EP0167848B1 - Device and method for setting and displaying the switching times of a digital time switch - Google Patents

Abstract

1. Method of setting and displaying the switching times of a digital time switch comprising a display unit with display elements arranged in a line for graphically indicating the duration of each switching condition, e. g. "NORMAL", "REDUCED", "OFF" by a stretch of switched-on or switched-off display elements on a display unit, with the beginning and the end of a stretch representing switching points, the stretch being differently marked depending on the switching condition, e. g. "NORMAL", "REDUCED", "OFF", characterised in that, in order to change a set switching condition, e. g. "NORMAL", a cursor is set to the beginning or the end of the stretch for said switching condition by actuating a switching member, e. g. a key (14, 15), and in that said cursor is moved on said line until a segment is reached corresponding to a desired time.

Description

The invention relates to a method and a device for setting and displaying the switching times in a digital time switch.

In a known digital time switch, a quartz crystal is provided, the vibrations of which are reduced by a frequency divider circuit and control an electronic minute, hour and day counter, the time and day of the week being indicated by a liquid crystal display. The time values for the switching commands can be entered into a memory using a keyboard, so that, for. B. at 6:00 a.m. the heating is switched to «NORMAL and at 10:00 p.m. again to« REDUCED. In this example, two switching points are set in the daily program, namely switching on at 6 a.m. and switching off at 10 p.m. Switching takes place between two switching states, namely «NORMAL and« REDUCED •. However, other switching states would also be possible, e.g. B. switching between «NORMAL» and «OFF •.

In the known time switch, different switching times can be programmed for the working days and for the weekend. Different daily programs can therefore be used for the working days and the weekend. The known time switch also has several channels, so that, for example, the heating on the south side of the house via a first channel, the heating on the north side of the house via a second channel and the hot water preparation via a third channel (e.g. an electric boiler) ) can be controlled.

The well-known digital time switch also takes the inertia of the heating system into account by automatically switching on a lead time. If, for example, the user sets the heating to 6 a.m. and the lead time is one hour, the time switch switches at 5 a.m. Correspondingly, the switch from «NORMAL to« REDUCED "takes place an hour earlier.

Many users find it difficult to program electronic digital time switches. The difficulties for the user are all the greater if different programs are planned for the weekdays and weekends and / or if there are several switching channels. In the case of mechanical time switches, the user was able to switch on time e.g. B. by a red tab and the switch-off time z. B. determine by a blue tab, so that the various switching states were still somewhat visible. Such an overview is missing in most digital time switches, because the different switching times can only be called up and made visible one after the other and there is no colored identification of the switch-on and switch-off times. Most digital time switches therefore lack the desired user-friendliness. In the case of such clocks, a time diagram is therefore necessary for a better overview, which is attached in the vicinity of the time switch. However, the use of a separate time diagram has the disadvantage that it has to be changed separately for each switching adjustment, but this is usually not done by the user.

GB-A-2091 913 describes a time-controlled heating controller which has an analog display with 48 display elements arranged along a line. Each of these display elements represents half an hour. The time can be set with several push buttons. To change a set on or off time, a corresponding push button is pressed. The newly set time is shown on the analog display. The disadvantage is that the user cannot easily recognize the effect of his manipulations. After manipulation, it is no longer possible to see where a change should take place or has taken place on the analog display.

GB-A-2 054 908 describes a time switch with an analog display which has 96 display elements arranged along a line or circle. Each of the display elements represents a quarter of an hour. In addition, a digital display is provided for the hours, minutes and day of the week. For reading the stored program or for programming, each of eight switching channels can be selected using a slider. This timer also has the disadvantage that the user cannot easily recognize the effects of his manipulations on the analog display.

It is therefore an object of the present invention to provide a method for setting and displaying the switching times and means for carrying out the method, which allow the construction of an inexpensive and user-friendly digital time switch.

According to the invention, this is achieved by changing the set on or off time for a predetermined switching state, e.g. B. «NORMAL by operating a switching element, for. B. a key, a cursor at the beginning or at the end of the route for this switching state and then the cursor is moved so far along the line until a segment is reached that corresponds to a desired time.

