DE2542829A1 - ARRANGEMENT FOR VOTING A RECIPIENT - Google Patents

Description

TEXAS INSTRUMENTS INCORPORATED
13500 North Central Expressway
Dallas, Texas, V.St.A.

Arrangement for voting a recipient

The invention relates to television channel selection and, more particularly, to one in solid state technology The arrangement shown for selecting television channels and for displaying the selected channel.

It is known that in conventional tuning arrangements with mechanical rotary switches, as they are currently available for selection of channels used in television receivers, difficulties arise. For example, subject Such mechanical rotary switches a mechanical failure, and they have due to the switch contacts own unreliability bad behavior. Moreover, such mechanical rotary switches did not allow parallel ones Channel access and no direct selection of a desired channel without step-by-step switching through undesired ones Channels. Mechanical rotary switches were also bulky and expensive.

Schw / Ba

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It has therefore been proposed that the difficulties encountered with mechanical rotary switches by using turn off electronic circuit arrangements. However, so far developed electronic channel selection arrangements have been not so versatile that they can be widely used in a wide variety of different types of television receivers and could be used for other applications. For example, certain previously required Developed arrangements for channel tuning capacitance tuning diodes with extremely identical properties, so that impermissible tolerances for the usual fluctuations in the Capacitance diodes were permitted. Others developed so far Arrangements were not sufficiently subdivided into individual assemblies to provide a choice of different types of Channel access or channel display enabled. In addition, there have been developed electronic channel selection assemblies so far not sufficiently economical to manufacture and they required wasteful printed circuit boards or other uneconomical manufacturing processes or constructions. For example, certain required known arrangements expensive potentiometers for each channel that should be tuned.

Furthermore, previously developed electronic voting arrangements corresponded not satisfactory for television receivers. recent requirements regarding the Provisions that require a television voting arrangement to be of comparable skill and quality when coordinating VHF and UHF stations. Such known tuning arrangements made possible in particular did not and did not include the selection and display of selected groups of exact UHF channels Devices for easy changing of selected UHF channels.

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With the aid of the invention, an arrangement implemented in solid-state technology for tuning a television receiver is provided which includes a group of switches each corresponding to a predetermined television channel. An address generator responds to the actuation of this switch in such a way that it generates an address consisting of several bits digital address word is generated, each of which corresponds to one of the switches. A display shows depending on the digital address words visibly indicate which TV channel is currently selected. A tuning memory contains a random memory for storing digital voting words and for outputting the tuning words depending on the address words. A circuit arrangement sets the tuning words into analog signals and controls a varactor diode tuner so that the desired television channel is selected will.

The invention further includes a tuning arrangement For television receivers, a switch matrix for selecting a desired television channel. An address generator generates a unique binary address that corresponds to the selected channel. A tuning memory stores several digital ones Tuning words, and it outputs a digital tuning word depending on each unique binary address. A digital-to-analog converter converts the binary tuning words into an analog signal to achieve the channel tuning from the unique binary address, circuitry generates one of three band select signals. A diode tuner is responsive to the analog signal and the band select signal to auto tune on the desired TV channel.

Also in accordance with the invention is a television channel tuning arrangement created with sequential channel selection,

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the switches to produce an up and down scan indication An up / down counter is responsive to the switches to count clock signals and binary address signals generated. A memory generates unique digital voting words depending on the Address signals. A circuit arrangement effects a vote on the depending on the voting words desired TV channel.

According to a further feature of the invention, a television channel tuning arrangement includes a switch matrix, which can be operated to select a desired TV channel. An address generator generates one of the selected ones Unique binary address corresponding to the channel. A memory stores several digital voting words, one of which each corresponds to a different television channel. A converter converts the tuning words into analog tuning levels. With With the aid of a circuit arrangement, the digital tuning words stored in the memory can be selected in a selected manner be changed. With the help of a circuit arrangement, selected digital addresses can also be skipped / grounded, while the tuning of the tuning arrangement is carried out with sequential channel selection.

According to a further feature of the invention, a television channel tuning arrangement includes a combined sequential and parallel channel selection, a channel selection switch matrix in which each switch is used to achieve parallel selection of a television channel can be operated. Up and down channel selectors can be operated so that sequential selection of the television channels is achieved; the up and down switches are on terminals connected to the switch matrix. A circuit arrangement responds to the actuation of the switch matrix in such a way that

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unique binary address signals corresponding to the selected television channel are generated. Depends on the Actuation of the up and down switches produces a circuit arrangement connected to the switch matrix sequential binary address signals corresponding to the sequential television channels. A tuning circuit causes the Tuning to a selected television channel based on the binary address signals.

The invention will now be explained by way of example with reference to the drawing. Show it:

1 is a schematic view of a first embodiment of a sixteen-channel television channel selection arrangement parallel channel selection with touch keys and with a television tuner with sequential channel selection,

2 shows a twenty-channel television channel selection arrangement with sequential channel selection with illuminated channel lamps,

3 shows a twenty-channel channel selection arrangement with parallel channel selection with pressure holders and light sources arranged next to them,

4 shows a further embodiment of a twenty-channel Dialing arrangement with parallel channel selection with illuminated display filters,

5 shows a channel selection arrangement with sequential channel selection, the has a two-digit numeric 7-segment channel display,

6 shows a twenty-channel dialing arrangement with parallel channel selection, which has a two-digit 7-segment channel display,

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7 shows a block diagram of a sixteen-channel dialing arrangement with parallel or sequential channel selection, which are provided with display signs illuminated by neon lamps is,

8 shows a block diagram of a twenty-channel dialing arrangement with combined sequential and parallel channel selection, which are provided with a two-digit 7-segment display is,

9 is a circuit diagram of an address generator for a sixteen-channel sequential channel selection arrangement,

Fig. 10 is a state diagram to illustrate the operation of the AFC sequence counter with the associated circuit of the arrangement shown in Fig. 9,

11a to 11h show the course of signals in parts of the in FIG circuit arrangement shown during operation,

Fig. 12 is a circuit diagram of a sixteen-channel address counter with parallel channel selection for use together with the sequential channel selection circuit of Fig. 9 »

Fig. 13 is a block diagram of a tuning memory for use with the address generator with sequential channel selection according to Fig. 9 or with the address generator with parallel channel selection according to Fig. 12,

14 is a schematic circuit diagram of a twenty-channel address generator with combined sequential and parallel channel selection according to Fig. 8,

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Fig.15 is a block diagram of a tuning memory for the Use with the address generator to select 20 channels according to Fig. 14,

16a and 16b are schematic circuit diagrams of the tuning memory of Fig. 15,

17a to 17h show the course of signals in part of the Tuning memory according to Fig.i6,

Fig.18 is a schematic circuit diagram of the decoder and the driver circuit for the selection arrangement shown in FIG. 7 for the selection of 16 channels and

Fig. 19 is a schematic circuit diagram of the display memory and the 7-segment decoder of the selection circuit according to FIG. 8 for the selection of 20 channels.

In the drawing, Figures 1 to 6 show different embodiments of tuning devices for a television receiver, which are provided according to the invention. Referring to Fig. 1, a television receiver 10 includes a conventional one Screen 12 and a control panel 14. A picture and sound control group 16 contains variable controls for Control volume, image brightness, contrast, hue and color saturation. A microphone 18 receives Ultrasonic commands from a remote control device.

To select VHF television stations is a group of 12 push-button or touch switches 20 are provided. A group of four push button or touch key switches 22 are provided for selecting UHF television channels. You can select one of the VHF channels 2 to 13

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the switches 20 are pressed in a selected manner. The digits 2 to 13 can be permanently set on the push-button switches 20 be attached; however, it can also be labeled with signs in a selected manner attached to or removed from switches 20 to 60 will. Pressing the switch 20 causes the selected switches and the corresponding sign are illuminated so that the operator knows that the desired Channel has been selected for playback.

The switches 22 can also be equipped with removable labels, so that in one to be described below Way any selected group of VHF and UHF television channels can be selected. In the illustrated Embodiment, four UHF television stations can be selected by pressing the switches 22. That Pressing one of the switches 22 results in the selected switch and the corresponding label designation be illuminated. In the illustrated embodiment, four UHF channels are provided for selection, but In the case of further embodiments of the invention to be described below, the possibility of selecting one larger or smaller number of UHF channels can be provided. As will be described later, the initial Tuning the television receiver 10 entered the desired VHF and UHF channels into the system, and into the Push button switches 20 and 22 are set with the desired Channel identification labels inserted. If desired, VHF and UHF channels can be selected changed at any time in selected ways.

For use with the tuning arrangement to be described here A remote control tuning device is provided which has an on / off button 26. It is a

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Up button 28 provided which can be depressed so that a sequential channel selection is made possible by the tuning arrangement of the television receiver 10 from a channel is changed to a channel with a higher number of channels. A down button 30 is provided which is depressed can be so that an automatic sequential selection of television channels is effected in the television receiver 10, by switching the tuning of the receiver from one channel to a channel with a lower number of channels.

As previously mentioned, one of the push button switches 20 and 22 can be selectively depressed and the television receiver 10 is then automatically tuned to the desired channel. That kind of choice is called selection with parallel channel selection. The type of serial channel selection made using the remote control tuner 24 is called sequential channel selection. Of course, it could be on the remote control tuner 24 a group of buttons can be provided so that with the aid of the remote control tuning device 24 a parallel selection of channels is enabled. The remote control device 24 operates according to one of the known methods, for example by generating acoustic signals with the help of tuned circles be detected in the television receiver 10 to enable the channel selection.

A voltage up programming switch 32 and a voltage down programming switch 34 are attached, for example, behind a removable plate on the television receiver 10, thus enabling the initial tuning to the VHF and UHF channels which can be selected by operating switches 20 and 22. For initial programming the tuning arrangement for the selection of a desired channel, the operator first makes the channel

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jump circuit and the AFC circuit (which will be added later are described) ineffective, and she then presses the first VHF switch 20, which corresponds to channel 2. The two Programming switches 32 and 34 are then momentarily pressed to clear the system. The programming switch 32 is then pressed until channel 2 appears on the screen. When either of the programming switches 32 or 34 is longer than a preset period of time is pressed, for example longer than 8 seconds, then the dialing arrangement switches to a quick voting mode around. When the image appears on the screen 12, the programming switch 32 is released, and when it is again Depressing the programming switch 32 or the Programming switch 34 switches the dialing arrangement back to the slow tuning mode. The switches 32 and 34 can then be operated intermittently for fine-tuning the program on the screen 12.

When channel 2 is tuned, the next switch is pressed and the same sequence of operations becomes available for selection of VHF channel 3 performed. If all VHF channels have been programmed, the four selected UHF channels are programmed in the same way, and labels with the inscriptions v / earth designating the selected UHF channels added to the switches 22. if it If desired, fewer VHF channels and more UHF channels can be programmed into the dialer. If all Switches 20 and 22 have been programmed, the snap circuit is put back into operation and it is needed only one of the switches 20 or 22 are pressed or otherwise operated, whereupon the television receiver 10 automatically tuned to the desired channel while the operated switch is illuminated.

