KR820002147B1 - Tuning system - Google Patents

Abstract

Feeding binary signal to the display according to the tuning position, the symbol of tuning position is indicated. Feeding binary signal which indicate the tuning voltage to the display, corresponding number is indicated. The tuning system is characterized by the multiplexing system which selects the mode of operations from the above two operations.

Description

Synchronization device

1 is a block diagram of a television receiver using a memory-type tuning device according to the present invention which is easy to adjust by a viewer.

FIG. 2 is a list table showing the binary code format for explaining the operation of the tuning device shown in FIG.

3 and 4 are logic diagrams of embodiments of each part of the tuning device shown in the block diagram of FIG. 1 arranged to facilitate tuning by the viewer.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a tuning device for a television receiver, and more particularly to a tuning device having a memory for storing binary signals representing tuning information.

Recently, various electronic tuning devices for television receivers have been proposed, which have a memory device for storing binary signals representing tuning voltages for controlling a voltage controlled local oscillator to tune various channels selected by the viewer.

Although such a memory type tuning device is convenient and inexpensive compared to other types of electronic tuning devices using frequency synthesizers, programming by producers, and in some cases by individual viewers, introduces tuning information into the memory. There is a drawback to this.

In some types of memory type tuning devices, the capacity of the memory, i.e., the number of locations where information can be stored, is limited when aiming to reduce the cost required for the tuning device. As a result, these tuning devices can store only tuning information for a limited number of predetermined channels, which is smaller than the total number of channels allocated to the television band. The channel favorite of a particular viewer can be determined only by the viewer because of the contents of the broadcast program or the reception state at the place of the viewer. For this reason, in a memory-type tuning device that uses a memory having only a limited number of memory locations, the viewer must program himself. In programming a memory-type tuning device, not only the selection of a predetermined channel, but also a binary signal representing the tuning voltage and channel number indication information corresponding to the predetermined channel must be generated. Viewers familiar with conventional mechanical tuning devices equipped with mechanical rotary channel selector switches are very troubled in programming the memory type tuning devices.

Therefore, the memory type tuning device is preferably configured so that the necessary program processing can be performed as simply as possible.

The problem encountered when programming a memory-type tuning device is that the visual image is related to the channel number. That is, the tuning voltage is adjusted until the visual image is displayed. If the period of identification is not broadcast between the visual image and the viewer does not know in which channel the displayed program is being broadcast, There is no way of knowing which channel the receiver is currently tuned into, so that the corresponding channel number indication information cannot be programmed.

In order to solve this problem, an electromechanical voltage meter which responds to the analog tuning voltage can be provided so that the viewer can recognize the relevant tuning position shown here. As an example, this can be found in reference to the tuning device shown in the "Magnafox Service Manual-703777 Videomatic Tune Assembly" manual No.7353, file volume 12, published by Magnafox Co., Ftwain, Indiana. This will be fully understood.

Electromechanical instruments are relatively expensive and, due to their size, not only do not attract the viewer's attention, but also are difficult for viewers unfamiliar with electronic devices to use. In addition, the electromechanical instrument has the drawback that it is impossible to make an accurate distinction between the tuning positions when the desired channels are in close proximity to one another. As an example, the distinction between channels 4, 5 or 6 becomes difficult.

Rather than the tuning voltage, an on-screen display, in which the channel number is engraved on the display screen as a scale, or a display in which the length of the bar changes along the scale when the tuning voltage is adjusted may be provided. By way of example, reference will be made to the tuning device shown in “General Instrument AY-3-8330 Electronic On-Screen TV-Tuning Scale” available from General Instruments. Although some of the drawbacks of electromechanical instruments are eliminated by these on-screen displays, they also cause difficulties for viewers because they provide analog format information as in electromechanical instruments. In addition, the on-screen display has a problem in practical use because the cost of the tuning device becomes expensive.

Therefore, it is desirable to provide a memory type tuning device having a device which minimizes the possibility of confusion of the viewer and displays the tuning voltage so that the viewer can easily recognize it.