Because the duration of the respective switching state, e.g. B. «NORMAL», «REDUCED», «OFF», is graphically displayed by a route on a display unit, the start and end of the respective route representing switching points, namely the beginning and the end of the relevant switching state, the user can use Find out at a glance that his heating is switched to "NORMAL" from 6 a.m. to 10 p.m. and to "REDUCED" from 10 p.m. to 6 a.m. The graphic display also enables the user to immediately determine the effects of his manipulations to change the switching time and to immediately correct any incorrect manipulations. The overview of the various switching states is further improved in that, depending on the switching state, for. B. «NORMAL», «REDUCED», «OFF», the respective route is marked differently. Are only two switching states, e.g. For example, if "NORMAL and" REDUCED or "NORMAL and" OFF "are present, it is sufficient if the second switching status is identified by a blank space. However, should more than two switching states, e.g. For example, if "NORMAL •," REDUCED and "OFF are displayed, different display sections are advantageously provided in parallel, but only one of them appears to indicate" NORMAL or «REDUCED. The third display state «OFF is then again represented by a blank position. It is now important that if the user wants to change a set switch-on or switch-off time, he can move a cursor to the beginning or end of the route by pressing a switching element and then move until a segment is reached that suits him corresponds to the desired time.

It is particularly advantageous if the cursor is automatically placed at the beginning or end of the route when the corresponding switching element is actuated. The cursor can then expediently be moved in two directions by actuating a corresponding switching element. However, if the movement is restricted to one direction, the number of switching elements can be reduced. A digital display of the switching time is also expediently carried out simultaneously with the movement of the cursor, that is to say with the analog time display. This enables the switching points to be set precisely.

To shift the switch-on time, the cursor is advantageously placed at the beginning of the route by a first actuation of a first switching element and the switch-on time is shifted by a subsequent actuation of a second switching element. This enables a very simple change in the switch-on time. In an analogous manner, to change the switch-off time, the cursor can be placed at the end of the route by a first actuation of a second switching element and the switch-off time can be shifted by a subsequent actuation of the first switching element. This enables the stripping time to be changed easily.

The cursor is expediently stopped when the switching element is actuated continuously when a switching point is reached and moved further after releasing and actuating the first or second switching element. This enables simple handling for changing or maintaining a previous switching point. However, the cursor can also be stopped for a predetermined time when the switching element is actuated continuously when a switching point is reached and can be moved further when the actuation is continued. This is advantageous for shifting the switch-off time for the corresponding switching state.

The cursor is expediently accelerated to a maximum speed after actuation of a switching element during a predetermined start-up time. This makes it possible to stop the cursor and thus also the digital display by releasing the switching element shortly before the desired switching time, the cursor and the digital display then running relatively slowly when the switching element is actuated again, so that when the desired value is reached the The button can be released in time and this value becomes the switching point. The setting of a switching point can also be facilitated by briefly pressing the cursor one increment, e.g. B. an increment of ten minutes. This advance can be followed on the digital display.

As mentioned at the beginning, digital time switches generally provide different daily programs for the working days and for the weekend. Furthermore, various switching channels are often provided. In such cases, it is expedient if one day program after the other can be selectively displayed from the first to the last switching channel by actuating a further switching element. The order in which the daily programs are displayed can be such that a switch is made from one daily program to the other daily program of a switching channel, then from the last daily program of the first switching channel to the first daily program of the following switching channel and finally back to the first after the last daily program of the last switching channel Daily program of the first switching channel and / or back to normal operation. After the last daily program has been programmed, the programming of the time switch is completed, so that an automatic switch back to normal operation is advisable.

The invention also relates to a device for performing the method, with a timer, a display unit which has display segments arranged along a line in order to determine the duration of the respective switching state, e.g. B. to display the duration of «NORMAL» in the form of a route, with the beginning and end of each route representing switching points. This device is characterized by a cursor control, with which a cursor in the form of a flashing display segment can be placed at the beginning or end of a distance by pressing a key and can then be moved further in accordance with the desired change in the switching point. This device is inexpensive to manufacture, has only a few buttons and is easy to use. To the time required to change the switching time To reduce th, a ramp circuit can be provided which controls the cursor speed.

The display segments are advantageously arranged in one or more circles. This arrangement is space-saving and can therefore be easily implemented in a liquid crystal display. But it would also be possible to display segments in one or more loops, e.g. B. one or more circles to arrange. Such an arrangement is space-saving and can therefore be easily implemented in a liquid crystal display.

The arrangement should correspond to a 24-hour cycle so that the entire daily program can be seen. In addition to the graphic display, the display can also have a digital time display. As with the previous digital time switches, this makes it possible to carry out an exact time reading and time setting.

