WO2006111481A2 - Tactile display device and electronic clock with manual time setting - Google Patents

Abstract

The invention relates to data display devices with a visually analogue form and in particular, electronic clocks with display on a display screen in the form of hour hands and minute hands. The clock comprises a tactile display screen structure (20), divided into selectively displayed adjacent zones, each representing a possible position for a hand element, with selective touch detection means for detecting the position of a finger on a displayed zone, means for detection of a displacement of the finger of said zone towards a neighboring non-displayed zone and means for resetting the clock to the time corresponding to the adjacent touched zone and for displaying the reset time. The invention is also applicable to the display of set values in the form of a cursor the position of which represents the set value. The cursor is defined by an element of the tactile zone and is displayed by means of the finger at a point which represents the value of the desired set value.

Description

 MANUAL ADJUSTMENT DEVICE, ESPECIALLY AN ELECTRONIC CLOCK WITH MANUAL TIME ADJUSTMENT

The invention relates to electronic display devices which display data in the form of an image whose position or size depends on the value of the data, and more specifically those which display data that it is desired to be able to regulate, in particular a displayable setpoint that we want to impose on a device. The invention is particularly applicable to electronic clocks displaying the time on an electronic display screen in the form of a large needle image (for minutes) and a small needle image (for hours), both turning around a virtual axis on a graduated or ungraded dial image. The adjustment envisaged is then either a setting of the time (setting the clock time), or a setting of a similar auxiliary function: setting the alarm time for a clock having an alarm function. These clocks (and by "clock" will be understood hereinafter clocks, clocks, clocks, alarm clocks, etc., regardless of their size and practical use) are intended to make the time more intuitively readable than that which is displayed as decimal digits of minutes and hours. They use a display screen which can be large and which is capable of reproducing an image of needles at different positions, and electronic control circuits of this screen to establish successively, as and when the flow of time, the image of each needle at successive positions that correspond to this flow of time. The electronic circuits are controlled by a programmed microcontroller provided with a time base derived from a stable frequency oscillator.

Similarly, for display devices displaying other data, the image display of a position or a dimension which represents in intuitive form (and not in the form of numbers) a numerical quantity is desired for a question of readability, ergonomics, comfort, intuitive reading. So, in a device where you want to be able to display as a given value a set value given to the device (temperature setpoint for an air conditioner for example, volume setpoint for an audio installation, flow setpoint for a valve, etc.), it may be useful to display the setpoint in the form of an image giving an intuitive preview of the value of the displayed instruction: for example a cursor which moves on a graduated, linear or circular zone or other. Or, it can be visually comfortable to display the setpoint as a more or less extended surface depending on the value of the setpoint, for example a rectangular strip more or less elongated, or a more or less arcuate band open according to the value of the setpoint. The displayed part represents in a visually intuitive form (and not in the form of displayed numbers) the numerical value associated with the cursor position.

Returning to the example of the clock, when the clock is no longer on time for example because of an unintentional interruption of power or for any other reason, it is put back to the time conventionally by various User-accessible adjustment buttons, these buttons acting on the microcontroller to increment the hours and minutes at will. These adjustment buttons are often not very ergonomic, the user manual is not always known by the user; there are several buttons to handle; most often these buttons act incrementally but not by decrement, which is inconvenient when you want to move back the displayed time of a few minutes only. The same ergonomic issues arise for the ring time setting if there is an alarm function in the clock. An object of the invention is to provide a low cost production clock, which can be extremely easily set by a user in the most ergonomic and intuitive way possible, whether for setting the current time or time setting of the alarm function. A more general object of the invention is to propose an electronic device for displaying an adjustable datum, which can be easily adjusted manually by the user, in the most ergonomic and intuitive manner, while remaining economic to achieve. For this, the invention proposes to provide a display device which comprises a touch display screen structure of which at least a portion is divided into juxtaposed zones selectively displayable and selectively touch sensitive, formed using individual electrodes which have the shape of the area to be displayed, each zone representing a possible position of a displayable cursor and a numerical value associated with this position, with selective touch detection means able to detect the position of a finger on a zone displayed by proximity detection with the corresponding individual electrode, means for detecting a movement of a finger from this zone to a neighboring zone, means for displaying the cursor on this neighboring zone, and means for transmitting a value corresponding to the new position displayed.

Thus, the finger touches the cursor to a first position where it is displayed, and moves the cursor to another position representing the new value to be displayed, which achieves a particularly intuitive and ergonomic value adjustment.

