GB1597411A - Electronic calculating watch with digital display - Google Patents

Abstract

The timepiece comprises means for numerically displaying several items of time-related information. The display for this information is arranged in three rows which can, by selection, provide indications of the current time or indications of particular times at which the sun occupies certain given positions. The timepiece comprises means for calculating these particular times as a function of a stored geographical position and of the time of year determined by the timekeeping function of the timepiece. Control and display-correction buttons (bpH, bpM, bpB) enable the display to be controlled and corrected independently for each row. This timepiece can advantageously serve to determine and display times for Islamic services. <IMAGE>

Description

(54) ELECTRONIC CALCULATING WATCH WITH DIGITAL DISPLAY (71) I, IBRAHIM SALAH, a citizen of Jordan, of Salzhausstrasse 7, 2503 Bienne (Canton of Bern, Switzerland) do hereby declare the invention for which I pray that a patent may be granted to me and the method by which it is to be performed to be particularly described in and by the following statement: This invention relates to electronic timepieces such as watches, particularly to an electronic wrist watch of the type having a digital display and comprising means for calculating and displaying the time.

A great many types of digital-display electronic watches have already been proposed, especially digital-display electronic wrist watches, equipped with various improvements and performing the functions of a chronograph, an alarm, a remainder, etc. On the other hand, there has hitherto never been manufactured, or even simply proposed, an electronic watch of this type which is particularly suited to the needs of the adherents of Islam, i.e., the Moslems. Yet the rites of the Moslem religion are governed by a number of principles quite closely related to the measurement of time, be it the time of day, the time of the (lunar) month, or the time of the year (or season).The calculations used to establish the precise moments of the Moslem calendar and the precise limits of daily times of prayer are relatively complicated, and the tables giving these indications must contain a great many data if it is desired to compile relatively reliable indications for most of the inhablted world.

Until now, it had not occurred to anyone to have these indications calculated and supplied by the electronic circuitry of a digital-display wrist watch, even through this would be a great convenience for the adherents of Islam. It seems that those skilled in the art have heretofore been of the opinion that it was practically not possible, owing the complexity, to introduce this entire "science" into the circuits of a wrist watch.

There is therefore a need for a digital electronic watch, particularly in the form of a wrist watch, which is capable of determining and displaying most of the elements in question which are useful to Moslems and which they are presently obliged to look up in almanacs.

To this end, there is provided according to the present invention an electronic timepiece comprising a digital display and electronic logic for establishing and digitally displaying information relative to particular positions of the sun.

In a preferred embodiment means are provided for determining and displaying one or more of the following particular times of day: the time preceding sunrise by approximately 90 min., the time of sunrise, the time at which the sun passes the meridian, the time of the sinking sun, the time of sunset and the time following setset by approximately 90 min.

"The time of the sinking sun" is used herein to define the time at which the elevation of the sun equals a given angle or, failing that, a specific time between the time at which the sun passes the meridian and sunset.

A preferred embodiment of the invention will now be described in detail with reference to the accompanying drawings, in which: Figure 1 is a front elevation of an electronic wrist watch of the type in question, comprising three lines of digital display; Figure 2 is a table showing some of the combinations of display functions which may be presented on the three display lines of Figure 1, there being shown in Figure 2, successively from A to P, sixteen different combinations from amongst the approximately one hundred or so which are possible; Figure 3 is a general block diagram of the electronic circuitry of the wrist watch in question; Figure 4 (Figures 4A, 4B, 4C and 4D) is a more detailed diagram of a display control, multiplexing, and coding portion shown in Figure 3;; Figure 5 is a detailed diagram showing the arrangement of the input circuits of the push-button switches of the watch in question, these circuits making it possible to obtain, without difficulty, three different control pulses with a single push button in order to limit the number of such buttons, Figure 6 is a waveform diagram (A) together with a logic diagram (B) showing how, in the watch in question, counting of the months of the year is carried out in a manner facilitating both the display of the number of the month and the detection of certain particular states of the counter, e.g., the "February" position, Figure 7 is a waveform diagram (A) together with a logic diagram (B) showing the manner of counting the years and of detecting the information for the periods "beginning of March - end of February", which periods must be known for computing of the parameters which are functions of the orbital position of the earth, Figure 8 is a diagram, together with a table of logical equations, showing the constitution and function of a transcoder for the hour data as shown in Figure 4 (4A), Figure 9 is a waveform diagram (A) together with a logical diagram (B) showing the manner of counting up to about 30 steps for dates in the Gregorian calendar, dates in the Islamic calendar, and the 30-year cycle of Islamic years Figure 10 is a more detailed diagram of a circuit portion shown in figure 3 relating to the determination if Islamic calendar data, and Figure 11 is a diagram, together with a partial plan view, showing the manner of controlling the supplementary display relating to possibilities of correction and to placing the watch in a special operating condition.