It is particularly advantageous if the display unit additionally has a display for the number of free switching points. In order to get by with as few or as cheap electronic components as possible, usually only a limited number of switching points can be provided. The user is therefore happy if he knows at any time when setting the time switch how many switching points he still has available.

A switching device, for. B. a button provided to display the individual daily programs in the same or different switching channels one after the other. The day programs then form a loop, so to speak, that one day program after the other is displayed by pressing the button, whereby switching from one channel to another automatically. In a known manner, the display can show both the channel and the days of the week, so that it can be seen at any time whether, for example, the daily program is shown for the south or north side of the house or for hot water preparation and whether it is the daily program for the working days or for the weekend.

A switching device for entering a standard program is expediently provided. This enables the user to easily enter a standard program. After entering the standard program, you can easily create a new program by changing this program.

• Fig. 1 eine Ansicht eines Ausführungsbeispiels der erfindungsgemässen digitalen Schaltuhr, wobei die graphische Darstellung der Einschaltdauer von 06.00 Uhr bis 22.00 Uhr ersichtlich ist,
• Fig. 2 in vergrösserter Darstellung die Gestaltung der Flüssigkristallanzeige,
• Fig. 3 eine schematische Darstellung einer Aenderung des in Figur 1 dargestellten Programms,
• Fig. 4 eine schematische Darstellung der Aenderung des in Figur 3 dargestellten Programms,
• Fig. 5 ein Blockdiagramm eines Ausführungsbeispiels der digitalen Schaltuhr,
• Fig. 6 eine Ansicht eines weiteren Ausführungsbeispiels der erfindungsgemässen digitalen Schaltuhr, wobei die graphische Darstellung der Einschaltdauer von « NORMAL von 06.00 Uhr bis 22.00 Uhr und die Einstelldauer von « REDUZIERT von 22.00 Uhr bis 24.00 Uhr ersichtlich ist, und
• Fig. 7 in vergrösserter Darstellung die Gestaltung der Flüssigkristallanzeige für das Ausführungsbeispiel von Figur 6.

The invention will now be explained in more detail with reference to the drawing. It shows :

• 1 is a view of an embodiment of the digital timer according to the invention, the graphical representation of the duty cycle from 6:00 a.m. to 10:00 p.m. can be seen,
• 2 in an enlarged view the design of the liquid crystal display,
• 3 shows a schematic representation of a change in the program shown in FIG. 1,
• 4 shows a schematic representation of the change in the program shown in FIG. 3,
• 5 is a block diagram of an embodiment of the digital timer;
• 6 is a view of a further exemplary embodiment of the digital time switch according to the invention, the graphical representation of the operating time of "NORMAL from 6:00 a.m. to 10:00 p.m. and the setting time of" REDUCED from 10:00 p.m. to 12:00 p.m., and
• 7 shows an enlarged representation of the design of the liquid crystal display for the exemplary embodiment from FIG. 6.

Figure 1 shows the embodiment of a digital timer 10 designed for use in heating and air conditioning systems. The display unit 11 can represent two operating states. In the normal state, the digital display 19 shows the time, with the colon 35 flashing. In the programming state, the colon does not flash and the setting time is displayed. But even during the programming process, the timer continues to run normally and controls the connected system according to the previous program.

The display unit 11 is designed as a liquid crystal display. Liquid displays are relatively cheap and require very little energy. To operate the time switch, six control buttons 12 to 17 are provided, of which the buttons 12, 16 and 17 can advantageously only be operated with a pointed object because they only have to be used rarely. However, buttons 13 to 15 can be operated with your finger. The function of the keys 12 to 17 is easier to understand if the liquid crystal display 11 is viewed beforehand. The following description of the liquid crystal display 11 is given with reference to FIG. 2.

FIG. 2 shows the different parts which can be made visible on the liquid crystal display by means of corresponding electrical signals. In addition to the digital display 19 for the time, a display 21 is provided for the days of the week. The switching state, e.g. B. «ON or« OFF is shown by arrows 23 and 25 respectively. These states correspond to the switching on or off of a contact of the time switch. The functions of the corresponding contact can be different, e.g. For example, switching the heating system from «REDUCED to« NORMAL and from «NORMAL to« REDUCED or switching a boiler on or off. The symbols 27, 28, 29 indicate the switching channels. Finally, a display 31 is provided, which shows the number of switching points still free during programming.