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In Fig.2 is another embodiment of the in Fig.1 shown television tuning arrangement; The same reference symbols are used for identical and corresponding parts. In this embodiment is on the front panel the television receiver 10 does not provide for parallel access to television channels; it's just one sequential channel selection provided for 20 channels. Twelve lamps are each labeled from 2 to 13, so that they display a desired VHF television channel when they light up. A second group of lamps 38 are used to display eight selected UHF channels. the Labels attached to the lamps 36 are permanent attached, while the labels on the lamps can be removed and changed if desired. the special UHF channels that can be selected and illuminated with the aid of the lamps 38 are used by the Operator selected by a step-up voltage programming button 40 and a voltage down programming button 42 in the manner described above be operated.

An up channel advancement button 44 and a down channel advancement button 46 can optionally be printed by the operator to cause lamps 36 and 38 to be sequential light up. When the lamp corresponding to the desired channel is lit, the button 44 or button becomes released and the television receiver 10 is tuned to the desired illuminated channel. Of course you can in the arrangement shown in FIG. 2, there is also a sequential channel selection with the aid of a remote control device as the device shown in Fig.1 can be provided. In addition, a parallel channel selection can be provided with the help of remote control devices associated with the required

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Number of push-button selector switches are provided.

As indicated, the initial programming of the channels associated with lamps 36 and 38 is in the above described manner achieved by the voltage programming buttons 40 and 42 actuated v / earth. In some cases it may be desirable during the sequential To skip certain channels during the dialing process. To skip a channel, a jump switch is opened, and the channel is selected. Both buttons 40 and 42 are then pressed briefly at the same time, and the jump off switch will then be closed. A subsequent actuation of the tuning arrangement leads to skipping of this channel so that the lamps 36 and 38 corresponding to the skipped channels do not light up this way, tuning through ineffective or unwanted channels is not required when valid Channels are searched.

Fig. 3 shows a third embodiment of the television channel selection arrangement according to the invention, the selection of the VHF channels with the help of twelve push-button switches 50 made possible, each of which is provided with a suitable channel label. There are twelve at switches 50 Lamps or light emitting diodes 52 attached, which light up when the associated switch 50 is pressed. To choose from UHF channels, eight push button switches 54 are along with eight light emitting diodes 56 are provided, which light up when the corresponding switch is pressed. Inscription labels can be used to designate the special UHF channels that are to be selected in the push-button switches be inserted. A step-up voltage programming

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Switch 58 and a down voltage programming switch 60 can be used during initial programming of the television receiver 10 can be operated so that the channels selected by means of the pushbutton switches 50 and 54 are tuned will.

4 shows a further embodiment of a channel selection and channel display arrangement according to the invention. Twelve push button switches 62 can be printed to select VHF channels v / earth. The push-button switches 62 are assigned lamps 64, which are provided with labels that light up when the lamps are pressed by pressing the corresponding push-button switch 62 can be switched on. To select the UHF channels, 8 or a selected smaller number of push-button switches can be used 66 can be printed. Eight lamps 68 have selected labels corresponding to those desired UHF channels. The labels can be selected in a selected way by removing tags that hold the labels and can be changed by selecting new labels with different labels. An up voltage programming button 70 and a voltage down programming button 72 enable tuning to desired channels selected using pushbutton switches 62 and 66 should. It should be noted that a remote control device can also be provided if desired like the device of FIG. 1 for controlling a sequential selection of channels in the Arrangement according to Figures 3 and 4 can be used. In addition, those shown in FIGS. 3 and 4 can be used Selector assemblies also include up and down channel selectors to be built in.

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Figure 5 shows a station selection and display arrangement in which a sequential channel selection using an up channel advancement button 74 and a down channel advancement button 76 is made possible. The channel number of the channel currently being displayed on the screen 12 becomes with a two-digit 7-segment display 78. In this embodiment, the channel numbers are the VHF channels contained in a read-only memory (ROM); they are not programmable. The channel numbers of the UHF channels, dismit help of the display 78 are selected by operating a display programming switch 83, the is pressed until the correct number is displayed; then it is released again. In operation, the operator pushes either the up button 74 or the down button 76; when the desired television channel number appears on display 78, the operator releases, and the television receiver is tuned to the desired channel.

In Fig.6 is a modification of the one shown in Fig.5 Arrangement shown in which a parallel channel selection with the aid of a switch field 84 is provided. The switch panel 84 can consist of mechanical push-button switches or touch keys with removable shields » so that the number of channels can be changed. When operating the arrangement shown in Figure 6 the desired channel is selected by simply pressing a switch in switch field 84 that corresponds to the desired channel corresponds to, is pressed or operated. The desired number of channels appears in display 78, and the television receiver is automatically tuned to the playback of the desired channel.

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Tuning arrangement for sixteen channels with neon display

7 shows a tuning arrangement for sixteen channels with a neon lamp indicator. This tuning arrangement can zmr to achieve the functions of the in Fig.1 up to 4 illustrated systems can be used. The terminals of a 4x4 pushbutton switch matrix 90 are with a Parallel address generator 92 connected, the binary address signals to a multi-core bus from the four lines 94, 96, 98 and 100 to a tuning memory 102 and to a neon display 104. A second serial address generator 93 is also connected to lines 94, 96, 98 and 100. The multi-core bus allows a modular construction of the dialing arrangement, so that different displays and address generators in a simple Wise can be used to provide a wide range of desired functions. An up push button switch 106 and a down push button switch 108 connected to the address generator 93 to enable sequential channel selection if desired. the Address generators 92 and 93 generate an AFC hold-off signal on lines 110, which is used to eliminate the function Automatic Frequency Control (AFC) is used during the tuning process. From the tuning memory 102 a jump signal is applied to the generator 93 via the line 112, which means that predetermined tuning positions are skipped during sequential channel selection. The switch 113 can be toggled so that the function skipping is made ineffective during the initial setting process. The switch 113 can mechanically with be coupled to the AFC switch so that the AFC function is eliminated during jump programming.

For programming the tuning memory to enable to select the desired channels, an upward push button

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switch 114 and a push-button down switch 116 are used. The selected ones stored in tuning memory 102 Binary words are applied to a digital-to-analog converter 103 which modulated with regard to the duty cycle Generated binary signals that are input to the analog integrator, which in turn the varactor diode tuner 120 feeds. The tuner 120 operates in a known manner such that the local oscillator of the television receiver for Selection of the desired television channels and the RF resonant circuits (not shown) to filter out undesired ones Signals are changed. Band selection signals are transferred from the tuning memory 102 to the base terminals of the transistors 122 created. The collector connections of the transistors 122 are connected to the base connections of the transistors 124, so that band select signals UHF ·, HVHF and LVHF are generated, which the varactor diode tuner 120 to select the varactor diode group that is required to carry out the desired voting process. The production the band selection signal is automatic; there is none except during initial programming Activity of the operator of the television receiver required.

The address signals generated by the address generators 92 and 93 are supplied by the multi-core bus also applied to a neon display driver 104 which enables transistors 130 and lines 132 so neon lamps contained in a 4x4 display matrix 134 be supplied with energy in selected ways. The neon display 104 responds to those of the Generators 92 and 93 generated address so that that neon lamp within matrix 134 is energized corresponding to the depressed pushbutton switch in matrix 90 to indicate which

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TV channel is currently tuned. The neon lamps may or may not be incorporated into switches 90 (Figure 1) be arranged next to the switches 90 (Fig. 3).

Upon actuation of the selection arrangement of Fig.7 in the Operating mode with parallel channel selection, one of the switches of the matrix 90 is actuated. The address generator 92 provides determines which push-button switch has been operated and generates a four-bit binary address lines 94-100 to tuning memory 102. In response The tuning memory applies a tuning word stored in it to the digital address to the digital-to-analog converter 103 at. The converter 103 converts the binary word into a binary signal modulated with regard to the pulse duty factor um, which controls the integrator 118, which generates an analog voltage, and this voltage to the varactor diode group im (tuner 120 that has been selected by the band selection signals. Such varactor diodes tuner are known; they generally work as voltage variable capacitors that are used to A local oscillator and an HF oscillating circuit frequency can be changed to achieve the channel tuning. The ones from Address signals generated by the address generator 92 cause either of them to be energized via the neon display driver 104 Neon lights in matrix 134 to indicate which channel is currently playing.

When operating the dialing arrangement of Fig. 7 with serial or sequential channel selection becomes the up channel selector 106 or channel down button 108 depressed by the operator. The address generator 93 generates then a series of addresses for tuning memory 102 so that a series of binary words stored in memory 102 are stored to the digital-to-analog converter 103 and

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can be applied to the integrator 118. To the capacitance diode tuner 120 then a series of analog voltages is applied so that one channel at a time is ready for playback is selected. The address from the address generator 93 is also applied to the neon display driver 104 so that the lights of matrix 134 are turned on in sequence to indicate which channel is currently playing will. If, by looking at the lit lamp in matrix 134, the operator recognizes that the desired channel is playing, he releases his finger from the buttons 106 or 108, and the television receiver is properly tuned. As mentioned earlier, desired channels can be set by pressing the up voltage programming button 114 and the down tension programming button 116 can be programmed to skip channels during sequential tuning will. In this case, the tuning memory 102 operates to skip the unused position, and neon display matrix 134 does not display the skipped channel display.

Tuning arrangement for twenty channels with numeric display

In Fig. 8 a tuning arrangement is shown, which is shown in to a certain extent is similar to the arrangement shown in FIG. for this reason are equal and corresponding to each other Parts used the same reference numerals. In this embodiment, a 5x4 pushbutton switch selector matrix 140 is provided, sd that 12 VHF and 8 UHF channels can be selected. Of course, the display shown in FIG can also be used in the tuning arrangement shown in FIG. 7 and vice versa; the arrangements shown are only examples.

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In the embodiment of Fig.8 contains a multicore Bus 5 address lines 94, 96, 98, 100 and 101 connecting between an address generator 141 and a tuning memory 143 run. An advantage of the tuning arrangement shown in Figure 8 is that both the up channel selection switch 106 and the down channel selector switch 108 are connected to the terminals of the matrix 140 so that no additional chip pins are required. In addition, the jump signal supplied via the line 112 is is applied to the address generator 141 via the matrix 140. The arrangement of FIG. 8 can be used in a system according to Figures 5 or 6 can be used; it can also be used in a channel selection arrangement in which both the upward channel advancement button 74 as well as the downward channel advancement button 76 of FIG. 5 and that shown in FIG Push button switch panel 84 on the front panel of the same Find television receiver application.

The mode of operation of the arrangement shown in FIG. 8 is the same that of the arrangement of Fig. 7 with the exception that the five Address lines from the address generator 141 are applied to a display memory 145, the control signals for a 7-segment decoder 142 generated. The decoder 142 and the display memory 145 can be formed on separate chips be; they can also be combined in one circuit. The decoder 142 controls the two-digit 7-segment display 147 so that the channel on which is currently just voted is visibly displayed. If desired, instead of the digital output and Display of the neon lamp display driver shown in Fig. 7 be used.