From Figure 1, it will be seen that the wrist watch in question comprises a display face on which there are three lines of display, each of which includes four main display locations of one digit each plus two auxiliary locations for displaying one or two dots, on the one hand, and identification symbols, on the other hand. Four push buttons are disposed about the periphery of the watch, three of whch, bpH, bpM, and bpB, are situated on the right-hand side of the watch case, as viewed in Figure 1, each on a level with a display line, and the fourth of which, bpC, is situated on the left-hand side of the watch case, as viewed in Figure 1, being used to establish the conditions under which possible corrections can be effected by means of the other three push buttons.There exist a great number of different possibilities of combining the displays of the three display lines, and besides the possibility shown in Figure 1, sixteen other such possibilities are shown in figure 2.

With the aid of Figures 1 and 2, the completely external operation of the watch in question will first be described. The middle display line is basically reserved for displaying the time of day. For example, Figure 1 indicates 10:28 a.m., as may also be seen in the first part (block A) of Figure 2. The upper and lower lines may be (and most often will be) non-energized so that, as part A of Figure 2 shows, the watch may display nothing but the official time of day. For the upper display line (H), there exists a series of types of data which may be caused to appear successively on this upper line by means of rapid pressures upon the push button bpH.For the upper display line, there is a cycle of five possibilities as follows: H1 resting (possibly tables, as will be explained in detail below), H2 Moslem calendar (day and month, changing at sunset), H3 day of the week (Moslem ritual day, which changes daily at sunset), H4 years (cycle of 30 Moslem years with short years and long years), and H5 next ritual hour (one of six ritual-hour data determined in a matrix and a calculator comprised in the wrist watch).

The display on the lower display line B comprises a more extensive range encompassing nine possibilities. These are: B1 resting (with a possiblity of display in tables, similarly to H1), B2 display of the seconds, recognizable from the fact that it changes each second, without any identification symbol being necessary, B3 calendar date (date and month of the Gregorian year), B4 day of the calendar week (identical with the Moslem day of the week except for changing at midnight instead of at sunset), B5 type of Gregorian year, i.e., 1st, 2nd, or 3rd year (short or common years), or 4th year (long or leap-year), B6 geographical zone (time zones for the longitudes and zone of 10 latitude with indication of "south" or "north" (s, n) in the auxiliary identification field), B7 local correction of latitudes in distance-units of 25 km each, maximum + 39 units or + 975 km.

B8 local correction of longitude effected directly in minutes, the lag (between true noon at the point in question and true noon at the center of the time zone) becoming greater as one proceeds west, and B9 "orientation towards Mecca" given by one of the eight indications S, SE, E, NE, N, NW, W, SW.

Starting from B1 or H1, the information advances by one step in the above-mentioned cycles each time a brief pressure is exerted on the corresponding push button (bpH for the upper line and bpB for the lower line). Moreover, a prolonged pressure causes the display to pass automatically to the last item of the cycle (H5, next ritual hour; B9, orientation towards Mecca); and if the button is pressed twice in rapid succession, the cycle returns to the first position (H1, B1, resting). In any case, a long pressure followed by a short one has the same effect since this leads initially to the last position, and thence back to the first position by an advance of one step.

The middle display line has only two positions which are reversed each time a brief pressure is exerted upon the middle push button bpM. The first position, M1, causes the hour of the Moslem day to appear, i.e., the figure 1 is displayed during the first hour after sunset, the figure 2 during the second hour after sunset, etc., this being approximate and continuing up to 24. As will be seen below, the tables data may also appear in this first position.

The second and last position of the middle display line, i.e., the position M2, causes the official time of day. (standard time) to be displayed, which is the most common function of the wrist watch.