It is of particular importance that the liquid crystal display has means in the form of display segments 33 which serve to graphically display the operating time. In the liquid crystal display 11 shown, 72 segments are provided, each with a duration of 20 Minutes. These segments are arranged along a line. In the exemplary embodiment shown, this line forms a circular loop, with every third segment being somewhat larger in order to indicate an hour. The display of 24 hours has the advantage that the entire daily program can be made visible.

Other display types with segments are also possible. For example, a different number of segments could be provided, e.g. B. 144 segments, which correspond to a duration of 10 minutes. The segments could also be arranged in an ellipse or along the sides of a square or another geometric shape. A loop-shaped arrangement has the advantage that the space on the display unit 11 is well used.

As Figure 1 shows, the arrangement of display segments 33 shown has the advantage that the duty cycle, z. B. the duty cycle of normal operation of a central heating can be displayed graphically. A segment is represented by the activated segments 33, the beginning and the end of which represent switching points. The start shows the switch-on time and the end the switch-off time. It is therefore immediately apparent from the state shown in FIG. 1 that the heating switches on normal operation at 6:00 a.m. and switches off again at 10:00 p.m. However, this statement still needs to be clarified. The accuracy of the analog display formed by the segments 33 is of course limited by the duration of the segments, which is 20 minutes. It would therefore be possible for the digital clock to be set so that the heating switches on at 6.10 a.m. and switches off at 9.50 p.m. However, this limited accuracy of the analog display is of no practical importance given the inertia of the heating system. Furthermore, the clock can always be set exactly to the minute using the digital display. In the present exemplary embodiment, however, a setting accuracy of 10 minutes is provided with the digital display.

It has just been mentioned that heating systems have a certain inertia. It is therefore expedient to design a digital clock intended for heating systems in such a way that a so-called lead time is provided. In this case, the actual switching process does not correspond to the switching point set by the user, but is brought forward according to the inertia of the heating system. As mentioned in the introduction, this has already been achieved in known digital time switches, so that further explanations about it are unnecessary.

Figure 1 shows the display in normal operation of the timer. It's 8:25 a.m. on Tuesday. The flashing colon 35 indicates normal operation. The display 27 shows that the first switching channel is shown, and the visible switching segments 33 show that the first switching channel is in the “ON STATE” from approximately 6:00 a.m. to 10:00 p.m.

This is the case at the displayed time (8:25 a.m.) and is indicated by arrow 23.

As already mentioned, the time switch 10 has three switching channels. You can switch from one switching channel to another by pressing button 13. The second switching channel is indicated by the display 28 (FIG. 2). It is shown what is on the day represented by the display 21; namely Tuesday, acts as a switching program in the second channel. If button 13 is then pressed again, the system switches to the third channel, as indicated by display 29 (FIG. 2). In this exemplary embodiment, this is the last available channel. Pressing the button 13 again switches back to channel 1, that is to say to the position shown in FIG. 1. Please note that this mode of operation applies to the normal state of the watch. In the programming state, the daily program for working days is switched to the daily program for the weekend. Only then will the switch to the first daily program of the next channel take place the next time the button is pressed.

After this description of the display unit 11, the functions of the keys 12 to 17 will now be better understood. The buttons 16 and 17 are used to set the time switch in a manner known per se, so that a more detailed description of these functions is unnecessary. The key 12 is used to enter the standard program. It is therefore only necessary to press this button to activate the corresponding standard daily programs for the various channels.

To get from the normal state to the programming state in which the individual switching points can be set, a short press on the button 14 or 15 is sufficient. B. the button. 14 pressed, the cursor is set from the midnight position to the beginning of the route which is formed by the switched-on switching elements 33. The cursor itself is formed by a flashing display element 33. If, therefore, the button 14 is pressed in the position of the time switch shown in FIG. 1, the display segment 33 flashes immediately at the number of hours 6. Since this has also switched from the normal state to the programming state, the colon 35 stops flashing and it stops the display 19 shows the switching time 06.00. Furthermore, the display 21 shows all working days MO, TUE, MI, THU. FR can be seen. This makes it clear that the daily program shown on the first switching channel is the weekday program.

If button 13 were now pressed, the weekend program, ie the second day program, would be displayed on the first channel. Pressing button 13 again would switch to the first daily program on the second channel, etc., until after the last daily program of the last (here the third) switching channel, pressing button 13 again removed the timer from the program Mier status would be brought into the normal state, where the blinking colon 35 makes it clear that the display 19 again shows the time.