Address generator for an i6-channel dialing arrangement with sequential channel selection

In Fig.9 is a program generator 92 for sequential channel selection for use with the dialing arrangement of Fig.7 shown schematically. As described below, the in Fig.9 shown circuit with the one shown in Fig.12 Circuit can be combined so that the manufacturer is able to select the serial and / or parallel channel selection. An advantage of the circuit shown in Figure 9 is that it is all on a single semiconductor chip 16 pin can be fabricated using conventional integration techniques.

Referring to Figure 9, there is an up channel selection push button switch 150 connected to a terminal pin 152 of the semiconductor chip, and it is connected via inverting buffers 154 and 156 to one Terminal of a NAND circuit 158 connected. Likewise, a downward channel select push button switch 160 is also included a pin 162 of the semiconductor chip, and it is connected via inverting buffers 164 and 166 to a Terminal of a NAM) circuit 168 connected. The NAND circuits 158 and 168 are to form a fiip-flop circuit connected with each other. The outputs of NAND circuits 158 and 168 are to the up and down inputs an up / down 4-bit counter 170 with several presettable counting capacities (multi-modulo counter) connected »The counter 170 enables the Circuit arrangement, either 6, 8, 12 or 16 television channels To choose as you wish. So that the counter 170 is set so that it selects a predetermined Number of television channels, the pins 172 and 174 are selected in a manner corresponding to one conventional code grounded or left open.

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The output signals of the counter 170 are made through NAND circuits 176, 178, 180 and 182 pins 184, 186, 188 and 190 are fed to make up four bits existing binary address is generated which is applied to lines 94, 96, 98 and 100, as previously shown in Figure 7 became. The channel jump signal, which will be explained later in connection with FIG. 13 or other figures Circuit arrangement is generated, is an input of an OR circuit 196 via inverting buffers 192 and 194 fed. The output of the OR circuit 196 is passed through an inverter 198 to enable incrementation of the counter 170 is controlled so that for each input signal on the channel hop line, a memory address is skipped.

An oscillator 200 generates clock signals that a 3-bit AFC sequence counter 202 are supplied. The output C of the counter 202 is an output clock signal that the second input of the OR circuit 196 is supplied. The output of the inverter 192 is applied to the oscillator 200 as an extension signal, and the output signal of the inverter 194 is supplied to the counter 202 as a clear signal. The counter's 3-bit output signals are fed as input signals to a NAND circuit 204, the output signal of which is sent as an enable signal to the oscillator 200 is created. The signals from the outputs A and B of the counter 200 are fed to a NAND circuit 206, its output signal via a NAND circuit 208 and an inverter 210 to an input of an OR circuit be applied so that a stretched AFC shutdown signal is produced.

The outputs of inverters 156 and 166 are on the inputs of an OR circuit 214 are applied, the output of which is connected to a NAND circuit 216. Of the

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The output of the NAND circuit 216 is at inputs of the NAND circuits 176 to 182 connected. In addition, the output of the NAND circuit 216 is connected to a NAND circuit 220 leading pin 218 located on the chip associated with Fig.12 is described. The output of NAND circuit 220 is input via pin 222 the NATTO circuit 216 is supplied. The NAND circuit forms a hold circuit that allows the manufacturer of the television set to either use the circuit sequential Channel selection according to Fig. 9 or the circuit with parallel channel selection according to Fig. 12 or both circuits to be selected. The output of NAND circuit 216 also becomes the Load input of the counter 170 supplied.

Figures 10 and 11 help explain the mode of operation the dialing arrangement shown in Fig.9. Fig. 10 FIG. 9 shows a state diagram which shows the various operating states © of the AFC sequence counter arrangement of FIG shows sequential channel selection. 11 illustrates the course of various signals in sections of the circuit arrangement of Fig. 9. If desired, set the television receiver in sequential channel selection mode only To operate, pin 222 is grounded so that the circuit arrangement of Figure 9 is activated will; the circuit to be described in connection with FIG. 12 is not installed. This ground connection will manufactured by the manufacturer of the television set after determining the type of channel selection controller desired. If the manufacturer decides to do so, both the circuit arrangement of FIG. 9 and the circuit arrangement are grounded of Fig.12 is used so that both the sequential and the parallel channel selection are possible. After this Applying ground to pin 222 produces the

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NAND circuit 216 outputs a signal with the signal value ¹ M "which allows data to pass through NAND circuits 176, 178, and 182.

According to FIG. 10, the counter 202 is set to the counter reading 111 at the beginning of the operation of the circuit arrangement from FIG. When the operator presses the upward channel select button 150 or the downward channel select button 160, the counter 202 advances to the count 000 where it generates a station change signal; then it switches to the counter readings 001 and 010. During the counts 000, 001 and 010, the NAND circuits 206 and 208 decode the output signals of the counter and they generate the AFC shutdown signal via the OR circuit 212. During the remaining counts 011, 100, 010 and 110, the operator decides whether the selected channel is the desired channel or not. When the desired channel is present, the operator releases buttons 150 or 160 and terminates operation of the dialer. During this operator recognition time, the oscillator 200 is enabled via the NAND circuit 204 and cannot be stopped during these operating conditions until the operator _{removes his or her finger from the up T} or down select buttons 150 or 160, respectively. In any case, the counter 202 only stops at the counter reading 111.

If the particular selected station is not the desired station, the operator continues to hold the finger on one of the buttons 150 or 160, and the counter 202 switches to count 111 and then to count 000 further, so that a station change signal is generated for the counter; then the cycle is repeated. The counter 170 then generates a new binary address on the pins 184-190. However, if during one

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Counter reading a jump signal is generated, then this jump signal from the NAND circuit 196 via the Inverter 198 is fed to counter 170 so that the counter advances by one count for each jump signal will. One or more memory addresses are then skipped and a new cyclical run begins, The resulting output signals of the counter 170 for a valid channel consist of a unique binary word with four bits, which is decoded in the following circuit will.

Reference is now made to a sequence counter 202 and the associated circuit of FIG. At the output of the OR circuit 214 appears a signal with a low logic signal value, which is an input of the NAND circuit 204 is supplied so that the output signal of this NAND circuit 204 assumes a high signal value, which the Oscillator 200 enables. The counter 202 then continues to count in full cycles until a signal with a low logical signal value the signal value "1" at the enable output of the NAND circuit 204. When the low signal level applied to the NAND circuit 204 is no longer present, the output signal of the NAND circuit 204 generates the conditions for the counter 202, that it stops when the counter reading appears at its output the next time, whereby the cycle ends will.

In FIG. 11, the signal curve 11a shows the depression of the upward channel selection button 150 by the operator during the time period t to t _Q. The waveform indicated in FIG. 11b illustrates the capacitor charging voltage generated in the oscillator 200. The interval indicated by arrow 230 indicates the generation of several channel jump pulses, while the interval indicated by arrow 231 indicates a jump

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impulse displays. The signal course given in Fig. 11d shows the output signal of the oscillator 200, which is fed to the sequential counter 202 to advance it. The waveform of FIG. 11e comprises the eight operating states of the counter 202, which are described above in connection with Fig.10 have been described. The first three states O, 1 and 2 of each cycle result in the AFC shutdown function.

The waveform of Fig.11f is the clock output signal of the counter 202, that of the OR circuit 196 and the NAND circuit 203 is supplied. Due to the generation of channel jump signals, the clock output pulse 232 is lengthened. The waveform of FIG. 11g shows the channel jump signals which are transmitted via inverters 192 and 194 of OR circuit 196 is supplied to ground. As mentioned, the channel jump signals generated in a circuit to be described below are generated, thus invalid Channels that do not contain a program in a certain area, from the circuit arrangement described here not run through v / earth. During the interval indicated by the arrow, five jump signals are generated, so that five invalid channels are skipped. During interval 236, an invalid channel is skipped. The waveform given in Fig.11h shows the clock signals generated by the OR circuit 196 and im Inverter 198 for clocking counter 170 can be negated.

During the operation of the circuit of Figure 9, the depression of the up channel selector 150 causes the counter 170 to have 4-bit address words in an ascending order at pins 184, 186, 188 and 190. These address words are used in the memory circuit shown in FIG supplied so that memory words are selected,

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which in turn cause the control of the varactor diode tuner. Depression of the downward channel select button 160 has an operation of the counter in the down-counting mode, so that from the counter 170 address words with decreasing sequence are generated. As mentioned, the number of address words generated by counter 170 thereby becomes controlled that the pins 172 and 174 in selected Way to be placed on earth.

Address generator for a 16-channel dialing arrangement with parallel channel selection

Fig.12 shows an address generator 92 for parallel Channel selection made using integration techniques on a single 18 pin semiconductor chip v / can earth; it is used in the circuit arrangement of FIG. The circuit of Fig.12 can be used instead the circuit of Fig. 9 or used together with this will.

As already mentioned, the are shown in Fig. 9 and Fig. 12 Circuits connected to one another via a common NAND circuit, the connections of which are selected in a selected manner can be connected to ground so that the manufacturer of the television set can either use the circuit of Fig. 9 or the circuit of Fig.12 can use. When the terminals of the NAND circuit are cross-connected, both circuits are for released for use.

In Figure 12 is a 4x4 array of 16 touch key switches or another type of switch in the form of a switch matrix 240. Four terminals of the matrix 240 are to one Amplifier stage with four line scan amplifiers 242 connected, while the remaining four connections of the matrix 240

609816/0731

connected to four line scan amplifiers 244. the Outputs of the amplifiers 242 are connected to a 4/2 coding circuit 246. The outputs of amplifiers 244 are with a 4/2 coding circuit 248 is connected. The outputs of amplifiers 242 are also applied to a NOR circuit 250, the output of which is fed to a NAND circuit 252. The outputs of the amplifiers 244 are connected to the inputs of a NOR circuit 254, the output of which is connected to an input the NAND circuit 252 is connected.

The two output signals of the coding circuit 246 are via Time delay elements 256 and 258 of a 4-bit hold circuit 260 supplied. The output of NATID circuit 252 becomes to charge the hold circuit 260, and it is also applied to the AFC shutdown unit 266. The AFC shutdown unit 266 generates an AFC shutdown signal that is triggered via the previously in FIG. 9 OR circuit 212 shown is conducted. The connector pin 268 connects the OR circuit 212 to the circuit shown in FIG shown semiconductor chip, while the pin is the OR circuit with the circuit arrangement of Fig.9 connects. The outputs of the latch 260 are passed through NAND circuits 274, 276, 278 and 280 to thereby a four-bit binary address is generated at pins A, B, C and D.