The "tables" function, or more properly the "tables" operating condition, is switched on by means of a prolonged pressure on the middle push button bpM. As soon as the tables operating condition is switched on, the three cycles of the upper, middle, and lower display lines automatically pass into their first positions, but then they need not necessarily remain there, for brief pressures upon the corresponding push buttons can cause the cycles to advance despite the tables operating condition. At the same time, the tables operating condition, which is divided into a first table condition TI and a second table condition TII, causes the appearance in the first position of each of the three cycles of the first three or last three ritual hour data determined in the calculating part of the electronic watch.At H1 and B1, these data occupy an empty place, whereas at M1 they replace the indication of the hour of the Moslem day. Thus, when the tables condition is switched on, the first indications to appear are the first three ritual hours, viz., from top to bottom, "90 minutes before sunrise" on the upper line, "sunrise" on the middle line, and "time when the sun passes the meridian" on the lower line, and "time when the sun passes the meridian" on the lower line. These are the data H1TI, M1TI, and B1TI, respectively. Another prolonged pressure upon the middle push button causes the second half of the tables condition to appear, i.e., the indication of the "sinking sun" time on the upper display line, the indication of the "sunset" time on the middle display line, and the indication of "app. 90 minutes after sunset" on the lower display line.These six indications are each identified by a symbol in the auxiliary display position; each such symbol forms part of an incomplete S, the appropriate segments thereof appearing consecutively from top to bottom for the indications 1 to 6. Starting from the tables operating condition, the cycles may be caused to advance as desired by means of the normal manipulations for controlling the advance or the jump within a cycle; however, as long as the tables condition is operative, the first positions of the H cycle and B cycle will be occupied by ritual hour data rather than resting. By the same token, the middle display line will have either the official time of day (standard time) or a ritual hour indication, rather than either standard time or the hour of the Moslem day.

Each time the next ritual hour indication is displayed, its identification symbol flashes, thereby indicating that precisely this hour is the next ritual hour.

Whenever the ritual hour data (even if not displayed just then) and the standard time data coincide, the watch goes into an alarm condition, i.e., it compels the last position of the cycle to appear in the upper and lower lines, signifying that right at that moment it is the ritual hour to be observed (with its identification symbol), the indication of the direction towards Mecca also being shown. Thus the adherent of Islam will immediately be able to perform the rites which the Koran prescribes for him at that time. It will be noted that when the alarm appears, the table condition is automatically suppressed if it was still proceeding then.

It remains to be explained how the displayed indications can be corrected. It should be noted at the outset that it is not possible to correct the data calculated by the watch if they are based on false premises, i.e., if the watch is not adjusted to the correct day, or to the correct time zone, or to the correct latitude, etc., and therefore the sunset hour (for example) is wrong, the sunset hour cannot be directly corrected and it is the adjustment (day, latitude, etc.) which must be corrected.

As stated above, a fourth push button bpC is situated at the left-hand side of the watch, as viewed in Figure 1. This push button is used to switch on the correction operation condition, either forward or backward, and actuates a cycle of three positions: a zero position, a position for forward correction, and a position for backward correction. For instance, when forward correction is selected (indicated by a small arrow pointing upward which appears at the extreme left of the watch near the button bpC), manipulation of the three line buttons produces quite a different effect. In this situation, a brief pressure on the push button causes a one-step advance--or a one-step reverse if backward correction has been selected--of the first figure on the right, e.g., the units of minutes, of the corresponding line.The result of a longer pressure is an advance (or reverse) of the second figure from the right of the line in question (e.g., the tens of minutes), and finally, a double pressure (push button pressed twice in very rapid succession) causes an advance (or reverse) of the number appearing towards the left of the line, e.g., the units of hours in this instance. If it desired to correct the tens of hours, ten correction of hour units must be made.

The correction functions are automatically adapted to the display functions, i.e., only a displayed indication can be corrected, and it is corrected as a function of the location where it appears on the face of the watch. The same pilot wires which control the appearance of the various indications on the display lines control the possibilities of correction of the counters or registers which supply these indications. As will be seen below, most of these counters or registers operate bidirectionally.