The selectively displayable juxtaposed areas of the touch screen are formed using individual electrodes that have the shape of the area to be displayed, and it is these electrodes themselves that serve for the capacitive detection of the presence of a finger . There is therefore both selective display of an area representing the cursor with the aid of an electrode having the shape of the cursor at this position and possibility of capacitive detection by the same electrode when a finger is touched on this zone. . In the case of a clock, the cursor is constituted by a hand representing the hour or the minute, and the invention proposes to produce a clock which comprises a touch display screen structure divided into selectively displayable juxtaposed zones and each representing a possible position of a needle element (preferably at least 60 juxtaposed zones distributed radially around a virtual center), with selective touch detection means able to detect the position of a finger on an area displayed, means for detecting a movement of a finger from this zone to a neighboring zone that is not displayed, and means for resetting the clock at the time corresponding to the neighboring zone affected and for displaying the recalibrated time . This setting is particularly interesting when the clock is in setting mode of a wake up time, to bring the hands to the desired hour and waking minute. The new alarm time displayed then represents a new alarm setpoint and the value of this setpoint is transmitted to the "clock" function of the clock.

The invention is particularly applicable to the display of an instruction in intuitive form, and the setting of this instruction by very simple and intuitive action of the user: the user moves the cursor with the finger to the position which corresponds to the desired new desired value, and a numerical value corresponding to this position is transmitted to the device to which this instruction is intended.

By the word cursor is meant the displayed area that corresponds to the numerical value that this cursor should represent, regardless of whether other areas are displayed as well. Thus, in the case where the numerical value is displayed in the form of a linear or arcuate strip which lengthens as the numerical value increases, the word slider will designate the position of the end of the elongated strip . The finger should be placed on this slider and move either to a neighboring area not displayed, to lengthen the band, or to a nearby area already displayed (but not the end of the band, so that is not not the cursor as it is meant here), to shorten the band. In the case of a simple cursor which designates only a displayed elementary zone framed by unposted elementary zones, the cursor is moved on one side or the other but in both cases towards an area not yet displayed. The word cursor must moreover be understood in a general sense independently of its displayed form: in particular, it may be desirable to display a cursor in the realistic or symbolic form of a hardware element controlled by the device or of a control device. control of this material element. For example, if the device is intended to control the opening of a valve, it can be shown a valve head whose rotation on the screen represents the opening of the valve to a greater or lesser extent. Or, if the device is intended to control a fuel injection, the slider can be represented as a throttle lever whose more or less pronounced tilting represents the injection setpoint. Moreover, in this patent application which refers to a touch screen and the finger that touches the screen, it will be understood that by finger means not only the human finger of the user if it directly touches the screen but of course also any object held by the user and that would play the same role as the finger vis-à-vis the touch screen, for example a pencil or a stick, if it has capacitive properties similar to those fingertips with regard to the principle of tactile sensing used.

In a touch screen, the selectively displayable zones, which are also used for selective detection, are individual transparent electrodes having the shape of the desired zones and having the dual function of displaying this zone and capacitive proximity sensor sensitive to the touch of this zone.

According to a possible embodiment in the case of a clock, the invention proposes that the touch screen display structure is divided into at least 60 pairs of selectively displayable and selectively touch sensitive zones radially distributed around a surface. virtual center of rotation, each pair having two zones substantially in axial extension from one another, one of the zones, closer to the center, constituting a small needle display element and the other zone, plus away from the center, constituting a complementary display element such that the pair of simultaneously displayed areas represents a large pointer.

Preferably, the clock comprises:

means for supplying an electronic signal representing the current time, in hours and minutes, means for regular automatic incrementing of the current time and occasional incrementation / decrementing means for setting the time the current time or the alarm time of the clock,

means for displaying the zones corresponding to the current time provided, these means being controlled by the current time electronic signal,

- Time reset control means by contact of a finger of the user on a displayed area and rotation of the finger in one direction, the control circuit comprising means for detecting the touch of the finger on the different areas displayed or not displayed, these means acting on the occasional incrementing means for incrementing or Decrement the time according to the direction of rotation when a touch of a finger on a displayed area is followed by a touch of a finger on a nearby unseen area.