When operating the circuit of Fig.12. can the manufacturer one of the address generators of FIG. 9 and FIG. 12 or select both address generators by selectively grounding the terminals of NAND circuit 220 or connected to each other. In some cases, the circuit shown in Fig.9 is used as the circuit for remote control Channel selection is used, while the circuit of Fig. 12 is used as the circuit for channel selection via the control panel of the television receiver is being used. If one of the

ρ η α ρ - ρ / ρ 7 Ή

Is pressed, one of the amplifiers 242 and one appear at the output the amplifier 244 a signal with the signal value "0". NOR circuits 250 and 254 then generate output signals with the signal value "1", which is transmitted via the NAND circuit 252 to issue an AFC shutdown signal of circuit 266 trigger. In this way, the automatic frequency control (AFC) is activated during the tuning process. the dialing arrangement is switched off, and it also turns on extended AFC shutdown signal generated after the Operator has released the button.

Encoding circuits 246 and 248 detect outputs from amplifiers 242 and 244 and transmit encoded ones Signals via the time delay elements 256 to 264, which result in sufficient time delays for the holding circuit 260 can be loaded depending on the signals generated by the NAND circuit 252. From the coding circuits 246 and 248 become a four-bit binary code group for storage in the hold circuit generated. The hold circuit 260 then generates a four-bit digital output code group through the NAND circuits 274-280. The outputs of NAND circuits 274-280 cannot go to the pins A through D transmit v / ground until the NAND circuit does not generate a "1" signal that represents the Inputs of the NAND circuits 274-280 is supplied. The NAND circuit 220 also causes overdrive of the output signal of the circuit arrangement shown in FIG.

If the circuit arrangements shown in Figures 9 and 12 are used simultaneously, care must be taken that the state of the shown in Fig.12

Circuit arrangement in the parallel circuit of Fig. 9 is saved. It is assumed that the circuit arrangement shown in FIG. 9 is in the upstream channel selection mode is switched and that the circuit arrangement shown in Fig.12 is then switched on, wherein a channel is selected by her. If the operator then tries to go back to the one shown in FIG To fall back on circuit arrangement, it is desirable to do so with the last of the shown in Fig.12 Circuit arrangement selected channel to begin. Thus, the data word generated by the 4-bit latch circuit 260 becomes also applied to the output of the circuit arrangement of FIG. If so the circuit arrangement of Fig. 9 is not active, a load signal is generated by the NAND circuit 220 and sent to the counter 170 via the inverter 286 applied so that it is loaded with the output signal of the circuit arrangement shown in Fig.12.

Abs timip stores for _M the selection order with 16 channels

Fig. 13 shows a schematic circuit diagram of the previously in 7 shown tuning memory 102. This circuit can in one or in both circuit arrangements according to Fig. 9 or 12 or used in other circuits that use a similar technique. The binary Address output signals of the circuits previously described in Figures 9 and 12 are applied to inputs A, B, C and D of the circuit of Fig. 13 are applied, and they are applied to a 4/16 decoding circuit 290. The resulting Word enable signals are sent to a random memory 292, in which sixteen band reversal, each consisting of two bits

16/0731

Switching and channel jump words are stored, as well as one Random memory 294 in which sixteen, twelve bits each existing tuning voltage words are stored, supplied. The random memories 292 and 294 contain binary coded ones Words indicating the TV channel to be skipped and LVHF, HVHF, and UHF band switching information and define an analog voltage value which is used to control a desired varactor diode in the tuning arrangement is used . Data multiplexing circuits control the input and output of the in random memory stored data. Data multiplexing circuits 298 control the input and output of those stored in random memory 294 Data. A DC voltage, which typically comes from a battery, is applied to the connection pin 300, so that the memory contents of the random memories 292 and 294 during the time period between the construction by the Manufacturer and the application is protected by the user. It gets such a voltage from a storage battery applied to the pin 300 that a protection of the in content stored in the random memories of up to 2 months.

The output of the random memory 294 becomes a one Presettable asynchronous ones with a capacity of 12 bits Up / down counter 302 fed to a 12-bit data comparator 304 supplies output data. A synchronous binary counter with a capacity of 12 bits 306 also supplies binary signals to the comparator 304, which then has an output signal via the inverter 308 which represents the digital data from the random memory in a predetermined output sequence.

6098 1 6/073 1

The predetermined output sequence is supplied with a high frequency frequency so that the integration capacitor in the integration filter of the digital-to-analog converter can be as small as possible. The output signal applied to pin 310 through inverter 308 is then applied to a D flip-flop and an integration filter, so that the desired analog voltage for Control of the varactor for tuning the television receiver is generated.

A clock signal with a frequency of 1 MHz is transmitted via the Pin 312 and an inverter 314 for clocking the synchronous binary counter 306 supplied. The counter 306 also becomes a countdown and frequency selection circuit Clock signals supplied, which generates clock signals for a tuning program generator 320. The generator 320 is activated by pressing the voltage up programming button and voltage down programming button 324 is loaded. the Operation of the programming buttons has been described above in connection with FIGS. 1 to 6. The buttons 322 and 324 are used to set the tuning voltage for the Program the VHF and UHF channels selected by the dialer. The generator 320 becomes the Counter 302 up / down clock and load signals supplied those for programming those stored in random memory 294 Binary words are used. The generator 320 also generates read / write signals for the data multiplexing circuits of random memory 294.

Program tape and channel skip signals are applied to pin 325 and from there to a tape / skip program generator 326, the read / write signals for the data multiplexing circuits 296 and clock signals for an asynchronous 2-bit counter 330 are generated. The band selection signals and the channel skip information is generated by a generator 334 and applied to pins 336, 338, 340 and 342,

2b42829

so that it becomes the varactor diode tuner in the manner shown in FIG gelarLgen. The dqm becomes asynchronous counter 330 the data multiplexing circuits 296 are supplied with data containing get from these circuits to generator 334 *

When operating the tuning memory circuit shown in FIG assume that the system is initially dated Should be programmed by the manufacturer. A rechargeable battery is connected to pin 300 to protect the contents of random memories 292 and 294. To the Both the up button 322 and the down button 324 become tuned to the first valid VHF channel 2 at the same time pressed for a short time. The generator 320 generates such a signal that the up / down counter 302 only signals rait the signal value "0" which are then loaded into the random memory «Since only signals are now in the random memory with the signal value "0" are present, which is a known Initial state results, the up button 322 is now pressed. After a predetermined period of time, for example after 8 seconds, the circuit arrangement changes from a slow operating mode to a fast operating mode, to

■■■■■ '"*

the button is released. Since the circuit arrangement from If the logic zero state starts off, the first channel is channel 2; the operator then releases the button. When the button is released, the circuitry goes into over the 8 second slow mode and the operator can alternate tuning buttons 322 and Press 324 to fine tune channel 2. This process is repeated by the manufacturer until all VHF channels have been selected. The selected UHF channels can be selected in the same way, usually by the user. It should be noted that in the case of channels whose binary data word is more like a word consisting exclusively of the values "1" than a word exclusively

word consisting of the values "0" is the same (above the middle of a tape), after resetting the memory, preferably the down button is pressed so that down is counted and the frequency is approached from above and not from below, as described above.

After the user has purchased a television receiver, it may be desirable to skip certain program channels, that are not available in the user's reception area. The television receiver is used to skip a channel addressed to the memory address of the channel to be skipped. The up button will be pressed at the same time 322 and down button 324 are pressed, and two data signals are entered into random memory 292 for that channel entered with the value "0". When the channel hop generator 334 receives the two data signals sent from the random memory 292 with the value "0" detects, it generates the channel skip signal, so that this channel in an operation with sequential Channel selection is skipped.

When the circuit arrangement is in operation, the random memory receives 292 the data input word consisting of two bits from the counter 330 via the multiplexing circuits 296. The word is stored in random memory 292 and later to generator 334 through multiplexing circuits 296 transmitted so that the band switching signals for the capacitance sdiodentuner generated via pins 336-340 will.

The 1 MHz clock applied to pins 312 causes the counter 306 to advance to the comparator 12 provides output signals and changes synchronously. The comparator 304 sets that from the random memory 294 via the Up / down counter 302 generated binary word into an output

B η q «·· F / η 7 3

2b42829

signal that is output via the inverter 308. The output signal has a duty cycle that is the desired DC voltage level corresponds. The output signal of the comparator 304 thus consists of data words that have a have such a duty cycle that a desired analog voltage is generated when they are integrated. That I the fastest changing) least significant bit from the synchronous binary counter 306 is transferred to the most significant bit from random memory 294 so as to achieve a maximum ripple frequency of the pin supplied output signal a maximum cross coupling is achieved.

It should be noted that to achieve input signals other types of digital sampling arrangements instead of the synchronous counter 306 and the for the integration circuit Comparator 304 can be used. Such a scanning arrangement is for example in the patent application P 25 14 388.8. For the counter 306 and the comparator 304, the multiplier circuit of FIG Texas Instruments, type SN 74 97, uses ground.

In the United States of America, the lower VHF band (which is released via connector pin 340) is out of five VHF channels 2 through 6, while the upper VHF band (which is enabled via pin 338) consists of seven VHF channels 7 to 12. The (via the connector pin 336 shared) UHF band, however, may consist of 70 channels. When fine-tuning in the course channel selection, more bits are required to fine-tune each VHF channel than to fine-tune each UHF channel. The down count and frequency selection circuit 318 generates depending on which band is enabled, a fast or a slow tuning voltage. If on pin 336

609816/0731

2b4282S

the signal for the UHF band is generated, a signal is sent to the frequency selection circuit 318 via the line 350 is applied so that the tuning program generator 320 is supplied with a slower clock signal.

Dialing arrangement with combined serial and parallel channel selection for 20 channels

Fig. 14 shows a schematic circuit diagram of the address generator 114 for use in the 20-channel dialer arrangement of Fig. 8. An advantage of the circuit arrangement shown in Fig.i4 is that with the help of a a single 18-pin integrated semiconductor chip, both a serial and a a parallel channel selection is also achieved.

In the circuit shown in Fig.i4 is a 4x5 switch matrix 360 provided with 20 push-button switches, which correspond to the arrangements with parallel, channel selection of Figures 1, 4 and 6 can correspond. A push button 362 for upward sequential channel selection and a push button 364 for a downward direction sequential channel selections are connected via switch matrix 360 to enable sequential channel selection. These Upward and downward channel selection can also be performed using a remote control device be achieved. The channel skip signal from the memory chip likewise arrives via the switch matrix 360 to the semiconductor chip containing the address generator.

The terminals of switch matrix 360 are connected to a group of output buffers 366 and input buffers 368. The outputs of the input buffers 368 are connected to a 5/3 line encoder 370. The entrances to the Output buffers 366 are connected to a 2/4 row decoder 372. The outputs of the encoder 370 are connected to the data

ppq q ι jρ / ρ 7 i '■

" ° " 2B42829

clamp D, - ,, D ₇ . and D "of a 5-bit presettable up / down counter 374 connected. The inputs of the decoder 372 are connected to the inputs D. and Dt of the counter 374. The outputs of the counter 374 are connected to pins Ag; they form the five-bit output signal which is applied from the address generator 141 to the tuning memory 143 shown in FIG.