As concerns the display of the "tables operating condition" or "correction operating condition," the watch bears at the lower left, as viewed in Figure 1, a small symbol in the form of an N. Depending upon which of the two sides of the N is removed, the syumbol represents an arrow pointing upward or an arrow pointing downward, corresponding respectively to a forward or backward correction possibility. Moreover, in the "tables operating condition" (which is never switched on simultaneously with the correction operating condition), the first table (or first table portion) TI causes one of the uprights of the "N" to be energized, while the second table (or second table portion) TII causes both uprights of the N to appear, thus yielding the display I or II, respectively.

As concerns Figure 2, it will be noted that the geographical zones "23rd time zone, 2nd zone north latitude" (F) and "3rd time zone, 2nd zone south latitude" (G) actually correspond to inhabited regions, Senegal (Dakar) being in the first of these zones, and the second comprising the whole northern part of Madagascar (Tananarive). As for the location of "time zone 16, 4th zone north," shown in the lower zone in Figure 1, it corresponds to San Francisco.

Finally, a factor which cannot be neglected is the so-called "summer-time" (daylightsaving time), sometimes even "double summer-time," and also, but very rarely, "slow time." All data concerning a time of day given by the watch are normally accompanied by a dot appearing between, and on or above the same line of writing as, the hours and the minutes. If this dot is on the same line, the time is the normal one for that time zone. If the dot appears above the line of writing, the time is summer- or daylight- saving time; and if a colon appears instead of a single dot, it is double summer-time. By the same token, if no dot appears, it signifies "slow time".

To make a correction corresponding to summer- or daylight- saving time, the watch will be set ahead one hour, just as with a mechanical watch, and automatically a "summer-time" register will accept a change-over to summer-time. The same applies to double summer-time (two hours ahead) or slow time (one hour behind). If on the other hand, it is desired to set the watch ahead one hour for the purpose of actualy correcting the setting rather than going on summer- or daylight-saving time, the procedure is to jump three hours ahead, then two backward. The first two jumps forward will put the "summer-time" register in the "double summer-time"position", the third jump ahead will not change that in any way, and the two jumps backward will return the "summer-time" register to its normal position, even through the watch will be set ahead by one hour. To set the watch back, the procedure will be reversed.

For corrections according to changing over the time zone, not the "hour display" but the "time zone display" has to be corrected. "Hour display" correction will automatically follow.

Figure 3 is a general diagram of the electronic watch in question; it comprises legends enabling it to be understood easily. The counting of standard time, from the crystal oscillator and the frequency-divider to the counting of the years, is relatively conventional and requires no particular explanation. In accordance with the months and the years, the number of counts of the days in the month is brought to 28, 29, 30, or 31. This is done by means of a reset circuit which, at the same time, supplies information for marking of the four successive periods recurring from each first of March to the end of February of the following year.This plays a relatively important part in determining the ritual hours, which are connected with sunrise and sunset, and for which it is necessary to take into account as exactly as possible both the position of the earth in its translatory motion about the sun and also the latitude. A calculator portion determines the ritual hours starting from two parameters which are, firstly, the angle a between the axis of the earth and a straight line Joining the centers of the earth and the sun, and secondly, the difference ot between true noon (fluctuating) and integrated noon (consistent). In the middle of a time zone where normal time obtains, e.g., at Greenwich, integrated noon corresponds to standard noon.A matrix stores 96 data, or eight per month, which always fall automatically on the first, the fifth, the ninth, the thirteenth, the seventeenth, the twenty-first, the twenty-fifth, and the twenty-ninth of the month (reference data). For the intervening days, the matrix gives a quantum by means of which the calculator obtains the parameters values by addition of a certan number of quanta. A quantum corresponds to a segment of three hours (1/8 of a day) of the earth's revolution around the sun. Thus, since the parameters are desired for the moment when the sun passes the meridian at the geographic point in question, any displacement of at least three time zones will cause the addition or subtraction of a quantum and, furthermore, one day more will result in the addition of eight quanta.Moreover, the exact values of the parameters are established for a period running from the first of March of a non-leap-year preceding a leap-year to the twenty-ninth of February of this leap-year.