Thus, we touch the image of a needle with the finger; this touch is detected by the corresponding touch zone; the finger is moved in rotation and thus comes touching an adjacent touch zone; this touch is detected; the direction of rotation is analyzed by comparison between the newly affected area and the area previously affected; if the areas are large needle areas, the current time electronic signal is incremented by one minute or decremented by one minute; at the same time, it is the new affected area that is displayed as a large hand moved a minute; if the affected area is a small needle area, it is the same but the current time electronic signal is incremented or decremented by one hour and it is a small neighboring needle area that is displayed. In wakeup time setting mode, it is the same thing, but of course the alarm time is displayed and the signal representing this time is only incremented or decremented by the occasional incrementation means. .

The user therefore sees the time change directly by the effect of the sliding of his finger on the touch screen as if he took the needle and brought it in rotation to the desired location, and that in a sense or in the other.

If the finger touches an area that is not displayed (and therefore outside the image of the hands currently displayed), no time reset action is triggered. The display screen is preferably completely transparent in the areas not displayed, for reasons of aesthetics and readability (in the case of a display operating in transmissive mode where the lighting is made from the back of the screen). 'screen).

The electronic time signal may be conventionally provided by a counting integrated circuit comprising the binary outputs representing the hours and minutes and comprising increment / decrement inputs acting on the output signal. The display means are preferably of the LCD type and comprise a display screen control circuit ("driver" of liquid crystal screen) connected to the individual electrodes which define the different zones selectively. displayable. The finger detection means are of the capacitive type, and include means for applying a high frequency signal to the electrodes constituting the different zones. The various circuits can be grouped together and it is possible in particular to provide for certain functions, and in particular the supply of the electronic signal representing the current time, the incrementation and the decrementation, the identification of the affected zone and the display control. a zone according to the current time signal, are executed by a microcontroller with the program that allows it to perform these functions. In this case, the clock comprises a microcontroller, a control circuit of the touch display screen, and a microcontroller operating program capable of:

- regularly change a current time from a time base; - change the current time or an alarm time to occasional time reset instructions;

- control the display of the zones corresponding to the current time or the alarm time;

- detect the touch of the touch zones of the screen; - detect if an affected area is displayed and trigger in this case a time reset program;

- during the time setting program, establishing time-setting instructions if an area adjacent to the affected area displayed is touched, the time setting including a time modification corresponding to the position of the said time zone; neighboring area.

By the use of a touch display screen, in which the same electrodes are used both for displaying and for detecting the finger position, the adjustment functions according to the invention can be realized at minimum cost. . Other features and advantages of the invention will appear on reading the detailed description which follows and which is given with reference to the appended drawings in which:

- Figure 1 shows a schematic view of the clock according to the invention; - Figure 2 shows the principle of a display screen divided into zones for displaying successive positions of small hand and large needle;

- Figure 3 shows schematically the principle of electronic control of a touch screen;

FIG. 4 represents a general flowchart of the time-setting function according to the invention;

- Figure 5 shows a flow diagram of the operation of the time modification.

Touchscreen displays have been known for many years and the principle will be briefly recalled. Details of operation and embodiments are given in various prior patents and in particular EP 0340 096, FR 2 820 869, WO 2004/049269 to which reference may be made.

These screens, generally liquid crystal screens (other display modes are possible but the invention will be described in the context of liquid crystal screens or LCD screens), rely on the selective display of juxtaposed zones defined each by a transparent electrode isolated from the electrodes corresponding to other zones. In general, the liquid crystal is located between two plates, one of the plates comprising the different electrodes and the other plate comprising a general counter-electrode. The display occurs when a voltage of a certain value is applied between an electrode and the counter-electrode. The electrodes are in principle transparent and the passage of light is allowed or prohibited according to the applied voltage. The displayed area has the shape of the electrode that defines it. The counter-electrode may have the same shape as the electrode defining the displayed shape. The term "display an area" will be used to express that the zone becomes visible in the middle of other zones not displayed, whether due to the presence of light through the electrode of this zone, the others preventing the passage light, or on the contrary because of the absence of light through the electrode, the others allowing the light to pass. And we will use the same name as soon as the zone becomes visible, either because of the application of a voltage (the other electrodes not receiving voltage) or because of the absence application of a voltage (the others receiving one). All these modes of operation are indeed similar.

In a touch display screen, these same electrodes that define the shape of the displayed visible areas, or separate counter electrodes having the same shape and placed opposite these electrodes, are also used to detect a proximity of a finger, hence the name touch screen. Electronic circuits apply a high frequency voltage to one or the other of the electrodes, superimposed on the display control voltage, and other circuits detect the changes introduced by capacitive effect on the voltages present on the electrodes. depending on the presence or absence of a finger in the immediate vicinity of the electrode.