According to an embodiment of the present invention, there is provided a tuning device having a memory device for storing tuning information for various tuning positions selected by a viewer. The multiplexing means has a tuning position code for identifying the tuning position during the normal operation mode period of the tuning device, in which information for selectively tuning the binary signal corresponding to the tuning position to the digital display device is extracted from the memory. To be displayed. Further, the multiplexing means supplies binary signals representing the tuning voltage corresponding to the tuning position to the display device so that a number related to the tuning voltage is displayed during a programming mode period in which a binary signal representing the tuning voltage is generated and introduced into the memory means. Let it be.

The binary signal representing the tuning voltage supplied to the display device is preferably arranged in a predetermined format so that the displayed number is linearly related to the tuning voltage during the programming mode period.

In order to further enhance the viewer's convenience during the tuning period, a binary signal representing a predetermined code may be supplied to the display means so as to be distinguished from the prescribed operation mode during the programming mode period.

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

In FIG. 1, an RF (radio frequency) signal is received by the antenna 12 and supplied to the RF processing circuit 14. The RF signal is filtered, amplified and processed by the RF processing circuit 14. The processed RF signal is supplied to the mixer 16 and synthesized with the local oscillation signal generated by the local oscillator 18 to generate an IF (intermediate frequency) signal. The frequency of the local oscillation signal is controlled in response to the tuning voltage generated by the tuning device 20 according to the channel selected by the viewer, and by combining it with the RF signal, the video, color and audio carriers modulated at a predetermined frequency The excitation IF signal is generated.

The IF signal is supplied to the IF processing circuit 22 where it is filtered, amplified and processed. Part of the IF signal is supplied to the AFT (automatic tuning) discrimination apparatus 24. The discriminator 24 generates an AFT signal that indicates a deviation between the image carrier frequency and its nominal value (eg, 45.75 KHZ in the United States), which may occur due to component aging or ambient operating conditions. This AFT signal is supplied to the local oscillator 18 to modify the tuning voltage so that the deviation between the image carrier frequency and its nominal value is minimized. The output of the IF signal processing circuit 22 is supplied to the signal processing circuit 26. The signal processing circuit 26 processes various components of the IF signal to reproduce the image by the video tube 28 and reproduce the sound by the speaker 30.

The tuning device 20 is a memory type tuning device capable of storing tuning information for tuning a predetermined channel smaller than the total number of channels allocated to the television band.

For example, in the United States, 82 channels (2 to 83 channels) are allocated to television bands by the Fcc (Federal Communications Commission). The tuning device 20 may program only 16 channels desired by the viewer. This is because it is due to the reception characteristics related to the contents of the program or the location of the viewer's residence.

In particular, the tuning device 20 has a tuning voltage memory 112 for storing a binary signal representing a tuning voltage for each of the 16 channels desired by the viewer. The tuned voltage memory 112 has 16 memory locations. Each channel position is for storing 12 binary signals or bits (binary digits) having a logic level "1" corresponding to a relatively high voltage + v, or a logic level "0" corresponding to a grounded signal voltage. 12 memory cells are included. The binary signals accumulated at each memory location are arranged in a straight binary format. The binary format means that 12 binary signals are arranged from 2 ° to 2, respectively, and are arranged to rise from right to left.

Each position of the tuning voltage memory 112 has an address. As will be described later, the tuning voltage information for the selected channel is accumulated in sequentially addressed memory locations as the magnitude of the channel number increases. The four-stage address register 114 is coupled to the tuning voltage memory 112 to display decimal numbers 0 to 15 in successive binary format to address any one of the sixteen positions of the tuning voltage memory 112. Generates four binary signals. The address register 114 is an up / down counter with a binary signal device coupled to a "jam" preset input, such as a CD 4029 integrated circuit available from RCA. ) (Indicated by four binary signals) may be increased or decreased by one decimal in response to a suitable control voltage, as will be described later.

When the position of the tuning voltage memory 112 is addressed, the contents of the addressed position are read out from the tuning voltage memory 112, so that the contents are converted to the corresponding tuning voltage for the local oscillator 18. D / A) converter 116 is supplied.