However, the programming will now be described further below. As previously described, pressing the button 14 caused the display segment 33 to flash at the number of hours 6. The cursor was therefore placed on segment 33 at the number of hours 6. The case is now considered where the user wishes to change the switching times in such a way that only switched on to «NORMAL at 8:00 a.m., but switched back at 1:00 p.m., then switched on again at 4:00 p.m. and switched back on as before at 10:00 p.m.

In order to achieve the desired change, the user first presses the button 15. The cursor now moves, as shown in FIG. 3, to the number of hours 8. At the same time, the digital display 19 switches the setting time in ten-minute steps. As soon as 8:00 is displayed, the user releases button 15. The new switch-on point is now set to 8:00 a.m.

However, since the switch-off time is to be set to 1:00 p.m., the user moves the cursor by holding down the button 14 until after 1:00 p.m. and releases the button as soon as 1:00 p.m. appears on the digital display. If he now presses key 15, the cursor continues to run. However, since it is to be switched on again at 4 p.m., he releases button 14 when the number 4 p.m. appears on the digital display. The programming shown in FIG. 3 has thus been achieved. If the user stops manipulating, e.g. B. switches to another daily program by pressing the key 13, then returns after a predetermined time, for. B. two minutes after releasing the button 14, the timer back to normal. The time is again shown on the digital display 19, which can be seen from the flashing colon 35. The display is therefore as in FIG. 1, except that the segments between 6 and 8 and 13 and 16 are no longer visible. The deletion of these segments is indicated in FIG. 3 by a dashed line.

As a last example, it will now be shown how the switching program of the time switch shown in FIG. 3 is changed to the switching program shown in FIG. This change is that the heating should switch to «NORMAL instead of 4:00 p.m. and switch back to 11:00 p.m. instead of 10:00 p.m. By pressing key 14, the cursor jumps to the segment at 8:00 a.m. By holding down the button 14, the cursor moves to the switching point of 1:00 p.m. and stops because it has reached a switching point. If the same key 14 is then either pressed continuously or released and pressed again, the cursor moves to 4:00 p.m. and then stops again because the previous switch-on point is located there. If button 15 is then pressed, it continues to run until the operator releases button 15 at 17.00 and thus sets a new switch-on point. The key 14 is then pressed so that the cursor runs and stops until the previous switching point of 10:00 p.m. By continuously pressing or releasing and pressing again, the cursor moves again, whereupon the operator releases the key 14 when the number 23.00 appears in order to initiate the setting of the switch-off point there.

It can also be mentioned that when buttons 14 and 15 are continuously pressed, display 19 switches relatively quickly in ten-minute steps and the cursor also moves quickly. However, if the key is released briefly, the advance in ten-minute steps is relatively slow at first. However, there is an acceleration until the normal speed is reached. So should the display on a certain setting, for. B. 23.00 brought, it is advantageous to let go of the key 14 at about 22.30 and then pressed again until 23.00 has been reached. However, it is also possible to switch gradually by briefly pressing until 23.00 has been reached.

Figure 5 shows a block diagram of the time switch. It is a simplified diagram, whereby only the most important functions are visible. The keys 12 to 17 are connected to the input control 37, which has outputs for the channel and day program selection circuit 39, for the cursor control 41 and for the ramp circuit 43. The ramp circuit 43 controls the speed at which the counter 45 delivers pulses to the cursor control 41 and display control 49. The counter 45 also supplies the setting time with hour and 10-minute information to the switching time memory 47. The switching point counter 51 counts down by one each time a switching point is set in order to display 11 the number of switching points which can still be programmed. However, if switching points are deleted, the switching point counter counts up. The timer 53 supplies time signals to the display controller 49, so that the time normally appears on the display 11. However, time signals are also supplied to the comparator 55, which compares these time signals with the switching times stored in the switching time memory 47 and outputs a signal to the switching command output 57 if they match. Since the switching time memory 47 additionally supplies a signal for determining the channel, the command output to the correct channel takes place if the switching time of the timer and the stored switching time match. However, the invention is not limited to the embodiment shown in the block diagram. Rather, modern electronics, in particular microprocessor technology, offer even more possibilities for realizing the idea on which the present invention is based.