We now know well:

- display selected areas from a set of possible areas;

- detect the presence of a finger on a displayed area;

- detect the presence of a finger on an area not displayed since the capacitive detection does not depend on whether the area is displayed or not. According to the invention, a touch display screen will be used to display the time in the form of needles, in principle a large needle and a small needle; the displayable areas are therefore juxtaposed needle shapes such that if the area is displayed we will see a needle at a specific position corresponding to this area. Then we will detect the presence of a finger on this area to change the displayed area and display a needle at another position determined by the movement of the finger.

We will describe a preferred embodiment of the invention. Figure 1 shows an exemplary embodiment for a folding table alarm clock. The electronic circuits are housed in the base 10; the touch screen display 20 is the foldable part of the alarm connected to the base, for example by a sheet of flexible conductors not visible. The screen is electrodes normally transparent. The displayed areas, small hand (22), large hand (24), graduated dial (26), digital time display (30), and other symbols (32, 34, 36), interrupt transmission light and therefore appear as dark areas on a transparent background, but we could obviously consider the opposite solution.

The displayable areas correspond to individual electrodes in the form of the area to be displayed. For the needles, there are as many electrodes as possible needle positions, typically 60 radially distributed positions, but the large needle is divided into two needle elements, one of which can be used for display a small needle. There are therefore, for 60 possible needle positions, 120 individually controllable electrodes. At least some of the displayable areas of the screen are tactile, i.e., selectively detect the touch of a finger on each of these areas. This is particularly the case of the symbol areas 32, 34, 36 because these areas are intended for the control of the clock (ignition or inhibition of the alarm for example, change to alarm time setting mode) .

In addition, and this is a specific feature of the invention, the 120 displayable areas corresponding to the possible positions of the small hand and the large hand are all tactile and selectively detectable.

FIG. 2 diagrammatically represents the constitution of the needle zones: the screen comprises 60 pairs of zones distributed radially around a center O if it is desired to display with a resolution of one minute, but for the sake of simplicity the representation has been considered that there were only 12 (resolution of 5 minutes); if you want a higher resolution, such as a resolution per half-minute, it takes more than 60 pairs but it assumes that the screen is large enough, otherwise the detection of touch is difficult and inaccurate. A pair of aligned areas in the same radius defines the shape of a large needle; in this pair there is a first zone Za closer to the center, defining the shape of a small needle and a second zone Zb, further from the center and in the extension of the first zone, constituting a complement such as when the two zones are simultaneously displayed a large needle is seen. The 60 pairs of zones are displayable independently of each other and the touch detection is selective for each of them.

FIG. 3 diagrammatically represents the electronic control circuits of the screen. They include a circuit 40 of application of control voltages at the different electrodes defining the displayable areas, the control voltages determining which zones are displayed; and a microcontroller 50 which defines the displays to be made and which is able to detect, in a known manner, by capacitive effect, the touch of a finger on a specific display area. The circuit for applying voltages to the electrodes, or "screen driver" 40 comprises, in a known manner, a multiplexing for

applying the appropriate DC control voltages to the different electrodes to display the zones specified by the microcontroller;

- apply a high frequency voltage, from a HF 60 circuit (a few hundred kilohertz to a few megahertz) successively and at high speed on all the electrodes corresponding to touch zones, so in particular to all zones Za type and Zb defining the needles; the rate of application is such that no more than a few tens of milliseconds to a few hundred milliseconds elapse between two applications of alternating voltage RF at the same electrode;

- pass to the microcontroller, in return, information indicating that this or that area has been affected; the information is related to the high-frequency impedance change, as seen by a microcontroller input, at a time when the high-frequency voltage is applied to an affected area.

Auxiliary functions of the clock are not shown (alarm function, radio, etc.); they are not related to the invention except as regards the setting of the alarm time and the transmission of the alarm set point in the case of an alarm.

FIG. 4 represents the general operating chart of the microcontroller for the time setting function according to the invention. This flowchart is presented for the simplest case where the instruction for the user is as follows: touching the end of the large hand displayed to change the minutes then move the finger, touch the body of the small hand displayed and move the finger to change the hours. If the time setting is for the alarm time setting and not for setting the current time, a preliminary step can be considered. example the actuation of a key (for example one of the keys 32 to 36) triggering the passage into alarm time setting mode; and this mode can be better visualized, for example, by flashing the illumination background or by lighting a specific zone for the entire time remaining in the alarm time setting mode. The time setting mode may stop automatically after a set time (for example, 15 seconds) after manually touching the hands if no new touch is made.