The output signals of the input buffers 368 are also fed to the inputs of an OR circuit 376, the output signal of which the load input of the counter 374 and an input of a NAND circuit 380 via an inverter 378 will. The NAND circuit 380 is connected together with a NAND circuit 382 to form a flip-flop circuit. The output signal of the NAND circuit 382 is fed as an input signal to an OR circuit 384, the output signal of which is fed via an inverter 386 to the clock input of the counter. The output of NAND circuit 382 becomes also applied as an input signal to a NAND circuit 388, the output signal of which is fed to an 'OR circuit 390, the AFC sequence counter having a capacity of 3 bits 392 supplies a clear signal.

The outputs A, B and C of the counter 392 are NAND-connected 394, whose output signal is via the NAND circuit 396 is fed to the counter 392 as a clock signal. The signal from counter 392 appearing at output C ″ is supplied to the OR circuit 384 as a serial clock signal. The signals at the outputs A and B of the counter 392 are transmitted via a NAND circuit 398 and a NAND circuit 394 and via an inverting buffer 402 to cause the generation of an AFC shutdown signal.

R Π 9 R ' Β / Π 7

An oscillator 404 generates clock signals which are fed to the clock input of a 2-bit sample counter 406. The NAND circuit 388 generates a clear signal which is passed through OR circuit 390 to counter 392 and also to the sample counter 402 is applied. The signals at outputs A and B of sample counter 406 are sent to decoder 372 created. The signal at output B of the sampling counter 406 is fed to the NAND circuit 396 as an input signal, serving as a clock signal for counter 392.

The input signals and the output signals of the output buffers 366 are fed via inverters as input signals to the UK ⁷ DJ circuits 408 and 410, the outputs of which are fed to an OR circuit 412 via inverters. The output signal of the OR circuit 412 is fed to an input of the NAND circuit 394 via an inverter. The output signal of the oscillator 404 is applied to the inputs of the NAND circuits 416 and 416 via an inverter 416. The output signal of the NAND circuit 416 is fed to an input of an OR circuit 420 and to an input of a NAND circuit 422. The output signal of the NAND circuit 418 is fed to the second input of the OR circuit 420 and to an input of a NAND circuit 424. The NAND circuits 422 and 424 are connected together to form a flip-flop circuit for generating up control signals and down control signals for the counter 374.

When operating the circuit arrangement shown in Fig.i4 can have both a sequential and a parallel number of channels be achieved. The local oscillator 404 controls the 2-bit sampling counter 406, which is in the usual way. The two binary outputs of the counter are connected to the connections D. and Dg of the up / down counter 374 connected to the parallel load data inputs of this

609816/0731

Counter 374 are. The output signals of the counter 406 are also fed to the 2/4 line decoder 372, the binary code into a 1-out-of-4 code. The output signals of the deociderer 372 are fed to the output buffers 366.

The outputs of output buffers 366 are high 25% of the time and low 75% of the time. Signals with a high signal value are thus applied one after the other to the four vertical lines of the switch matrix 360 when the circuit arrangement is in the operating mode with parallel channel selection. If the operator presses one of the 20 buttons on the switch matrix 360 and one of the signals on the vertical lines is high, the signal on the corresponding horizontal line also goes high; this state is input via the input buffers 368 and via the 5/3 line encoder 370. The encoder 370 converts the signal into a binary code group which corresponds to the three most significant bits of the address code group and is fed to the parallel load data inputs of the up / down counter 374. The OR circuit 376 NORs the "0" signals at the inputs of the encoder 370, so that each input signal at the encoder 370 that changes to a low signal value causes the corresponding 3-bit binary code group to be loaded into the counter 374 . At the same time, the 2-bit code group applied to connections D. and D ″ is loaded into counter 374.

As long as the operator keeps his finger on one of the pushbuttons in the switch matrix 360, the logic circuitry 376, 378 and 390 a signal for clearing the counter 392 is generated. The counter 392 and its associated The circuit thus work in the same way as the counter 202 in FIG

60981 6/0731

Circuit of Fig.9. When the circuitry in the Operating mode with parallel channel selection, a signal with the signal value "1" appears on line 430, so that the NAND circuit 382 a signal with the value "0" gives away. The up / down counter 374 is provided via the OR circuit 384 and the inverter 382 are not supplied with clock signals. The operation of the shown in Fig.i4 The circuit arrangement thus resembles the mode of operation of the circuit arrangement shown in FIG.

If desired, the circuit arrangement of Fig. 14 To operate in serial channel mode, either button 362 or 364 is pressed to activate the corresponding vertical line in switch array 360 is grounded. The AND circuit 408 or the AND circuit 410 represents the up / down operation by detecting the case where the output buffer 366 is the transition of the signal on line B to the high signal level, but this transition does not occur when the down button 364 is depressed can so that the down command is generated. Likewise, AND circuit 408 sets up operation fixed, which occurs when the output buffer 366 makes the transition of the signal - request the high signal level on line A, but with the up button 362 depressed, see above that the line is connected to ground. The outputs of the AND circuits 408 and 410 are sent to the NAND circuits 416 and 418 and NAND with the short output pulse from the inverter 414 and the oscillator 4o4 combined. The output signals of the NAND circuit 416 and 418 are applied to OR circuit 420 which detects a "0" signal to one of the NAND circuits and to set the serial side of the flip-flop circuit formed by NAND circuits 380 and 382. Setting the

ρΠ η ο "ρ / η 7

The serial side of the flip-flop circuit outputs clock signals to the up / down counter 374 enables OR circuit 384 to operate the circuit.

Further output signals of the AND circuit 408 are negated and applied to the OR circuit 412 which detects a signal of the value "O ^ at one of its inputs. The detection of the signal with the value "O" through the OR circuit 412 causes the generation of its signal with the fourth "1", which is negated and for the momentary suppression of the application of clock signals to counter 392 via NAND circuit 394 is used. If the counter 392 is not is deleted, it tries to start the AFC sequence. This process just described is triggered by the first pulse generated via the switch matrix 360 by actuation of the up button 362 or the down button 364 is effected.

In the operating mode with serial channel selection, the flip-flop circuit formed by the NAND circuits 380 and 382 'applies a signal with the value ¹¹ O "to the line 430 in order to indicate to the decoder 372 that it is desired that the Only signal values "1" appear at outputs A to D of the output buffer 366.

The flip-flop circuit formed by NAND circuits 380 and 382 enables the clock pulses to be applied to counter 374 in the manner described above. Also opens the flip-flop circuit the NAND circuit 388, whereby the Clearing counters 392 and 406 is enabled when a jump signal is received. If there is no jump signal, the OR circuit 384 is opened so that the counter 374 is incremented. The counter 374 generates thus one out of five bits at pins A through E existing binary code group.

fi Π η ρ «ρ / ρ 7

If the channel selected by the operator is not a valid channel and is to be skipped, a jump signal is applied via switch 434. The skip signal is large enough to the position shown in Fig.i4 circuit arrangement in the same manner to override as in operation of the switches 362 and 364, so that the jump signal on line ά of the switch matrix 360 and the line 436 to the OR circuit 384 passes . The NAND circuit 388 detects the jump signal and it generates a signal with the value ⁿ 0 ", whereby the jump signal is formed again in the serial channel selection. The signal with the value" 0 "from the NAND circuit 388 clears the counter 392, and it holds the counter 406 at the counter reading 00, which prevents normal counting. The flip-flop circuit formed by the NAND circuits 380 and 382 previously had the OR circuit 384 for operation with serial channel selection or for receiving the Current signals via line ^{/ l} 36 open.

When the up button 362 or the down button 364 is pressed, the counting direction of the counter 374 must be determined. The output of the NAND circuit 416 or the NAND circuit 418 causes the setting of one side of the FÜpflop circuit formed by the NAND circuits 422 and 424, to set the counter 374 in the desired counting mode.

When the operating mode of the circuit arrangement shown in Fig is switched from serial channel selection to parallel channel selection with a valid channel no signal to reset the counter 392 supplied. The counter 406 is running at this time, but is from Decoder 372 and blocked by the signal on line 430 from NAND circuit 380. When the operator

Γ; 0! 1 P. 1 6/0 7 3 1

presses a button on the switch matrix 360, the signal on the line is already high and it will fed to the OR circuit 376 via the input buffer 368, thus the flip-flop circuit formed by the NAND circuits 380 and 382 you switch back to the operating mode with parallels * channel selection.

Kie mentioned, 'did the signal at the selected vertical line in the switch matrix 360 for 25% of the A high signal value for the time and a low signal value 75% of the time. The decoder 372 is now open, so that it decodes the input data from the sample counter and loads the counter 374 with the correct data.

If the circuit arrangement shown in Fig.i4 in the Operating mode with parallel channel selection is working and the operator is trying to select a non-programmed channel then a jump signal is applied to the OR circuit 384 which is not open and the serial continue? prevented from this channel. However, the circuit arrangement continues to load the data and the OR circuit 376 is still switched on, so that the counter is loaded with a pulse generated by the OR circuit 376 will. If the operator so desires, a non-programmed channel can still be addressed.

Tuning memory for a circuit arrangement with twenty channels

In Fig.15 is a schematic circuit diagram of the tuning memory 143 (Fig.8) for use with the one shown in Fig.i4 Circuit arrangement shown. Those of that shown in Fig. 14 Circuit arrangement or generated with the help of another arrangement (binary address

609 B 16/0731

are input to a 5/20 line decoder 450 which applies the resulting word enable signals to a tuning voltage random memory 452 which Contains 20 words of 12 bits each. The output of the random memory 452 is passed through multiplexing circuits a 12-bit data bypass 454. The output signal of the data shunt 454 is provided to a presettable, asynchronously operating up / down counter 456 with a capacity of 12 bits. The output of counter 456 is fed to a 12-bit data comparator 458, which also receives the output of a synchronous binary counter which has a capacity of 12 bits. That The resulting output signal of the comparator 458 is fed via an inverter 461 to a D flip-flop and an integration filter 463, which feeds the analog signal to the control of the varactor diodes of the tuner 464 generated.

A clock signal with a frequency of 1 MHz is applied to the pin 465 to control the synchronous binary counter 460 created. A signal having a frequency of about 256 Hz is fed from the counter 460 to a down-counting frequency selection circuit 466 supplied. The outputs of the frequency selection circuit apply a clock frequency to a tuning program generator 468 and the generator feeds the counter 456 clock and load signals and data bypass circuit 454 Release signals too. Pressing a voltage boost programming button 470 and a voltage down programming button 472 actuates a tuning timer 474 which the frequency selection circuit 466 supplies fast or slow signals.

Output signals from the counter 456 are provided to the data multiplexing circuits 453 for input into the random memory 452.

f, D 1 R ^ R / Π 7 ': I

Read or write signals are applied from the tuning program generator 468 for reading or writing of the random memory 452 is controlled. The output of counter 456 is also sent to channel hopping decoder 478 supplied, which emits the above-mentioned channel hop signal.

The output signals of the address decoder 450 are also fed to a band switching arrangement 480, which the three Band control signals LVHF, HVHF and UHF generated, which are fed to the varactor diodes in the manner described above. When the output of the band switching device 480 is on appears on a UHF output, the frequency selection circuit is also used 466 is supplied with a signal via line 482 so that the frequency selection circuit 466 is in the operating mode with slow cycle works.