A 12-step tuning voltage register 118, arranged as an up / down counter for counting in a continuous binary format, is coupled to the tuning voltage memory 112, so that the selected channel during the adjustment operation of the tuning device 20 Twelve binary signals stored in each memory position of the tuning voltage memory 112 representing the tuning voltages for each are generated. During the adjustment operation of the tuning device 20, the contents of the tuning voltage register 118 are increased or decreased by one in response to the control signal generated under the control state of the viewer, and the image reproduced on the video tube 28 is satisfied. Is converted by the D / A converter 116 to the corresponding tuning voltage. The selected one of the binary signals generated by the tuning voltage register 118 is supplied to the channel number display device 120, where the channel number related to the tuning voltage is displayed, whereby as will be described later, It is possible to confirm that the image corresponds to the channel desired by the viewer. The contents of the tuning voltage register 118 are written at the currently addressed memory location of the tuning voltage memory 112 in response to the viewer's control.

The channel number corresponding to the channel selected by the viewer is displayed by the channel number display device 120 in response to the binary signal generated by the channel number register 112. The channel number register 122 becomes two four-stage up / down counters equipped with a device for sending a binary signal to a "jam" (preset) input, such as a CD4029 integrated circuit available from RCA. Each counter generates four binary signals arranged in BCD (binary decimal) format representing decimal numbers 0-9. This is shown in the form of codes corresponding to decimals 0 through 9 of the column labeled "binary" in the table of FIG. The binary signals generated by the first counter represent the least significant digit (LSD) of the decimal number, and the binary signals generated by the second counter represent the most significant digit (MSD) of the channel number. The two counters are cascaded and counted between channel number 02 and channel number 83 in such a way that they increase or decrease in response to control signals generated in response to the control of the viewer.

For the purpose of reducing the number of circuits used in the display device 120, the binary signals representing the LSD and the MSD of the channel number are multiplied in time and processed by the channel number display device 120 continuously. In particular, the binary signal representing the LSD is supplied to the display decoder 124 by the display device multiplexer (MUX) 126 during one unit (UNITS) timing signal period, and the binary signal representing the MSD is 10 units. (TENS) is supplied to the display decoder 124 by the display input multiplexer 126 during the timing signal period. The display decoder 124 converts the four binary signals supplied to its input terminal into seven binary signals corresponding to the display device having seven parts (hereinafter referred to as seven segments). The seven binary signal outputs of the display decoder 124 are supplied to the display output multiplexer (MUX) 128, from which the display output multiplexer 128 outputs an output signal therefrom one unit of the unit of the (UNITS) time signal period. To the seven segment display device 130A indicating the unit and to the seven segment display device 130B indicating the 10 unit of the ten unit time signal period. Seven-segment display devices 130A and 130B in the form of light emitting diodes or liquid crystals comprise seven segments a to g, and the logic level of the respective binary signal supplied to these seven segments (ie, "0" or "1"). Selectively emit light in response to ") to form decimal numbers 0-9. For example, to represent the decimal number 9, segments a, b, c, f and g should emit light. The frequency and duty cycle of the display timing signal are selected such that no flicker in the channel number display is perceived by the viewer.

The LSD and MSD binary signals generated by the channel number register 122 are also supplied to the skip memory 132. The skip memory 132 is a memory including 82 positions each having memory cells for storing one bit. The addresses of 82 positions in the skip memory 132 correspond to 82 channel numbers between 02 and 83. Thus, for example, when channel number register 122 includes a binary signal representing channel number 13, the corresponding memory location of skip memory 132 will be addressed. Skip memory 132 provides an indication, i.e., logic "1", when a particular channel is not skipped because the channel is not a viewer's favorite. In response to the logic " 1 " being present at the location of the skip memory 132, the skip detector 134 generates a skip signal.

The LSD and MSD generated by the channel number register 122 are also supplied to the band selector 136, which may also be a ROM. This band selection signal is generated. Thus, for example, in the United States, the band selector 136 generates respective band select signals corresponding to channels 2 through 6, 7 through 13, and 14 through 83, respectively. The band select signal is supplied to the local oscillator 18 to control its oscillation frequency range. The local oscillator 18 has a variable capacitance diode arrangement, which is selectively switched in the circuit of the oscillator in response to respective band selection signals to determine the frequency range in which the local oscillator 18 oscillates. The specific frequency at which the local generator 18 oscillates is determined by the magnitude of the tuning voltage.

