a CATV system or a combination of standard television and satellite antennas and the like. The antenna 30 is connected to a tuner 32 that tunes various television signals. The analog demodulator 34 is connected to the output of the tuner 32 and is connected to the switch 36.
The output is supplied to one of the inputs. Digital demodulator 38 is also connected to the output of tuner 32 and includes a phase locked loop having a tuning resolution of, for example, 62.5 kHz. The output of the digital demodulator 38 is converted by the D / A converter 40 and then supplied to the second input of the switch 36. The output from the switch 36 is provided to an audio signal processor 42 for producing audio signals for loudspeakers 44 and 46. In addition, the output from switch 36 is also provided to video signal processor 48 to generate a video signal for display 50.

The tuning of tuner 32 is controlled by a microcontroller 52 which receives error signals from analog and digital demodulators 34 and 38. Depending on whether an analog or digital television signal is tuned, the microcontroller 5
2 controls the switching position of the switch 36. In addition, the microcontroller 52 provides control signals to the audio signal processor 42 to control the audio parameters of the reproduced audio signal and to the video signal processor 48 to control the visual parameters of the reproduced video signal. Supply control signals. The microcontroller 52 is controlled by a user using a user control 54 or, alternatively, a remote control transmitter 56 that sends an infrared signal to an infrared receiver on the user control 54.

A list of all television channels, as well as their respective nominal carrier frequencies, is stored in the microcontroller 52. While there are actually various allocation plans,
In practice, the actual carrier frequency of the television signal for a particular channel may be different everywhere within the channel bandwidth around the nominal carrier frequency. Therefore,
It is necessary for the microcontroller 52 to perform search tuning to find the actual carrier frequencies of all available television channels.

The procedure by which the television receiver searches and tunes both analog and digital television signals can be described as follows. To begin the procedure, the television receiver performs an analog channel search. This search may be the same as the search shown in FIG. As mentioned above, the magnitude of the frequency step for the analog channel search is set to 1000 kHz, while the magnitude of this step is arbitrary and may be set to other values in the range 750 to 1250 kHz, for example. You should understand that. Following the analog channel search, the television receiver performs a digital channel search, with the procedure terminating thereafter.

The procedure by which the television receiver performs the digital channel search can be described as follows. After performing an analog channel search, the procedure determines if the current channel is the last channel in the television band. If it is the last channel, the procedure ends. If it is not the last channel, the television receiver proceeds to the next channel number and compares this channel number with the channel number of the television signal captured in the analog channel search. If the current channel number corresponds to the stored analog channel number, the procedure returns to the first step. If not, the procedure sets the first channel subband frequency step for the current channel. The television receiver then attempts to capture the digital signal. If a digital signal is acquired, the television receiver stores the digital channel-frequency data and returns to the first step. If no digital signal is acquired, the procedure determines if the current channel subband frequency step is last in the current channel. If not, the procedure proceeds to the next channel subband frequency step and the procedure returns to the digital signal acquisition step. If the current channel subband frequency is the last in the current channel, the procedure returns to the first step.

As mentioned above, the digital demodulator 38 has a tuning resolution of 62.5 kHz. Therefore, in order to ensure that a suitable carrier frequency has been found, the channel subband frequency step size is set to twice the tuning resolution, ie 125 kHz.

In summary, by performing a faster analog channel search first, when the digital channel search is performed, the assigned analog channels may be excluded from the digital channel search, thus saving the television band. Significantly reduces the time associated with digital channel searching to scan and search.

The above embodiments are illustrative rather than limiting of the present invention, and one of ordinary skill in the art can design many alternative embodiments without departing from the scope of the appended claims. It should be noted that. In the claims, any reference signs placed between parentheses shall not be construed as limiting the claim. The word “comprising” does not exclude other elements and steps not listed in the claims. Although the elements are shown in the singular, it does not exclude the presence of a plurality of the same elements. The present invention may be implemented by hardware having several discrete elements and a suitably programmed computer. In an apparatus claim enumerating several means, some of these means may be embodied in one and the same item of hardware. The mere fact that certain measures are recited in mutually different dependent claims does not indicate that a combination of these measures cannot be used to advantage.

[Brief description of drawings]

FIG. 1A shows a television channel showing an analog channel subband frequency step of 1000 kHz.

FIG. 1B shows a television channel showing a digital channel subband frequency step of 125 kHz.

FIG. 2 is a diagram showing a television receiver capable of receiving both analog and digital television signals.