During this period, the values of parameters determined as indicated above are exact. After 29 February, at any given hour of any given day, the earth will always be situated eighteen hours, i.e., six quanta, farther on its orbit than on the same day and at the same hour of the preceding year. Therefore, six more quanta should be added during this first period, and the calculator will do this. Then, during the following period, a quarter of a day has been lost, and no more than four quanta will have to be added. During the following period, it will be but two quanta, and finally, for the period coming just before a twenty-ninth of February, there will be no quanta at all to add.Although the calculator has not been drawn in detail, its mode of operation will be easily comprehended; the data leading to the sides of the block representing the calculator in Figure 3 are presented from top to bottom in the order in which they are taken into consideration by the calculator. Thus, it first considers the date and must, for that purpose, recognize the reference date (e.g., if the date is 15 April, it will recognize the fourth reference date in April, which is 13 April), then the number of days beyond the reference date (e.g., two days--after 13 April-- if it is then 15 April). The reference-date information, valid for a period of four days, is supplied by the third, fourth, fifth bits of the date-counter and by the bits of the month-couner.The first and second bits (of lesser weighting) of the date-counter will give the number of days beyond the reference date and will cause the addition of eight quanta, of sixteen quanta, and of eight + sixteen quanta for one, two, or three days of difference, respectively. Next will come the corrections by six, four, and two quanta to take into account whichever "beginning March - end February" period it is. Then come corrections by quantum which will be made from the time-zone register, with three time zones having the value of one quantum (if so desired, the calculator can be arranged to take into account also at this point the local correction of longitude--up to +79 minutes, 1 arc degree for four minutes--since this local correction may be equivalent to an advance or regression of a time zone).Finally, provision is also made to effect a "Gregorian correction," if necessary, to take into account that a year does not last exactly 365l/4 days. This "Gregorian correction" is simply carried out by hand, e.g., at the watchmaker's, in that a "Gregorian correction register" is caused to advance by one step by briefly grounding a point which may be discovered with the aid of a tool when the watch has been opened (possibly when the battery is being changed). This "Gregorian correction" requires approximately a correction of one quantum every twelve or thirteen years.The above-mentioned procedure will enable the calculator first to calculate the difference between true noon and integrated noon, then, taking into account the local correction of longitude (deviation in minutes from the center of the time zone) and, if need be, the fact that instead of the normal time there is summer- or daylight-saving time (or possibly double summer-time or slow time), to calculate the exact hour and minute when the sun passes the meridian at the location in question, expressed in the standard time system, given by the watch and for all the other watches in that place.

Furthermore, the calculator will calculate the hours of sunrise and sunset. For that purpose, it will consider, firstly, the angle a between the axis of the earth and the earth-to-sun line, and secondly, the latitude X which will be given by the "geographic" register as well as by the local-latitude-correction register.

If it is assumed that the parameter consisting of the angle a does not vary during a single day, the interval between the rising of the sun and its passing the meridian equals the interval between its passing the meridian and sunset. The calculator calculates this interval as a function of the angle a and of the angle X representing the latitude. In the watch, the angle X is entered in the register of zones of latitude, on the one hand, each such zone extending over ten degrees of latitude, and in the register of local corrections, on the other hand; with respect to the middle of a zone, the latter establish positive or negative corrections in units having a value of 25 km, i.e., 0.225 degrees, or 9/40 of a degree.In order to establish the value of the parameter a entering into consideration, the calculator proceeds similarly to what has been described concerning the parameter ot, i.e,, it takes from the matrix a ot value corresponding to a reference date, then it adds a certain number of quanta (the value of a quantum is supplied by the matrix together with the value of the parameter) in order to obtain the value of the parameter a just at the moment and at the location in question.In order to obtain the parameter a at the moment when the sun passes the meridian, exactly the same number of quanta would be added as were added to obtain the value of the parameter ot. However, since sunrise takes place, on an average, about six hours before the sun passes the meridian, and since sunset takes place, on an average, about six hours after the sun passes the meridian, the calculator is arranged to take two quanta less for the value of the parameter a at sunrise and to take two quanta more for the value of the parameter a at sunset.