The flowchart includes the following steps in the case of a simple time setting:

Step E1: display of the time continuously, under the control of the microcontroller controlled by its internal time base.

Step E2: detection by the microcontroller of the touch of a touch zone Za or Zb type inside the dial of the clock; Step E3: verification by the microcontroller: Is the detected zone, whether Za or Zb type, currently displayed? If not, return to the continuous hours display mode, the user having not indicated an intention to change the time; if so, change to time reset mode: steps 4 and following. Step E4: Is the affected area a Zax zone (Za type, small needle) or a Zbx zone (Zb type: large needle complement)? If it is a zone Zbx, we go into minute modification mode: Step E5. If it is a Zax zone, proceed to step E4-1: sub-procedure for determining whether the affected needle is a large needle or a small needle.

Step E4-1: Is there another Zay displayed zone (type Za)? If not, it is that the displayed area Zax represents the small hand well but it is confused with the large, because when the needles are not confused there are necessarily two zones of type Za displayed simultaneously; change to time modification mode: Step E6. If so, one of the two zones Zax and Zay is the little needle, but you must know which one; step E4-2 to determine it.

Step E4-2: Is the Zbx zone in the extension of Zax or the Zby zone in the extension of the Zay zone that is displayed as a complement of the large needle? - if it is Zbx, it is because Zax and Zbx constitute the minute hand and Zay constitutes the hour hand; in the example described here, it is considered that if the user has touched the central part Zax of the minute hand, while there is a separate hour hand Zay, it is that he does not really want the modify (otherwise it would have touched Zbx), and we return to the step E1 display of hours continuously. However, another embodiment could be envisaged in which it is considered that it wishes to modify the minutes even by touching the central part of type Za of the minute hand displayed;

If Zby is displayed, it is because Zax and not Zay represent the hour hand. Change to hours change mode: Step E6.

In all the preceding and following steps, sufficient delaying operations are provided, which are not indicated, in order to avoid untimely detections by inadvertent touching.

Fig. 5 shows the hours changing steps, which may begin with a systematic check (Step E6-0) that the Zax area is affected; this verification will be necessary cyclically thereafter.

Preferably the operations include a blinking trigger of the needle that has been touched and which effectively gives rise to entry into the time modification mode; if the small hand has been touched to change the time, the small hand is flashing: Step E6-1.

The microcontroller then detects whether an area immediately adjacent to Zax is touched (following a movement of the finger). Step E6- 2. If yes, the process of actually changing the time is started. If no, the flashing continues, as long as the Zax zone remains touched. If no adjacent zone has been touched and the zone Zax is no longer touched, the display returns to the continuous time display, the time modification process is interrupted.

If an adjacent area is affected, Zax 'behind Zax or

Zax "in front of Zax, we define Zax 'or Zax" as appropriate as a new value of Zax in the time counter of the microcontroller which sets the current time to display (Step E6-3). This is the resetting step on the new affected position.

The microcontroller then displays the value Zax 'or Zax "as the new current time, in accordance with the new contents of its time counter, and the process is repeated: flashing, detection of the touch of an adjacent zone and new incrementation of time cessation of the process if no adjacent area is affected and the area being displayed ceases to be affected.

The process of changing the minutes is basically the same, with the following differences: Suppose a Zby area, displayed as a large hand, has been hit. It is the Zby zone that serves as a starting point and adjacent Zby 'and Zby' adjacent zones are observed.

Zby to the zone Zby 'or Zby "is observed, then the microcontroller which detected this displacement modifies its contents of current time to settle on the new current minute defined by the new zone and it commands, in correspondence with this minute , the display of a new zone Zby, but obviously also the display of a corresponding zone Zay to display the totality of the big hand at the new current minute .Also, in the preliminary stage of flashing of the touched needle, one preferably blinks the two elements Zay and

Zby and not the only Zby element that was hit.

The alarm time setting is the same as the current time setting, but it is performed after entering the alarm time setting mode and applied to the hands that display the alarm time and not the alarm time. current time. The new alarm clock time is not only displayed but is transmitted to the "clock" function of the clock for execution.

The setting of current time or clock alarm time has been given as an example of application of the invention.

Other examples may be given, without limitation:

- temperature setpoint adjustment of an air conditioner, settings of other air conditioner parameters (ventilation intensity, etc.) - Adjustment of the flow setpoint of a fluid line, adjustment of the position of a valve by visualization of a greater or smaller opening of the valve

- sound volume adjustment, channel balance adjustment, equalizer adjustment, sound spectrum modification adjustment etc. in an audio installation

The cursor is then a tactile zone element displayed among a series of juxtaposed tactile zones and the movement of the finger makes it possible to bring the cursor to another position which visually represents the desired new desired value.