The mode of operation of the storage memory of Fig. 15 is the same Operation of the circuit arrangement shown in Fig. 13 with the exception that an additional random memory for the band switch bits or for the jump bits is not required. If desired, addressing signals To store in random memory 452, pin 486 is used to protect the contents of random memory 452 The battery is connected and the two buttons and 472 are pressed. The momentary depression of the two Buttons 470 and 472 cause a bypass signal on generator 468 to be provided to the 12-bit data bypass circuit 454. This has the application of signals with the value 0 to the output of the data bypass circuit result. This process sets the random memory to the zero state. If then only the up button is pressed, the tuning timer 474 switches to after a period of time such as 8 seconds

609R16 / 0731

fast mode, and he operates the down-counting Frequency selection circuit 466 in the fast mode, so that a high clock frequency is applied to the tuning program generator 468. When the operator is the first Channel, she releases the button and the circuit goes into slow mode so that the channel passes selected actuation of the tuning buttons can be fine-tuned. The tuning program generator then causes the reading the desired address and storage in the random memory 452

If the operator wants to skip unused channels, both buttons 470 and 472 are momentarily on the Place these channels pressed so that a signal with the value "0" appears at the output of the tuning program generator 468, which is detected by the data bypass circuit 454, which thereupon the appearance of 12 signal values "0" as data causes. Therefore, only data signals with the value "0" are input into the random memory 452 at this point. The data word consisting of the values "0" generates a jump signal at the output of the decoder 478 if this Channel address is selected with a subsequent actuation.

As mentioned above, the output words are obtained from random memory 452 via data bypass circuit 454 directed to actuate the counter 456. The output signals of the counter 456 are combined with the output signals of the counter 460 is applied to the comparator 458. The comparator 458 sets that stored in the random memory 452 Binary word into a signal with a pulse duty factor that corresponds to a specific DC voltage value. This Duty cycle is determined by the flip-flop 462 and fed to the integration filter 463, so that the desired analog signal for controlling the varactor diode tuner 464 is generated.

R09R16 / 0731

2 b 4 2 8 2 9

For a more detailed illustration of how the Tuning memory of FIG. 15 is shown in FIGS. 16a and 16b a logic circuit diagram of the circuit arrangement of FIG. There is an important feature of the invention described herein in that the circuit arrangement shown in Fig.16 on a single semiconductor chip using the technique can be formed with integrated injection logic. A description of the built-in Injection logic can be found in the article by K. Hart and A. Slob entitled "Integrated Injection Logic - A New Approach to LSI "published in the I.E.E.E. Journal in October 1972 of Solid-state Circuits, Volume SC-7 No. 5 has been published. The 5-bit binary address input signals are applied to pins 500 and through inverters a 5/20 line decoder formed by the NAND circuits 502 fed. The decoded output signals of the NAND circuits 502 are applied to the random memory 504, which contains 20 words of 12 bits each. To simplify the representation, the structure of the random memory is shown not shown in full; only one bit 506 of the random memory is shown in detail. Bit 506 is off built up several interconnected transistors, which in the manner shown the signals "word release", Generate "data input", "data output" and "data input".

The output signals of the decoding circuits 502 are detected by NAND circuits 508 and 510, thus via buffers and a NAND switch * 512 the three band selection signals for the Capacitance diode tuners are generated. These band selection signals control the selection of the VHF low band, the VHF high band and the UHF band.

The input and output of the random memory 504 are controlled by the data multiplexing circuit 514 which is composed of

B09S16 / 0731

12 stages consists of interconnected NAND circuits and 518. The read and write control signals are to the data multiplexing circuits via lines 520, the read word being a signal having the value "0" and the write word is a signal with the value "1" at the output of the inverter. The output of the data multiplexing circuits becomes the NAND formwork 528 feeds the connections to the Have counter 456. The counter 456 contains 12 stages that each from a counter 526, NAND circuit 528 and 530, AND circuits 532 and 534 and OR circuits 536 exist. The lines 540 and 542 are used for upward and down control signals applied. The up and down control signals are operated by pressing the up and down voltage programming buttons 470 and 472, respectively and they are fed through NAND circuits 544 and 546 which are used to form a flip-flop circuit with one another are connected.

The 12 outputs from counter 456 are fed to the 12-bit data comparator 458 (Fig. 16a) which contains 12 NAND 'circuits 550. The inputs of the NAND circuits 550 also receive clock signals from the synchronous counter 460, the capacity of which is 12 bits, and the 10 NAND circuits which are connected to 12 flip-flop circuits 554. The flip-flop circuits 554 are put on the line by one 556 applied clock signal is driven at a frequency of 1 MHz.

The outputs of the NAND circuits 550 in the comparator are fed to a NAND circuit 558 which is located on the pin 560 generates a data output signal that is fed to the D flip-flop and the integrator 463, which receives the analog signals generated according to the invention.

Tuning program generator 468 includes NAND circuits 566 and 566 which receive the up / down signals generated by voltage programming switches 470 and 472. The output of NAND circuit 564 is provided on line 568 to data bypass circuit 554 (which is an input to NAND circuits 528). The output signal of the NAND circuit 566 is fed to the D flip-flop 570, the outputs of which are connected to four flip-flop circuits 571 which are connected to one another. The outputs Q and "Q. of the flip-flop circuits 571 are connected to NAND circuits 572, 573 and 574. The outputs of the NAND circuits 572-574 generate clock, write / read and load signals and 472 are also supplied to a flip-flop circuit formed by the NAND circuits 578 and 580 through a NAND circuit 577.

The countdown frequency selection circuit 466 includes seven Counter stages 590 which receive a signal with a frequency of approximately 256 Hz from the counter 460 via the line 592. The input of a NAND circuit 596 is fed via the line with an output signal at a frequency of about 2 Hz. Further output signals of the counter stages 590 are fed to the inputs of the NAND circuits 600, 602, 604 and 606. The output signals of the NAND circuits 600 to 606 are applied to a NAND circuit 608, the output of which is via the line 609 applies a clock frequency to the D flip-flop 570.

The inputs of the NAND circuits are connected via line 6i0 and 606 is supplied with a logic signal indicating that the UHF band has been selected from the output of the NAND circuit 512 is. The indication of the presence of the UHF band causes the frequency selection circuit 466 to use a slow clock frequency generated for the tuning program generator 468. The tuning program generator 468 operates in response to an upward or Down input from NAND circuit 566,

n ι e / n73

2 b 4 2 B 2 9

a signal with the value "1" on the extinguishing line enables the counting process to be started. After 16 counting steps or a delay time of 8 seconds is provided by the 5-stage 612 tuning timer a signal having the value 1 is applied to the line 616 to cause the frequency selection circuit 466 to enter the fast operating mode is switched over for coarse tuning.

From the frequency selection circuit 466, the channel hopping decoding circuit 478 clock signals are supplied via line 618. The clock signals are sent to a NAND circuit applied, the output of which is fed to a NAND circuit 622. The outputs of the counter 456 are fed to the inputs of a NAND circuit 624, the output signal of which is applied to a D flip-flop 626. The Q output of the D flip-flop 626 is connected to the NAND circuit 622 connected. The output signal of the NAND circuit 622 is buffered and used to generate the channel hop signal the pin 630 supplied.

If, when operating the tuning program generator 468 of FIG. 16b, it is desired to skip a tuning position, the up and down switch buttons 470 and 472 are pressed simultaneously. The negated output signals the switches have the value "1"; they are fed to NAND circuit 564. The NAND circuit 477 provides the presence of signals with the value "1" is also fixed, and it feeds those from the NAND circuits via an inverter 578 and 580 formed flip-flop circuit. The input of the NAND circuit 578 is with that of the counter stages 512 formed 5-bit time delay counter.

60981 6/0731

As a result of the pressing of the switch buttons 470 and 472, a signal with the value "0" would be applied to the shunt line if the output signal was the NAND-. Circuit 578 would be present. The tuning program generator 468 does not cause the input of signals with the values "0" until the switch buttons 470 and 472 have been depressed for a short period of time, since clear signals are present on the Q lines connected to the input of the NAND circuit 578. After a predetermined period of time, the signal at the input of the NAND circuit 578 assumes the value ¹¹ O ", with the result that the output signal of the NAND circuit 578 assumes the value" 1 ". The input conditions of the NAND circuit are now met , and the shunt is enabled.

The flip-flop circuit formed by NAND circuitry 578 and 580 causes the signal coming from switches 470 and 472 to be debounced. The output signals switches 470 and 472 are detected by NAND circuit 577. If one of the switches or Both switch to ground, a signal with the value "1" appears at the output of the NAND circuit 577. That Output signal is negated to reset the NAND circuit of the flip-flop circuit, thereby sending to the NAND circuit 564 the signal with the value "1" is no longer present. This cycle must be performed during the next operating sequence start again.

The counter stages 612 extend the fine-tuning mode before the transition to the coarse-tuning mode. the NAND circuit 596 causes the counter to postpone the time period

609816/07 3 1

" ⁵¹ " 2 b 4 2 8 2 9

of 8 seconds based on the feedback signal it applied continue to count in fast mode. The NAND circuits 600 through 604 generate the different fast and slow tuning speeds for UHF and VHF operation.

The mode of operation of those shown in FIGS. 15 and 16a-b Circuit arrangements can be better understood by referring to the waveforms shown in FIG to understand. Fig.17a shows the depression of one of the switches 470 or 472. Fig.17b shows the course of the from generated by the NAND circuit 566 and supplied to the D flip-flop 570. Fig.17c shows the Course of the signal at the output Q of the D flip-flop 570. The state diagram shown inFig.17d illustrates the states of the program counter contained in the four counter stages 571 in the tuning program generator 468. Of the 17e shows the signal at the output Q of the D flip-flop 571, which is used to delete the D flip-flop 570 is created. Fig.17f shows the profile of the up / down charge signal that is sent from the output of the NAND circuit and used to control the loading of the up / down counter 456. Fig.17g shows the course of the output of the NAND circuit 573, which is supplied to the counter 556 is supplied via the clock line. Fig.17h shows the write signal for the random memory, which is from the NAND circuit 574 is applied to data multiplexing circuits 518 and 518 to cause the random memory to issue an instruction for writing.

In normal operation, the bypass circuit 454 is open and the counter 456 is continuously charged; the random memory 504 is read continuously. When the write signal shown in Fig. 17h is generated, the secondary

609816/0731

Final circuit controlled and loading is blocked. Either the count up or the count down signal is used as required and the write signal for the random memory, the read enable signal and the load enable signal from Tuning program generator 468 is generated.

When the signal shown in Fig.17a is high assumes because one of the buttons 470 or 472 is pressed, and also the free clock signal shown in Fig.17b has a high value, the leading edge of the signal from FIG. 17b causes the data signal from FIG. 17a to be transmitted to the output Q of the flip-flop circuit 570. After a transition time T ^ indicated in FIG of the data.