With the two data concerning the latitude (angle h) and the parameter consisting of the angle between the axis of the earth and the earth-to-sun line (angle a), the calculator is able to calculate the interval between sunrise and the moment when the sun passes the meridian, and the interval between the latter moment and sunset.In order to do so, it applies the following formula: t1 = (12 hr. 00 I a) ti = (12 hr. 00 min.)-I cos-l (tan k ctn During the course of the year, the angle a varies within limits indicated by the following equation: 113 26' > a > 66 34' For the values of a greater than 90 , ti is greater than 6 hr D0 min. because the cosine is negative, whereas for the values of a less than 90 , ti is less than 6hr. 00 min. because the cosine is positive. This means that for the northern hemisphere, the angle a is to be considered the angle formed by the earth-to-sun line with the southern portion of the earth's axis, and vice versa.As a function o the days of the year, the matrix stores the values of the parameter a for the northern hemisphere, i.e., the values of the parameter a corresponding to the angle formed at the center of the earth by the sun-to-earth line and the portion of the earth's axis pointing towards the south pole. For the southern hemisphere, the calculator will take the supplement of the angle a (180 - a) or else will invert the results with respect to 6 hr. (e.g., 7 hr. 13 min. instead of 4 hr. 47 min.). After having determined the intervals t1 for sunrise and sunset, the calculator will check that these intervals are neither less than 4 hr. 30 min. nor greater than 7 hr. 30 min.If that should happen, the calculator would do the calculation over again, taking only one quantum less for sunrise and only one quantum more for sunset if the interval is less than 4 hr. 30 min., and taking three quanta less for sunrise and three quanta more for sunset if the interval is greater than 7 hr.

30 min. Furthermore, if the interval is less than 3 hr. or more than 9 hr., the calculator leaves it at those values and stores this fact.

Once the calculator has calculated the interval, it subtracts the interval relative to sunrise from the standard time at which the sun passes the meridian, thus giving the time of sunrise expressed in terms of standard time; and it adds the interval relative to sunset to the standard time at which the sun passes the meridian, thus giving the time of sunset expressed in terms of standard time. In this way, the calculator determines the second and fifth ritual hours, the third being the time when the sun passes the meridian. To obtain the first ritual hour, the calculator simply subtracts one hour and thirty minutes from the second ritual hour (sunrise); and to obtain the sixth ritual hour, the calculator simply adds one hour and thirty minutes to the fifth ritual hour (sunset).

Theoretically, the fourth ritual hour is that at which the shadow of an obelisk is twice as long as the obelisk itself, meaning that the elevation of the sun must then be 26 30'. The calculator calculates the interval between the sun's passing the meridian and its 26 30' elevation by means of the following formula:: 1 = (12 he. 00mix.) 1 cos~1 (tan X ctn a + sin 26 30 z = (12 hr. 00mm.) - cos X sin a As soon as the geographical point being considered is situated at a relatively high latitude and the date is close to the solstice of the shortest day in the hemisphere being considered, this formula no longer gives any result for the good reason that the sun does not reach 26 30' even at its maximum point, for the maximum height of the sun equals a-k, or for the southern hemisphere, 1800 - a - B. Thus it will be seen that at the winter solstice, the maximum height of the sun is about 26030' approximately at the location of the 40th parallel.As concerns the interval ti, for the fourth ritual hour, the calculator fixes the minimum at 2 hours and the maximum at 7 hr. 30 min.

It has just been seen how the electronic circuitry of the watch establishes the six indications of the Moslem ritual hours. As concerns the "direction towards Mecca", the matrix stores directly the data for 368 of the 384 co-ordinate zones corresponding to the combinations of 24 time zones and 16 zones of latitude (eight for each hemisphere). For the 16 co-ordinate zones surrounding Mecca, extending over the four time zones 1, 2, 3, and 4 and over the four northern hemisphere zones 1, 2, 3, and 4 (each counting 10 of latitude), the matrix supplies information in terms of a division of the co-ordinate zones into three in each direction, i.e., a division into nine. This increases the number of points for which a direction is stored to 128, in addition to the 384 which would exist without this finer division.However, in the 16 restricted fields surrounding Mecca (each of which has a surface area equal to one-ninth of a large co-ordinate zone), a further subdivision takes place which increases the number of locations for which a direction is stored by another 240.

Finally, in the immediate vicinity of Mecca, an even finer division further increases the number of locations to be stored by another 48. Therefore, it is for a total of 800 different locations on the earth that the matrix stores one of the eight data N, NE, E, SE, S, SW, W, and NW. In the matrix, these zones are addressed by the data from the geographical register of the large co-ordinate zones, and from the registers of local latitude correction (in distance units of 25 km, i.e., of 9/40 of an arc degree) and longitude correction (in minutes, i.e., in quarters of an arc degree). At its "direction-of-Mecca" data output, the matrix directly encodes in the desired manner the binary date for the second and third display locations (and indirectly for a part of the fourth one), these coded data, B9, being intended for display on the third display line of the watch.It will be noted that for an approximately square zone of about 25 km on each side in which the city of Mecca itself is situated, the matrix does not supply any data except for the indicator symbol "orientation" in the auxiliary field.