There are also other options for executing the graphical representation. This is illustrated by FIGS. 6 and 7. The time switch according to FIG. 6 is fundamentally similar to that of FIG. 1, but on the liquid crystal display 11 display segments 33 and 33 'are arranged in two concentric circles. This enables e.g. B. to represent three different operating states. In FIG. 6, the segments 33 that are switched on show the “NORMAL” operation, and the segments 33 ′ that are switched on show the “REDUCED” operation. The distance, which is represented by non-switched segments 33 and 33 ', represents the state "OFF of the heating system. As FIG. 7 shows, the state" REDUCED "is represented by reference numeral 24.

However, the described assignment of operating states is only an example. It would also be possible for segments 33 and 33 'to represent the operating state of different channels.

Claims (19)

1. Method of setting and displaying the switching times of a digital time switch comprising a display unit with display elements arranged in a line for graphically indicating the duration of each switching condition, e. g. «NORMAL•, « REDUCED • , « OFF by a stretch of switched- on or switched-off display elements on a display unit, with the beginning and the end of a stretch representing switching points, the stretch being differently marked depending on the switching condition, e. g. « NORMAL »·, « REDUCED », « OFF , characterised in that, in order to change a set switching condition, e. g. « NORMAL a, a cursor is set to the beginning or the end of the stretch for said switching condition by actuating a switching member, e. g. a key (14, 15), and in that said cursor is moved on said line until a segment is reached corresponding to a desired time.

2. Method as in claim 1, characterised in that, on actuating the respective switching member (14, 15), a cursor is automatically set to the beginning or the end, respectively, of the stretch.

3. Method as in claim 1 or 2, characterised in that, on actuating a respective switching member (14, 15) the cursor is moved in one direction or the other direction, respectively, of the stretch.

4. Method as in claim 1 to 3, characterised in that, on actuating a switching member (14,15) the cursor is moved only in one direction.

5. Method as in claim 1 to 4, characterised in that simultaneously with the movement of the cursor a digital display of the switching time takes place.

6. Method as in claim 1 to 5, characterised in that for shifting the switching-on time the cursor is set to the beginning of the stretch by a first actuation of a first switching member (14), and in that the switching-on time is moved by a subsequent actuation of a second switching member.

7. Method as in claim 1 to 5, characterised in that for shifting the switching-off time the cursor is set to the end of the stretch by actuating a second switching member (15), and in that the switching-off time is moved by a subsequent actuation of the first switching member (14).

8. Method as in claim 1 to 7, characterised in that, on continuous actuation of the respective switching member, the cursor is stopped when it reaches a switching point, and, after releasing the first or second switching member, is further moved.

9. Method as in claim 1 to 8, characterised in that, on continuous actuation of the switching member, the cursor is stopped for a predetermined time when it reaches a switching point, and, on continued action of the switching member, is further moved.

10. Method as in claim 1 to 9, characterised in that, after actuation of a switching member, the cursor is accellerated to maximum speed during a predetermined starting time.

11. Method as in claim 1 to 10, characterised in that by a short actuation of the switching member (14, 15) the cursor is stepped by one increment, e.g. an increment of ten minutes.

12. Method as in claim 1 to 11, characterised in that by actuation of a further switching member (13) one daily program after the other is selectively displayed from a first to a last switching channel.

13. Method as in claim 1 to 12, characterised in that the order of display of the daily program is such that switching takes place from one daily program to another daily program of a switching channel, in that then switching takes place from the last daily program of the first switching channel to the first daily program of the following switching channel, finally, in that, after the last daily program of the last switching channel, switching takes place back to the first daily program of the first switching channel, or back to normal operation.

14. Device for carrying out the method as in one of the claims 1 to 13, comprising a clock (53), a display unit (11) with display elements (33) arranged in a line for indicating the duration of each switching condition, e.g. the duration of « NORMAL •, in form of a stretch, with the beginning and the end of each stretch representing switching points, characterised by a cursor control (41) by which a cursor in form of a flashing display element (33) can be moved by actuation of a key (14, 15) at the beginning or the end of the stretch and then according to the desired change of the switching point.

15. Device as in claim 14, characterised in that a ramp circuit (43) for controlling the cursor speed is provided.

16. Device as in claim 14 or 15, characterised in that the display segments are arranged in one or more loops, e.g. in a circle (34).

17. Device as in claims 14 to 16, characterised in that the display unit has additionally a display for the number of free switching points.

18. Device as in claims 14 to 17 with a plurality of daily programs and/or channels, characterised in that a switching device (13), e.g. a key, is provided to display the different daily programs after each other in the same switching channel or in different switching channels.

19. Device as in claims 14 to 18, characterised in that a switching device (12) is provided to input one or more standard programs.

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