During the presetting time of the state diagram of FIG. 17d, the first three flip-flop circuits 571 go high Switching state held as indicated in state 7. After the time period T to enable the operation of the flip-flop circuits the next 500 kHz clock pulse that is supplied causes a transition to the state "0", as shown in Fig. 17d. According to FIG. 17f, state 7 is decoded by NAND circuit 572, which has a high state assumes so that the random memory from the up / down counter The counter in front of it then does not cause any paralles Load more and it is ready to receive the clock signals. The state "i" is now generated by the NAND circuit 573 decoded and the up / down counter is clocked with the data signals. States 2, 3 and 4 of Figure 17d are skipped so that an increment time is available for the counter, and state 5 is the NAND circuit 574 is decoded (Fig.17h) so that the write command for the random memory is executed. To achieve of debouncing protection, state 6 is not decoded.

As soon as the circuit arrangement transitions to state 7, the NAND circuit 572 transitions to its high state, and the negated output of this NAND circuit 572 goes high.

According to FIG. 17e, the output signal of the last flip-flop circuit 571 had a high value. After a delay time T, the output signal of the last flip-flop circuit now assumes a low value due to the negated output signal of the NAND circuit 572. This causes the flip-flop circuit 570, after a time delay T ^, to emit a signal with a low value which is used to preset the remainder of the flip-flop circuit. The last flip-flop circuit 571, whose output signal has just assumed the low value, now follows a time delay T _c to the high state. This removes the clear signal from the flip-flop circuit 570 and the state of the circuit arrangement returns to the beginning.

If the operator still operates one of the switch buttons 470 or 472 when that shown in Fig. 17b Clock signal assumes a high value, then the entire cycle is repeated. When the operator Release switch button 470 or switch button 472 then the television receiver is fine-tuned, and the counter containing the four stages 571 remains in state 7.

Whenever a "1" signal appears at the Q output of flip-flop 626 in response to the signal value ^w 0 "from NAND circuit 624 during a channel hopping operation, the D flip-flop becomes the leading edge of 32 Hz Clock signal on line 618 clocked.

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2b42829

The signal at output D7 of D flip-flop 626 follows the leading edge the clock signals and the data from the NAND circuit 624. The output signal of the D flip-flop 626 is in the NAND circuit 622 with the output signal of the NAND circuit 620 combined in a NAND and it is negated to produce the desired output waveform. That resulting output signal is a narrow pulse going to negative values, which is delayed so that the random memory can adjust, thereby reducing the circuit arrangement receives the time to change the program counter. Otherwise, the operation of the circuit arrangement is from FIG. 16 can be seen from the previous description of FIGS. 15 and 13.

Anzeigev orric Pla with Neonlarapen for Abstimros chaltung with Sixteen channels hn

In Fig. 18, the control circuit 104 for the neon lamp display device is shown and the neon lamp display matrix 134 of FIG Fig. 7 schematically!), Shown. It can be seen that the Neon lamp indicator also used for tuning circuit arrangements with more or less than 16 channels can be. The address code group formed by 4 bits from the address generator 92 is the inputs A to D fed. The inputs A and B are applied to a 2/4 line decoder 605, the outputs of which are connected to the base connections of the four transistors 130 shown in Figure 7 are connected. The collectors of the transistors 130 are connected to four horizontal lines 652 to 658. With each of lines 652 through 658 is a load resistor 660 connected. The resistors 66O are then connected to a load resistor 662 which has a high voltage of for example 200 V is connected.

Θ098 1 6/073 1

~ 55 -

542829

The address bits C and D from the address generator 92 are applied to a 3/5 line decoder 664, which can be used as a 2/4 line decoder, and whose output signal is applied to four lines 666, 668, 670 and 672, which are connected to lines 652 Cross over to 658 to form a matrix arrangement. As shown, there are sixteen between the lines Neon lights 674 turned on. As already mentioned above, the causes of the connection points A to D of the The address applied to the circuit shown in FIG corresponds to the channel selected by depressing one of the push-button switches in the switch matrix 90. It is to recognize that such a neon lamp display device for the discussed circuit arrangement with twenty channels can be used by the decoder is changed to a 3/5 line decoder and in which four additional neon lamps are added. The advantage the circuit arrangement shown in Fig.18 is again that it is in a single semiconductor chip with fourteen connection pins, which is manufactured using integration processes. The input E and the output line 673 can be used when making a circuit arrangement with twenty addresses it is asked for.

Two-digit 7-segment display device for twenty channels

According to FIG. 9, the display memory previously shown in FIG. 8 contains 145 five connection pins 700 for receiving the 5-digit binary memory address input signals from the address generator of Fig.i4. The address input signals are fed to a 5/20 line address decoder 702,

G 0 3 P ^ R / 0 7

which decodes the input signals and supplies 12 decoded addresses to a read-only memory, which has a capacity of 12 words of 7 bits each. The read only memory 704 stores the VHF constant channel code signals; the read-only memory therefore does not need the ability to write data to it. The decoder 702 also maintains a random memory 706 eight words, which has a capacity of 8 words of 7 bits each. The random memory 706 must store eight different words for the different UHF channel numbers so that it has the ability to read and must have for writing. Reading and writing are carried out using an input and output multiplexer achieved, which is controlled by a program control unit 710 to achieve reading or writing. The program control serv / calc 710 generates a clock signal with a frequency of 2 Hz for a BCD counter 712 with a capacity of 7 bits, which controls the multiplexer 708. The controller 710 operates in response to the actuation of the channel number increment button 711 the selective advancement of the in the random memory 706 stored words of the desired number in order to achieve the desired UHF channel display.

The output signals formed of seven bits from the solid - · fourth memory 704 or the random memory 706 are routed through a "1" be added UHF circuit 716 and the value "4" be added UHF circuit 718, the signals for a display time multiplexer 720 generate. Clock signals for the circuit arrangement are generated by a 130 Hz oscillator, which applies the clock signals to a divider circuit 724 with a division factor of 2 and a divider circuit 726 with a division factor of 32. The output signal of the divider circuit is applied as a position selection signal to the pin 730 of a 7-segment decoder chip 142, which has already been shown in FIG. The output signals of the display time division multiplexer 720 are input via inverters 732 and 734

q c ι ρ / ρ 7 3

/ _b42829

a decoding matrix 736 which provides signals A through B "to selected inputs of the ten NAND circuits 738.

The output signals of the NAND circuits 738 represent ten digits, which via a connection matrix 740 so that selected groups of the digit signals are applied to inputs of seven NAND circuits 742 will. The outputs of NAND circuits 742 are applied to pins 744 via drivers 743, thus the 7-segment control signals to control the 7-segment display device 144 of FIG. 8 is provided. The digit select outputs applied to pin 730 are negated and passed through a driver 748, so that a digit control signal is generated which selects which of the two display digits is actuated. To the exits driver 743 is generally an open collector saturated NPN transistor connected. At Large lateral saturated PNP transistors are connected to the output of driver 748 to allow display 144 to work properly is controlled.

When operating the circuit arrangement shown in FIG pins 700 become the binary memory address inputs which one of the 20 stored either in read-only memory 704 or in random memory 706 Select words. For programming the random memory the channel number increment button 711 is pressed. To this In a manner, the program controller 710 generates read and write control signals. The 7-bit BCD counter 712 runs through the counter readings 000 .... 79, so that the multiplexer 70S dfese counter readings enters as data into the random memory 706 "

0 1 6/073 1

2 b 4 2 8 2 p

Since the random memory 706 UHF channel numbers up to above the Number 80, an 8-bit random memory would normally be required. In this case however, it is recognized that the UHF channel number is greater than 14. Thus, in the random memory 706, only 0 to 70 words are stored, and the fourth 1 is added to the stored word with the aid of the addition circuits 716 and 718 or the value 4 is added. Therefore, only 7-bit random memory is required. The display time division multiplexer 720 performs the four-bit BCD numbers in ten order the decoding circuit to convert the data into the 7-segment format. The data are then used to control the with light-emitting diodes (LED) equipped display device 144 switched on.

It can thus be seen that, with the aid of the invention, a tuning circuit arrangement implemented in solid-state technology for television receivers is created. The system described here is divided into sub-assemblies, so that display devices or channel selectors can be easily swapped out without changing the rest of the circuitry. No expensive potentiometers or large printed circuit boards are required in the circuit arrangement needed. The invention is described herein with reference to the tuning of a television receiver has been, but it can be seen that the circuit arrangement described can also be used to tune other receivers, for example can be used by radio receivers, cable television receivers, and the like. The one shown in Fig.13 Circuitry requires the storage of words of two bits to obtain the band switching information. As mentioned, this band switching information is obtained by operating switches by the operator

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programmed during the initial programming of the entire circuitry. Another aspect of the invention described here is a circuit arrangement in which such programming is carried out the operator is not necessary.

In such a circuit arrangement, a band switching logic such as the band switching arrangement is connected to the circuit of FIG 480 of FIG. 15 is connected so that the contents of the read-only memory 704 and the random memory 706 are determined will. The band switching logic thus decodes portions of the read only memory 704 and the random memory generated discrete address, and it generates the band switching signals, which in the manner described above to the varactor diode tuner be created. The band switching logic can be based on a simple comparison logic with two BCD decades of the Display memory word and it can consist of only two OR circuits and a connected NOR circuit be educated.

The invention has been described here in connection with specific embodiments, but is for It is obvious to the person skilled in the art that further modifications and changes are possible within the scope of the invention.