It has just been seen how a number of quite unusual data, pertaining to the Moslem ritual, are determined in the watch in question. The data concerning geographical co-ordinate zones, from the latitude and longitude register, are likewise available for display and, as the case may be, for desired adjustment, at B6. Moreover, the data concerning local corrections for the latitudes (in distance units of 25 km) and for the longitudes (in minutes of time) are also available for display and, if need be, for correction, at B7 and B8, respectively.

It should also be noted that the calculator, which receives high-frequency pulses from the frequency-divider for its operation, automatically carries out a new determination of the six ritual hours each time at least one of the data supplied at its various inputs undergoes a change.

These receives the current time information in minutes and hours, including the information AM/PM, This coincidence stage operates continuously under the effect of a clock frequency which it receives from the frequency-divider, and at six outputs corresponding to each of the ritual hours it supplies logical information indicating either that this ritual hour has already passed during the course of that day (level "0"), or that this ritual hour is still to come or is just then present (level "1"). These six logical data are sent to a "recognition and selection of the next or present ritual hour" stage, which applies a "1" level only on one of its six output conductors which corresponds to the next ritual hour or to the ritual hour corresponding to just the present moment.These output conductors are connected to a symbol-flashing control stage which applies cadenced flashing interruptions to one of six conductors which control the illumination of the identification symbols when the corresponding ritual hour is displayed. These six identification symbols need not be coded at this location because they are each sent directly to a different input of a general coder when a gate circuit selects the corresponding information.

The coincidence detection stage also supplies a signal, over a single conductor, at the very moment when a coincidence is detected with any one of the six ritual hour data. At that moment, an alarm circuit receiving minute pulses starts operating for a period of five minutes, during which it blocks the "recognition and selection of the next or present ritual hour" stage so that this stage remains in the state it then occupies as long as the alarm circuit is operative, even though one minute later the ritual hour in question will be considered to be past within the coincidence detection circuit. An alarm-cancelling order may, however, be given before these five minutes are up by means of a long pressure on the correction-cycle control push button (which controls that cycle only when that push button is pressed briefly).

The output of the alarm circuit is connected to the display-control, multiplexing, and coding circuit and simultaneously to the symbol-flashing control circuit, by which route it stops the flashing of the symbols. When the alarm is given to the display-control, multiplexing, and coding circuit, the latter, which also receives the six outputs of the recognition and selection of the next or present ritual hour circuit, selects, as a function of that one of those outputs which presents a "1" level, the ritual information indicated as being next or present, but which is actually present since the alarm is operating. This display-control stage, upon receiving the alarm, thus causes the obligatory display of this present ritual hour on the upper display line.At the same time, by acting upon the multiplexing scanning circuit, it causes the flashing of all the indications given on this upper display line, so that all the information concerning the present ritual hour flashes. Still at the same time, under the control of the alarm, the display-control, multiplexing, and coding circuit necessarily causes the information on the direction of Mecca to appear on the lower display line, so that the wearer of the watch has right on his wrist, first, the indication of the standard time of day; second, the indication of the fact that a Moslem ritual hour, identified by its identification symbol in the auxiliary display location, is present at that very moment; and third, the indication of the direction of Mecca towards which he must face for his ritual prayers.

As soon as the "cancellation of alarm" order has been given manually, the alarm circuit is reset, even if the five minutes of timing are not yet up, and the watch resumes operation as before. If the alarm cancellation is not actuated manually during those five minutes, the alarm circuit is reset at the end of that period so as not to keep the watch needlessly in alarm condition any longer.

To explain the operation of the alarm simply, it may be said that it automatically causes each of the three display cycles (upper, middle, and lower lines) to pass to its last position, as would be done by a prolonged pressure on each of the two push buttons bpH and bpB, while the standard time would assuredly be displayed on the middle line.