The timing signal for controlling the continuous operation of the tuning device 20 is generated by dividing the clock signal generated by the clock oscillator into various timing periods by the timing and control device 138. The counting operation of the address register 114, the tune voltage register 118 and the channel number register 122 is controlled by controlling the transfer to or from the tune voltage memory 112 and the skip memory in the manner described below. The control voltage for controlling is generated in response to the timing signal and is also generated by the power up detector 142, keyboard 144, mode select switch 146 and skip detector 134. It is generated in response to a signal. The power up detector 142 performs a detection operation when the power supply voltage is supplied to the receiver that is not in the operating state and rises above a predetermined level of the voltage of the power supply supplied to the tuning device 20. Generate a power up (PUP) signal. The keyboard 144 has a push button labeled UP, DN, STORE and ERASE, and when it is pressed by the viewer, a corresponding command signal is generated and supplied to the timing and control device 138. . These command signals indicate whether the contents of the address register 114, the tuning voltage register 118, and the channel number register 122 increase or decrease, and whether data is stored in the tuning voltage memory 112 and the skip memory 132. Or erase from it. The mode select switch 146 has a normal, channel and tuning position for generating a corresponding signal for the purpose of controlling the operation mode of the tuning device 20. The operation of the control and timing device 138 for controlling the operation of the tuning device 20 is clear in detail below. The control and timing device 138 is a timing and control method described in detail in US Patent Application No. 810,877, filed Jan. 28, 1977, entitled "Memory Type Tuning Device with Ease of Tuning." Configured to perform the same operation as the apparatus. The control and timing device 138 may also be used to perform operations stored in the associated memory, as described in Kenting Scott's article "Working With Microprocessors… select the station the Microway," published April 13, 1977. It includes a microprocessor that operates according to a program. The plurality of control connecting lines between the timing and control device 138 and the respective parts of the tuning device 20 are omitted for the purpose of brevity in the drawings. However, the function of these control interconnections will become apparent in the following description describing the operation of the tuning device 20.

In operation, assume that mode select switch 146 is in the NORMAL position. When the receiver is operated, a binary signal representing the lowest channel number, i.e., channel number 02 (channel number indicated by the channel number display device 120), is supplied from the device 123 to the channel number register 122, and the number The binary signal representing (15) is supplied from the device 113 to the address register 114, and supplied to each register in response to the generation of the pup signal. At this time, the contents of the original value of the skip memory 132 corresponding to the channel number 02 are irradiated by the skip detector 134. If logic " 1 " is detected, a skip signal is generated indicating that channel 2 is not desired and should be skipped. If a logic " 0 " is detected, a skip signal (pole, logic maintenance component of the Skip signal) is generated and supplied to the timing and control device 138, indicating that channel 2 is desired and should not be skipped.

In response to the skip signal, the contents of the channel number register 122 are increased by a factor of 1, and the contents of the position of the skip memory 132 corresponding to the next channel are examined. In response to the skip signal, the contents of the address register 114 are increased by a factor of 1, but the contents of the channel number register 122 are no longer increased. At this time, the contents of the channel number register 122 (the body 1 address of the skip memory 132 in which logic " 0 " is detected) are displayed by the channel number display device I20, and the tuning voltage memory 112 is displayed. The content of the first position of is read out and converted into the corresponding tuning voltage.

When the viewer wishes to change channels, he presses either the UP or DN pushbutton on keyboard 144. If the UP push button is pressed, the contents of the channel number register 122 are continuously increased by a factor of 1 until the skip signal is generated by the skip detector 134. When a skip signal is generated, the content of the address register 114 is increased by a factor of 1, but the content of the channel number register 122 is no longer increased. At this time, the channel number of the second desired channel is displayed and a corresponding tuning voltage is generated. The operation of the tuning device 20 when the DN pushbutton is pressed to change the channel is except that the contents of the channel number register 122 and the address register 114 are not increased by a factor of 1, but rather are reduced. Is the same as the operation of the tuning device 20 when the UP pushbutton is pressed to change the channel.