/ 0731

Claims (1)

2b42829 Claims 1.] Arrangement for tuning a receiver, characterized by switches which can be actuated to select receiving channels are, an address generator that works depending on the actuation of the switches to generate from several Bits of existing digital address words, each corresponding to a different receiving channel, on a multi-core Manifold, a display device connected to the manifold that is dependent on the digital address words visibly indicates which receiving channel is currently selected, one to the bus connected voting memory with a programmable random memory for storing digital voting words, each corresponding to a different receiving channel, and dependent on outputting the tuning words from the address words received from the bus, translator means for translating the tuning words in analog signals and a tuning device that, depending on the analog signals, the channel tuning of the receiver changes. 2. Arrangement according to claim 1, characterized by a device for automatically generating a band selection signal depending on the digital address words, 3. Arrangement according to claim 1, characterized in that the switches consist of an array of switches for parallel channel selection, each corresponding to a predetermined television channel correspond. 4. Arrangement according to claim 1, characterized in that the switches from up and down switches for one sequential channel selection exist. 5. Arrangement according to claim 1, characterized in that the switches from a field with switches for a: parallel channel selection and from up / down switches for a sequential Channel selection exist. 6. Arrangement according to claim 1, characterized in that the display device from an array of light-emitting Devices exist, each with a 'different receiving channel correspond. 7. Arrangement according to claim 1, characterized in that the display device consists of a multi-digit numerical Display device consists. 8. Arrangement according to claim 1, characterized by a device for skipping selected receiving channels during channel selection _and 9. Arrangement according to claim 1, characterized in that some of the switches and predetermined VHF television channels select some of the switches for programmable UHF television channels. 10. Arrangement according to claim 1, characterized in that the indicator formed on the switches and means for illuminating the switches in their actuated state. 11. The arrangement according to claim 10, characterized by a device for changing the mounted on some switches Channel identifiers to correspond to selected UILF television channels. f-09816/0731 V642829 12. The arrangement according to claim 1, characterized in that the display device includes channel labels and devices of the labels formed close to the channels Pressing a switch arranged next to it contains. 13. The arrangement according to claim 1, characterized in that the display device formed on the switches channel identifiers and light emitting devices which illuminate when the switches are operated, close to the switches contains. 14. Arrangement for tuning to television channels, characterized by switching devices for selecting a desired one Television channel, an address generator for generating a unique binary address corresponding to the selected one Channel, a tuning memory for storing several digital tuning words and for outputting a digital tuning word Depending on the unique binary address, a digital-to-analog converter to convert the digital tuning word into an analog signal to achieve the channel tuning, a signal generating device that depends on the Binary address of one of a selected number of band selection signals generated, and one dependent on the analog signal and diode tuner operating on the band selection signal to tune in to the desired TV channel. 15. Arrangement according to claim 14, characterized by a device the tuning speed depending on the band selection signal the tuning arrangement changes so that when UHF channels are selected, the tuning speed is slower than when choosing VHF channels. 16. The arrangement according to claim 14, characterized by a device for changing the stored in the tuning memory digital voting words. 60981B / 073 1 2bA2829 17. The arrangement according to claim 14, characterized in that the address generator, the tuning memory and the converter are formed on a single semiconductor chip. 18. Arrangement according to claim 17, characterized in that the semiconductor chip using the technology with inte is. integrated injection logic (IL technology) Arrangement according to Claim 14, characterized in that the band selection signals include VHF channels 2 to 6 VHF low band signal, a VHF high band signal including VHF channels 7 to 13, and all UHF channels contain signal for the UHF band. 20. The arrangement according to claim 19, characterized by a Device for lowering the tuning speed of the tuning arrangement as a function of the UHF band signal. 21. Arrangement according to claim 14, characterized in that the switching device consists of a switch field in which each switch corresponds to a predetermined channel, where 12 switches correspond to the VHF channels and one group of switches correspond to the UHF channels. 22. Arrangement according to claim 21, characterized in that the group of switches corresponding to the UHF channels 8 switch contains « 23. Arrangement according to claim 21, characterized by a device for changing the group of switches corresponding UHF channels. 24. Arrangement for tuning to television channels with sequential channel selection, characterized by a switching device for Generation of upward and downward scan displays, one QO ^ o * P / 0731 2b4282S Clock circuit for generating clock signals, an up / down counter that depends on the switching device Clock signals .counts and generates binary address signals, a storage device for generating unique digital Tuning words depending on the address signals and a Tuning device for tuning to a desired television channel depending on the voting words. 25 »Arrangement according to claim 24, characterized by a Apparatus for generating channel skip signals and a device for changing the clock signals such that the Counter Skips predetermined binary address signals. 26. The arrangement according to claim 24, characterized by a device for generating AFC shutdown signals during of the voting process. 27. The arrangement according to claim 24, characterized in that the arrangement is based on semiconductor chips using the Technology of the integrated injection logic (I L technology) is produced. 28. ' Arrangement according to Claim 24, characterized by an AFC sequence counter for controlling the generation of the AFC switch-off signals during the generation of the address signals. 29. The arrangement according to claim 24, characterized in that a vote on 16 television channels is provided, and that the counter generates 4-bit address signals. 30. Arrangement according to claim 24, characterized in that a vote on 20 television channels is provided, and that the counter generates 5-bit address signals. ^ b 4 2 8 2 9 31. Arrangement for tuning to television channels, characterized by switching devices for tuning to a desired one Television channel, an address generator for generating a unique binary address corresponding to the selected channel, a storage device for storing a plurality of digital tuning words each representing a different television channel represent, a converter for converting the tuning words into analog tuning levels, a device for selectively changing the digital voting words stored in the storage device and a jumping device for selectively skipping selected digital voting words in the storage device during voting of the system with sequential channel selection. 32. Arrangement according to claim 31, characterized by a device for automatically generating one of three Band selection signals depending on the binary address. 33. Arrangement according to claim 31, characterized in that the switching device consists of a switch panel with switches for there is a parallel channel selection, each corresponding to a predetermined television channel. 34. Arrangement according to claim 31, characterized in that the switching device includes up and down switches for sequential channel selection. 35. Arrangement according to claim 31, characterized in that the converter contains the following components: an up / down counter, a device for outputting selected ones Vote words from the memory device to the up / down counter, a synchronous binary counter, a device for comparing the output signals of the up / down counter and the synchronous binary counter for generation / ^ 7 3 2b42829 a digital tuning signal whose duty cycle corresponds to a selected channel, and a device for Converting the digital tuning signal into an analog tuning level. 36. Arrangement according to claim 31, characterized in that the jumping device has a loading device for inputting Signal values "0" in the memory device on the memory , contains the place of the voting words to be skipped. 37. Arrangement for tuning to television channels with sequential and parallel channel selection, characterized by a matrix field from channel selection switches, each of which can be actuated to achieve a parallel selection of a television channel, upward and downward channel selection switch to achieve a sequential selection of television channels, these up » and downlink channel selection switches are connected to terminals of the matrix panel, a device which is dependent on the actuation of the switches of the matrix field unambiguous parallel binary address signals corresponding to the selected one TV channel generated, a device connected to the matrix field, which is dependent on the actuation the up and down channel selection switches send sequential binary address signals corresponding to sequential television channels and a tuner for tuning to a selected television channel from the binary address signals. 38. Arrangement according to claim 37, characterized by a jump device for generating a jump signal when selecting a specific TV channel and one Device for applying the jump signal via the matrix field to skip the television channel during the sequential channel selection. 609818/0731 39 · Arrangement according to claim 37 »characterized in that The device for generating address signals contains the following components: A device for sequential Application of signals with a high signal value to switches of the matrix field, a coding device for coding the signals applied by the matrix field if one of the switches is during the application of a signal with a high Signal value is operated, an up / down counter and means for applying the encoded signals to the up / down counter which contains the address signals generated. 40. Arrangement according to claim 39, characterized by a Clock signal source and a device for detecting the actuation of one of the upward or downward channel selection switches to apply the clock signals to the up / down counter to achieve generation of the address signals. 41. Arrangement according to claim 37, characterized by a device for generating AFC-AbschaTtsignalen during a section of each tuning cycle. 42. Arrangement for tuning to television channels, characterized by a programmable random memory for storage predetermined digital voting words, a device for generating binary address words for addressing the Random memory, an up / down counter, a device for applying the addressed tuning words the random memory to the up / down counter, a synchronous binary counter, a comparison device for Compare the output signals of the up / down. Counter and the synchronous binary counter for generation R Π ° P ■ P / 0 7 3 1 -68- 2 ^ 2829 a digital tuning signal, the duty cycle of which represents a desired television channel, and a converter device to convert the digital tuning signal into an analog signal for performing tuning to a television channel. 43. Arrangement according to claim 42, characterized in that the device for generating binary address words contains the following structural units: a switching device for generating upward and downward search advertisements, a Device for generating clock signals and a counter that generates the clock signals as a function of the switching device counts and generates the binary address signals. 44. Arrangement according to claim 42, characterized in that that the device for generating binary address words The following building blocks contains: an array of switches, each one for a given television channel correspond to a coding device for coding the output signals of the switch panel and a Device that generates the binary address signals as a function of the coding device. 45. Arrangement for voting a receiver, characterized by a memory for storing digital voting words, a device that adjusts the receiver to a desired position depending on the digital voting words, Programming switches that can be operated to change the stored digital tuning words in the memory, a speed control device operating in dependence on the switches for fine-tuning words in the Memory for a preset period of time and for the subsequent coarse matching of words in the memory. R Π ^Ω Ρ 1 F. / ^π 7 3 1 46. Anordnimg according to claim 45, characterized in that the receiver is a television receiver. 47. Arrangement according to claim 46, characterized in that the speed control device is different Tuning speeds when tuning to VHF channels and when tuning to UHF channels results. 48. Arrangement for tuning to television channels, characterized by dialing devices on the outside of a television receiver an address generator for generating digital address signals for selecting desired channels depending on the dialing devices, a storage device for storing digital voting words and for outputting selected voting words depending on the address signals, a converter device for converting the digital tuning words into analog tuning control signals, programming switches on the outside of the television receiver for changing the stored digital tuning words in the memory and a speed control device which, in response to an initial actuation of the programming switches, a Fine tuning ^ by slowly changing the stored digital tuning words in the memory for a preset period of time and then a coarse tuning by quickly changing the stored digital tuning words until the programming switch fails are operated more, results. 49. Arrangement according to claim 48, characterized in that the programming switches up and down switches and a snap circuit, which operates depending on the actuation of these two switches, to cause the skipping of a predetermined television channel. £ 09816/0731 2b42829 50. Arrangement according to claim 49, characterized in that with the aid of the snap circuit signals with the values "O" at one Storage space can be stored in the storage device for skipping a channel. 51. Arrangement according to claim 48, characterized in that the speed control device slower fine and coarse tuning speeds for the choice of UHF channels than for the choice of VHF channels. 52. Arrangement according to claim 48, characterized in that the speed control device is fine-tuned again results when the programming switches are no longer actuated. 53. Circuit arrangement for the display of television channels with reduced need for bit storage spaces, characterized by a device for generating address signals representing a selected television channel, a memory device, which contains a plurality of UHF channel indicator words and selected UHF channel indicator words depending on the address signals outputs, means for adding a predetermined amount to those output from the memory device VHF channel indicator words and a display device which, depending on the UHF channel indicator words, indicates the selected UHF channel displays. 54. Arrangement according to claim 53, characterized in that the memory device consists of a random memory storing 7-bit words consists. 55. Arrangement according to claim 54, characterized in that the predetermined size has the value 14. 56. Arrangement for tuning to television channels and for displaying the television channels, characterized by a device 809816/0731 2 ^ 2829 for generating electrical binary address signals representing a selected television channel, a Voting device that depends on the address signals tunes to a selected television channel, a read-only memory for storing multiple 7-bit display words, each representing a different VHF channel, a random memory for storing several 7-bit UHF indicator words, each on a different UHF channel represent an addressing device for addressing the read-only memory and the random memory with the address signals for outputting selected VHF and UHF display words, means for adding a predetermined number for the UHF display words and a display device for displaying a numerical display of the selected TV channel depending on the VHF and UHF indicator words. 57. Arrangement according to claim 56, characterized in that the display device consists of a two-digit 7-segment display device consists. 58. Arrangement according to claim 56, characterized in that the binary address signals consist of 5-bit binary address words exist. 59. Arrangement according to claim 56, characterized in that the predetermined number is the number 14. 60. Arrangement according to claim 56, characterized by a device for changing the in the random memory stored UHF indicator words. ^ 09816/0731 Blank page