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Claims (10)

[Claims] 1. A method of receiving an input television signal including a plurality of analog and digital television signals, capturing all the analog television signals in the input television signal, and capturing the captured television signal. Capturing all assigned digital channel numbers in the input television signal and capturing an assigned channel number of the captured digital television signal. A method of performing search tuning in a television receiver for both an analog signal and a digital signal, wherein the step of capturing the digital television signal comprises the capturing determined in the step of capturing the analog television signal. The analog television signal Channel - the method comprising the step of skipping the position of the frequency. 2. The step of capturing the analog television signal includes the step of determining whether or not the current channel number is the last channel number, and the step of determining whether or not the last channel number is the last channel number. If it is, the routine ends; if it is not the last channel number, the next channel number is selected; the first channel subband frequency step is selected; Attempting to capture a television signal in the step of capturing the television signal, in the step of capturing the television signal, if the television signal is captured, storing channel-frequency data, the current channel number being Returning to the step of determining whether it is the last channel number, if the above television signal is not captured Determining whether the current channel sub-band frequency step is the last channel sub-band frequency step in the band of the current channel, the current channel sub-band frequency step being the current channel. In the step of determining whether it is the last channel sub-band frequency step within the band of, if it is the last channel sub-band frequency step, whether the current channel number is the last channel number. Returning to the step of determining if it is not the last channel sub-band frequency step and returning to the step of selecting the next channel sub-band frequency step and attempting to capture the television signal. The method described. 3. The channel subband frequency step is from 750 to 1250k.
The method of claim 2 in the frequency range of Hz. 4. The method of claim 3, wherein the channel subband frequency step is 1000 kHz. 5. The step of capturing the digital television signal includes the step of determining whether the current channel number is the last channel number, and the step of determining whether the current channel number is the last channel number. If it is, then exit the routine, if it is not the last channel number, select the next channel number, and compare the current channel number with the stored analog channel number. Including the step of returning to the determination step if the result shows conformity in the comparing step, selecting the first digital sub-band frequency if the result shows no conformance, and the digital channel sub-band frequency. At the stage of capturing the television signal, including attempting to capture the television signal within Then, if the television signal is captured, storing channel-frequency data and returning to the step of determining whether the current channel number is the last channel number, if the television signal is not captured, Determining whether the current channel sub-band frequency step is the last channel sub-band frequency step in the band of the current channel, the current channel sub-band frequency step being the current channel. In the step of determining whether it is the last channel sub-band frequency step in the band of, if it is the last channel sub-band frequency step, whether the current channel number is the last channel number. Return to the step of determining the next channel sub-band frequency if it is not the last channel sub-band frequency step. The method of claim 1, including the step of returning to the step of selecting a wavenumber step and attempting to acquire a television signal. 6. The method of claim 5, wherein the step size of the digital channel band frequency is twice the tuning resolution of a digital demodulator in a television receiver. 7. The method of claim 6, wherein the step size is 125 kHz. 8. The digital channel search includes the step of determining whether or not the current channel number is the last channel number, and the step of determining whether or not the current channel number is the last channel number is the last channel number. The step of terminating the routine, the step of selecting the next channel number if it is not the last channel number, and the step of comparing the current channel number with the stored analog channel number. , If the result shows conformity, return to the decision step, if the result does not show conformance, select the first digital subband frequency, and the television signal within the digital channel subband frequency. In the step of capturing the television signal, the television including: If the television signal is captured, store the channel-frequency data and return to the step of determining whether the current channel number is the last channel number; if the television signal is not captured, the current channel number. Determining whether the channel sub-band frequency step is the last channel sub-band frequency step in the band of the current channel, wherein the current channel sub-band frequency step is in the band of the current channel In the step of determining whether it is the last channel subband frequency step, if it is the last channel subband frequency step, determining whether the current channel number is the last channel number. If not the last channel sub-band frequency step, select the next channel sub-band frequency step. The method of claim 2 including the step of returning to the step of attempting to capture a selected television signal. 9. Means for receiving an input television signal including a plurality of analog and digital television signals; capturing all the analog television signals in the input television signal; and capturing the captured television signal. Means for capturing the assigned channel numbers of the input television signals, and means for capturing all the digital television signals in the input television signals, and capturing the assigned channel numbers of the captured digital television signals. A device for search tuning in a television receiver for both analog and digital signals, the means for capturing the digital television signal being determined by the means for capturing the analog television signal. Of the captured analog television signal Yaneru - apparatus including means for skipping the position of the frequency. 10. A television receiver having a search tuning device according to claim 9, a video signal processor coupled to the search tuning device, and a display coupled to the video signal processor.