As described above, the tuning voltage for the channel desired by the viewer is stored in consecutive positions of the tuning voltage memory 112 in the same order as the corresponding channel number. To do this, the viewer must first place the mode select switch 146 at its channel position. In response to the occurrence of the channel CHANNEL signal, the contents of the channel number register 122 and the contents of the address register 114 are determined by the channel number of the first channel having a logic "0" at the associated position of the skip memory 232. The associated position of the tuning voltage memory 112 will also be increased until it is addressed in the same way if a PUP signal is generated when the initial receiver is powered up. If no channel is programmed, the channel number 02 will be displayed by the channel number display device 120, and no visible image is displayed on the screen of the image tube 28. This is because no skip bits, i.e., logic " 1 " do not enter the skip memory 132, and no meaningful tune voltage information is included in the tune voltage memory 112. The viewer then needs to program the tuning device 20 to switch the mode selector switch 146 to its tuning mode to generate a suitable tuning voltage as described below, so that the desired indication appears. If any channel is programmed, the channel number for the first channel having the logical " 0 " of the skipped memory 132 is displayed and the associated location of the tuning voltage memory 112 is addressed, thereby displaying the visible image. . At this time, if the desired video is not played back or the video is played but the image quality cannot be improved, the viewer generates a new tuning voltage to the corresponding channel for the purpose of improving the image quality in the manner described below. The reprogramming device 20 may be reprogrammed, or the UP pushbutton on the keyboard 144 may be pressed.

If the viewer presses the UP pushbutton, the contents of the channel number register 122 are increased by a factor of 1 until another scheme SKIP is generated. At this time, the channel number of the next already programmed or unprogrammed channel is displayed, and the associated position of the tuning voltage memory 112 is addressed.

To program or reprogram the tuning voltage, the viewer places the mode select switch 146 at its tune- (TUNE) position, and then presses the UP and DN pushbuttons on the keyboard 144, the video tube 28 The tuning voltage must be changed by changing the contents of the tuning voltage register 118 until the desired image is obtained on the screen.

At this time, before the tuning voltage information is written into the tuning voltage memory 112, it is necessary to ensure the image corresponding to the selected channel into which the tuning voltage information is to be entered. This is because an image corresponding to a channel number different from that displayed by the channel number display device 120 appears when the mode select switch 146 is in its channel (CHANNEL) position. As an example, this occurs when the RF carrier for the selected channel is not sufficient to reproduce a satisfactory image, so that the viewer tunes to the tuning voltage for another channel beyond the exact tuning voltage for the selected channel. Of course, the viewer can wait until the broadcast station identification signal is broadcast to confirm that the display corresponds to the selected channel. However, this is not desirable because it will be different each time programming the desired channel.

In the apparatus of the present invention, the viewer corresponds the display to the selected channel to be programmed by positioning the mode selector switch 146 at its TUNE position and then simply referring to the display of the channel number display device 120. can confirm. When the mode select switch 146 is in its TUNE position, the display input multiplexer 126 sends the binary signals generated by the channel number register 122 indicating the LSD and MSD of the channel number to the remaining channel number. The display device 120 is separated from the display device 120, and instead, the selected one of the binary signals generated by the tuning voltage register 118 representing the tuning voltage is supplied to the rest of the channel number display device 120. As a result, the channel number display device displays a decimal number which is precisely related to the tuning voltage so that the viewer can see an appropriate display of the tuning position. The selected binary signal generated by the tuning voltage register 118 and supplied to the display input multiplexer 126 and the rest of the channel number display device 120 has a corresponding tuning voltage number displayed during the tuning mode period. As will be described later, it is selected to relate directly to the tuning voltage, which is not within the range causing difficulty in judgment for the average viewer. When the tuning device 20 is in the tuning mode for each channel number, the viewer can refer to the tuning voltage table related to the tuning voltage number displayed by the channel number display device 120 so that the viewer can tune in to the TUNE. It may be confirmed whether the image obtained in the mode period and the corresponding tuning voltage correspond to the channel to be programmed.

In order to write a binary signal representing the tuning voltage, the viewer must press the STORE button on the keyboard 144. In response to the generation of the STORE signal, the contents of the tuning voltage register 118 are supplied to and written to the current addressed position of the tuning voltage memory 112. At the same time, a logic " 0 " (provided by flowing the signal to ground) in response to the STORE signal is supplied and written to the current addressed location of the skip memory 132.

If the picture corresponding to the channel to be programmed does not meet the viewer's wishes or corresponds to another channel as determined by the associated tuning voltage number displayed during the TUNE mode period, the viewer must press the ERASE pushbutton. do. In response to the generation of the erase (ERASE) signal, a logic " 1 " (provided by coupling to the + V supply voltage source) is supplied to and written to the current addressed position of the skip memory 132.

After the channel has been programmed, the viewer must place the mode select switch 146 in the CHANNEL position so that the next channel can be programmed or reprogrammed.