More generally, the invention is directed to all situations in which a variable instruction is displayed in visually intuitive form (cursor position, linear or arcuate band dimension, etc.) and in which the user is desired to be able to easily adjust the displayed setpoint by acting directly on the displayed intuitive shape, to bring it to the new position or to the new shape extension that corresponds to the display of the desired new setpoint.

In the case of a slider which is constituted by the end of a linear or arcuate strip, it is considered that the extent of the strip represents the analog display of the value of the displayed setpoint; in this case, the setpoint modification algorithm does not rely solely on the detection of the movement of the finger towards a neighboring area not displayed, but it also uses the detection of displacement towards a neighboring area already displayed: for example, assuming that the displayed size is even larger than the displayed band extends further to the right (the cursor then being the right end of the band), it is necessary to provide that the finger is placed on the cursor and that

a detection of the movement of the finger on a neighboring zone further to the right (thus not displayed) means that the value of the setpoint must be increased;

- A detection of the movement of the finger to a neighboring area to the left (so already displayed) means that the value of the setpoint must be decreased.

Claims

A display device having a touch display screen structure of which at least a portion is divided into selectively displayable and selectively touch sensitive juxtaposed areas formed with individual electrodes in the shape of the zone to be displayed, each zone representing a possible position of a displayable cursor and a numerical value associated with this position, with selective touch detection means able to detect the position of a finger on a displayed area by proximity detection with the corresponding individual electrode, means for detecting a movement of a finger from this zone to a neighboring zone, means for displaying the cursor on this neighboring zone, and means for transmitting a value corresponding to the new position displayed.

2. Device according to claim 1, characterized in that the displayed cursor position represents in visually analog form the value of a given instruction.

3. Device according to one of claims 1 and 2, characterized in that the cursor position is the end of an elongated linear or arcuate strip which is displayed to give an intuitive representation of the numerical value associated with the position.

4. Device according to one of claims 1 to 3, characterized in that the cursor is displayed in the realistic or symbolic form of a hardware element controlled by the device or a control element of this hardware element.

5. Device according to one of claims 1 and 2, characterized in that it constitutes a clock comprising a touch screen display structure (20) divided into juxtaposed zones selectively displayable and each representing a possible position of a needle element (Za, Zb), with selective touch detection means capable of detecting the position of a finger on a displayed area, means for detecting a movement of a finger from this area to a neighboring area not displayed, and means for resetting the clock at the time corresponding to the neighboring area affected and display of the recalibrated time.

6. Device according to claim 5, characterized in that the touch display screen is divided into at least 60 pairs (Za, Zb) of selectively displayable zones and selectively sensitive to the touch, distributed radially around a virtual center of rotation , each pair having two zones substantially in axial extension from one another, one of the zones (Za), closer to the center, constituting a small-needle display element and the other zone (Zb) further away from the center constituting a complementary display element such that the pair of simultaneously displayed areas represents a large hand.

7. Device according to one of claims 5 and 6, characterized in that the time setting is an alarm time setting.

8. Device according to one of claims 5 to 7, characterized in that the clock comprises:

means for supplying an electronic signal representing the current time, in hour and minute,

means for regular automatic incrementation of the current time and occasional incrementation / decrementation means for setting the time of the current time or of the alarm time to the clock,

means for displaying the zones corresponding to the current time provided, these means being controlled by the current time electronic signal,

- Time reset control means by contact of a finger of the user on a displayed area and rotation of the finger in one direction, the control circuit comprising means for detecting the touch of the finger on the different areas displayed or not displayed, these means acting on the occasional incrementing means for incrementing or decrementing the time according to the direction of rotation when a touch of finger on a displayed area is followed by a touch of a finger on a nearby unseen area.

9. Device according to one of claims 5 to 7, characterized in that it comprises a microcontroller (50), a circuit (40) for controlling the touch screen display, and a microcontroller operating program for

- change a current time from a time base

- change the current time or an alarm time to occasional time reset instructions;

- control the display of the zones corresponding to the current time or an alarm time;

- detect the touch of the touch zones of the screen; - detect if an affected area is displayed and trigger in this case a time reset program;

- during the time setting program, establishing time-setting instructions if an area adjacent to the affected area displayed is touched, the time setting including a time modification corresponding to the position of the said time zone; neighboring area.