In the tuning system 20, B ₁₁ to B ₉ shown in FIG. 1 generated by the tuning voltage register 118 in order to perform numerical display directly related to the tuning voltage generated during the tuning mode TUNE mode. the illustrated 2 "to 2 and ⁹³ most significant bits are supplied by the channel number in binary signals instead of the display-input multiplexer 126 to the display decoder 124 for indicating the MSD's of the 10 units of the timing-signal period corresponding to the tuning voltage register The next three most significant bits corresponding to 28 to 26 shown by B ₈ to B ₆ in FIG. 1 generated by 118 are instead of a one-time timing signal, a binary signal representing the LSD of the channel number during the period. It is supplied to the display decoder 124 by the display input multiplexer 128. In such a configuration, the contents of the tuning voltage register 118 correspond to the maximum tuning voltage from the first limit value corresponding to the minimum tuning voltage. When changing within the range up to the second limit value, the number of display positions of 10 units and 1 unit varies between 0 and 7, depending on the octal code form shown in the column marked "octal" in the table of FIG. Using a three-bit octal code ensures that there are no codes for numbers greater than or equal to 7. Therefore, using this octal code always uses the same binary and hexadecimal codes described above. A code format is generated that allows meaningful numeric display, that is, using the octal format, the channel number display unit 120 changes directly in relation to the tuning voltage between numbers 00 to 77 and the display is tuned to. There is no total gap that occurs when not linearly related to.

In comparison, this is different from the case of using direct binary code or hexadecimal code. Refer to the "2" column in Figure 2 and the table. For example, if a direct binary code of a bit is used by supplying the binary signals B ₁₁ to B ₈ to the channel display 120, each display position of the channel number display 120 is 10 decimal digits, that is, 0. To 9 only. However, after the number 9 is displayed at a certain display position, the four bits corresponding to the display position assume a code configuration corresponding to the number greater than 9, that is, the numbers 10 to 15, so that six code configurations occur separately. do. On the other hand, there is no sign corresponding to the magnitude of the tuning voltage meaningfully, and there is an interval that appears when the display does not directly correspond to the tuning voltage. If a 4-bit hexadecimal code is used as shown in the column labeled "Hexadecimal" in the table of FIG. 2, letters A through F may be displayed for the remaining digits above the digit 9, but this may confuse the viewer. Cause

3 shows the logic circuit of the displayed input multiplexer 126, which supplies the six most significant bits B ₁₁ to B ₆ to the remainder of the octal format channel number display device 20. As shown in FIG. This causes two decimal digits to be linearly related to the tuning voltage during the tuning mode of the tuning device 20. The display input multiplexer 126 of FIG. 3 includes 4 × 4 transfer gates T12a to 312d, 314a to 314d, 316a to 316d, and 318a to 318d arranged in a rectangle. Each transmission gate has an input terminal 301, an output terminal 302, and an input terminal 301, an output terminal 302, and a control terminal 303 for controlling data transmission between the input terminal 301 and the output terminal 320. As long as logic " 0 " is applied to the control terminal 303 of the transfer gate, the input terminal 301 is in the state of the signal level at the output terminal 302 regardless of what signal is supplied to the input terminal 301. It is separated from the output terminal 302 so that the influence is not affected.

When logic " 1 " is supplied to the control terminal 303 of the transmission gate, any signal supplied to its input terminal 301 is transmitted to its output terminal. The output terminal 302 of each transfer gate of the thermal species is coupled to each of the four common output lines 320a to 320d.

Output lines 320a to 320d of the display input multiplexer 126 of FIG. 3 are four lines other than the display decoder 124 of FIG. The input terminal of each transmission gate in a row is coupled to each of four rows of common control lines 322 to 328.

The control signal supplied to each of the control lines 322 to 328 is generated by the four AND gates 330, 332, 334, and 336, respectively.

Note that there are four bits related to the 10 unit and 1 unit position of the channel number indication, whereas there are only three bits related to the 10 unit and 1 unit position of the tuning voltage indication. To correct this difference, a logic " 0 " provided by grounding the signal is continuously supplied to the input terminals of the transfer gates 316a and 318a of the type associated with the 10 unit and 1 unit positions of the tuning voltage number display.

The output of the AND gate 330 becomes a logic "1" so that the 10-unit (TENS) timing signal has a logic "1" and the NORMAL signal or the channel signal supplied to the OR gate 338 is the logic level "1." Has a binary signal indicating 10 units of the channel number, that is, MDS ₃ to MDS ₀ corresponding to bit positions 2 ³ to 2 ⁰ are transmitted to the display decoder 124. The output of the AND gate 332 is logic "1", so that one unit of the channel number when the unit timing signal has a logic level "1" and the normal or channel signal has a logic level "1". A binary signal representing a unit position, that is, LSD ₃ to LSD ₀ corresponding to bit positions 2 ² to 2 ⁰ is transmitted to the display decoder 124. Binary signals B ₈ to B ₆ indicating the position of one unit of the tuning voltage number are displayed only when the output of the AND gate becomes logic "1" and the 1 unit (UNITS) timing signal and the TUNE signal have logic "1". Sent to decoder 124. Gene supplied to the display decoder 124. The signal is decoded according to the code shown in the column labeled "DECODER" in the table of FIG.

In the case of a logic circuit in the indicated input multiplexer 126 shown in FIG. 3, when the contents of the tuning voltage register 118 are changed to change the tuning voltage from one extreme to another, the tuning voltage number is two decimal digits. The corresponding linear relationship is changed between 00 and two decimal numbers 77. Also, since the channel number is two decimal numbers, it can be confusing to the viewer as to whether they are in the tuning unit 20 normal operation mode, channel selection mode or tuning voltage adjustment mode. In order to avoid such confusion, it is desirable to display the tuning voltage during the TUNE mode period by using only one decimal number rather than two decimal numbers. Moreover, in order to avoid confusion, it is preferable to indicate one sign when the tuning device 20 is in the channel mode and another sign when the tuning device 20 is in the tuning mode.

Only three most significant binary signals B ₁₁ through B ₉ (rather than two groups of binary signals B ₁₁ through B ₉ and B ₈ through B ₆ ) so that the tuning voltage is represented by one number rather than two numbers. 126 is supplied. The display input multiplexer 126 supplies the binary signals B ₁₁ to B ₉ to the display decoder 124, and a 7-bit display code is supplied to the one-unit position display device 130 during the one-unit timing signal period. When the tuning voltage changes, the binary signal changes from the code configuration corresponding to decimal zero to the code configuration corresponding to decimal seven. For this reason, there will be no code configuration displayed in a form difficult to determine by the one-unit display device 130A. As a result, the tuning voltage number changes linearly in accordance with the tuning voltage over the tuning voltage range.

To enable the viewer to more clearly distinguish between the channel selection mode and the tuning voltage adjustment mode, when the mode selection switch 146 is in the TUNE position, the viewer presses the UP and DN of the keyboard 144. Unless the tuning voltage is adjusted by the button, the letter “A” corresponding to a properly coded binary signal supplied from the device 148 to the display input multiplexer 126 is displayed continuously at the 10 unit position 130B. Further, the letter "J" corresponding to the appropriately coded binary signal supplied from the device 156 to the display input multiplexer 126 is continuously displayed at one unit position, whereby the symbol "AJ" is displayed during the tuning period. Is displayed. When the viewer adjusts the tuning voltage by means of the UP and DN pushbuttons, a one-digit tuning voltage number that changes corresponding to this is displayed in the one-unit position 130A, and the letter "A" is in the ten-unit position 130B. Is displayed. Since only the three most significant binary signals B ₁₁ through B ₉ are supplied to the channel number display device 120, the tuning voltage changes very slowly, thereby causing the viewer to decode that the tuning voltage does not change in response to control. To solve this problem, two kinds of binary signals indicating the + V voltage source and the ground point signal indicating the sign "-(dash)" are generated by the display input multiplexer and supplied to the display input multiplexer 126. As a result, when the tuning voltage is adjusted during the tuning mode, the two kinds of signals are displayed alternately in place of the letter A at the 10 unit position 130B.

It is preferable to display the letter "A" and the sign "-" displayed alternately with respect to the rate of change of the tuning voltage using a timing signal. The binary signal B ₈ of the tuning voltage register 118 has a rate of change 1/2 of the rate of change of B ₉ , which is the lowest binary signal supplied to the channel number display device 120. Therefore, it is preferable to use this for the said purpose.

To distinguish the CHANNEL mode from the TUNE mode, a binary signal representing the letter "C" supplied by the device 152 and a binary representing the letter "H" supplied by the device 154 The signal is supplied to the display input multiplexer 126. As a result, when the selector switch 146 is in the channel mode, the symbol "CH" indicating the channel alternately with the two-digit channel number is displayed at the 10 unit position 130B and the 1 unit position 130A. do. In order to alternately display two numeric channel numbers and the sign "CH", a timing signal "alternating" having a period of about two seconds generated by the timing and control device 138 is supplied to the display input multiplexer 126. Supplied.

4, a 4x7 transfer gate T is shown. Here, (1) two numeric channel numbers are displayed consecutively during the NORMAL mode period, and (2) two numeric channel number and code "CH" are alternately displayed in the CHANNEL mode. (3a) During the TUNE mode, "AJ" is displayed continuously when the tuning voltage is not adjusted by the UP and DN pushbuttons, and (3b) Pressing UP and DN during the TUNE mode. When the tuning voltage is not adjusted by the button, a one-digit tuning voltage number is displayed at one unit position 130A of the display device, and symbols "A" and "-" are displayed at the ten unit position 130B of the display device. Is displayed alternately.

The configuration of the logic circuit of FIG. 4 is similar to that of FIG. The OR gate 412, the NAND gate 414, the inverter 41b, and the AND gates 418, 420, 422, and 424 provide information about the display decoder 124 such that the above operations (1) and (2) are performed. To control the transfer operation. NOR gate 434 and AND gates 436 and 438 control the transfer of information to display decoder 124 such that the operation of 3a above is performed. The NOR gate 440, the inverter 426, and the AND gates 428, 430, 432 control the transfer of information to the display decoder 124 such that the operation of 3b is performed. The display decoder 124 is configured to decode the four binary signal groups supplied to it, forming a desired number and code according to the code of the column designated as "DECODER" in the table of FIG.

In order to simplify the adjustment of the tuning device 20, it is preferable to display a sign indicating a tuning band at the 10-unit display position 130B, following the display of the tuning voltage number at the 1-unit display position 130A. To realize this, assuming that there are three tuning bands, the binary signals representing the letters "A", "B", and "C" corresponding to the first, second and third tuning bands are respectively displayed in the input / output multiplexer 126. It can also be supplied to. When a tuning voltage for the channel of the first band is generated, a binary signal representing the letter A is supplied by the display input multiplexer 126 to the remaining portion of the channel number display device 120, thereby providing 10 units (130B). The letter "A" is displayed at 1), and the corresponding one-digit tuning voltage number is displayed at one unit position 130A.

The same works in the remaining two bands. In order to detect the band, it is also possible to use a modulo three type up / down counter (ie an up / down counter with three output stages).

Its contents are counted whenever the contents of the tuning voltage register 118 correspond to the magnitude of the maximum tuning voltage, for example, whenever the contents of the tuning voltage register 118 change from logic "1" to logic "0". Decreases by 1. Although the above relates to an embodiment of the present invention, various modifications are possible within the scope of the present invention.

Claims (1)

A memory device for storing tuning information for various tuning positions selected by the viewer, the introduction of the tuning information for the memory device during the programming mode operation of the tuning device, and the memory device in the normal mode of the tuning device; A tuning device for a receiver, comprising: a control device for controlling the extraction of the tuning information from the apparatus, wherein the tuning device is coupled to the control device 138 to cause the tuning device to operate in the normal mode. And a mode selection device 146 for selectively generating a tuning signal for causing the tuning device to be operated in the programming mode, and coupled to the control device to correspond to the tuning position in response to viewer control. A synchronization position device 122 for generating a binary signal, and coupled to the control means, A predetermined code is displayed in response to a tuning voltage device 112, 116, 118 for generating a binary signal representing a tuning voltage corresponding to the tuning position and a coded array of the binary signal, respectively. And display devices 124, 128, 130A, and 130B, and the binary signal corresponding to the tuning position to the display device, and the tuning position code for identifying the tuning position is in response to the normal signal. Supplying a predetermined signal of the binary signal indicative of the tuning voltage to the display device so as to selectively display the number related to the tuning voltage in response to the tuning signal. A tuning device characterized by a multiplexing device (126).

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