It may be seen from Figure 3 how the cycle for counting Moslem time operates. For that purpose, the coincidence detection circuit additionally supplies a pulse when it detects a coincidence with the fifth ritual hour (sunset). At that moment, it resets a modulo 6 counter which counts the tens of minutes of the standard time of day. Thus, after a period which may last between 51 and 60 minutes according to the moment when sunset took place, a pulse leaves this modulo 6 counter and causes the operation of a 0-9 counter which had been returned to the "1" position at the moment of the sunset pulse. Thus, for approximately one hour, the watch will indicate that the first Moslem hour is then in progress if the position M1 of the cycle of the middle display line is chosen.After an hour, which will correspond to a whole number of tens of minutes of standard time, this indication will become that of the second Moslem hour, then an hour later that of the third Moslem hour, i.e., the third hour after sunset. This 0-9 counter furnishes a carryover to a 0-2 counter which is likewise reset at the moment of sunset, so that this counting and this display of the Moslem time can continue until sunset on the following day, i.e., for twenty-four hours.

The 0-9 and 0-2 counting as a whole is preferably arranged so that it cannot go further than 24, which otherwise might happen, especially because at the vernal equinox, chiefly in the northern regions, up to 24 hours and three or four minutes may pass.

The information concerning the Moslem hour is applied at M1 to the display-control, multiplexing, and coding circuit.

In order to make the operation of the watch correspond to the decisions of certain Moslem governments, the sunset pulse could, if need be, be replaced by a pulse occurring regularly at 6 p.m. every day, or to prevent any indefiniteness, by a pulse occurring at 20 seconds past 6 p.m., for instance. The sunset pulse (or possibly, as a replacement, a 6 p.m.

pulse) is also applied to a set of bidirectional counters which count the Moslem days of the month (almost always alternating between 29 and 30 days), the Moslem months (always 12 in number), and the Moslem years within the 30-year cycle during which common (or short) years and intercalary (or long) years follow one another in a very special order of succession. In the source of this 30-year cycle, the 2nd, 5th, 7th, 10th, 13th, 16th, 18th, 21st, 24th, 26th, and 29th years are long or intercalary years, during which the twelfth month has 30 days instead of 29. In order to distinguish between those cases where the months must have 29 days and cases where the months must have 30 days, a reset circuit is controlled by the Moslem month- and year-counters and acts upon the Moslem date-counter.

Besides that, a 1-7 counter counts the days of the Moslem week, starting each time from the sunset pulse.

From Figure 3, it will be seen that the correction, display-cycle, and alarm-cancellation control circuit (which is shown divided up for ease of illustration), if suitably conditioned, sends correction pulses to the various bidirectional counters as well as to the geographical position registers. It will be noted that the longitude register, which counts the time zones, likewise sends a pulse to the correction control circuit to bring about a corresponding correction of the hours and, in addition, when there is a passage from the 13th to the 12th or from the 12th to the 13th time zone, a corresponding correction of the dates and days of the week which must then change.In order that this may not at the same time cause an improper variation of the computation of the parameters a and ât, the correction of the quanta due to the time zone is such that eight more quanta are added for time zone 13 than for time zone 12. The starting situation is re-established little by little for a person who travels around the word and adapts the longitude register of his watch as he successively crosses the boundaries of the time zones.

Part of the correction control circuit (certain special features of which will be explained in more detail in connection with Figure 5) controls, through the action of the push buttons, the advance of the registers, of the H, M, and B display cycles. This same circuit also controls the tables register, having three positions, "0", "T1", and "T2". The output of this tables register also divides the first outputs of the three registers H, M, and B into three different outputs each. All the outputs of these registers are applied, over a single conductor, to the display-control, multiplexing, and coding circuit so that the latter may suitable select the various data supplied to it in order to cause them to appear on the proper display lines.

Figure 4, composed of figures 4A, 4B, 4C and 4D shows the mode of operation of the display-control, multiplexing, and coding circuit seen in Figure 3. Generally speaking, a shift-register 20 receives a multiplexing frequency fm from the divider and causes a "1" level to pass successively over six conductors of different outputs. These output conductors control gate circuits 21, containing transmission gates, which cause a potential V1 to pass successively over the left half of the upper display line, then over the right half of that line, than over the left half of the middle display line, then over the right-hand part of the latter, then over the left-hand part of the lower display line, then over the right-hand part of the latter, and so on.Thus the potential V1 is led over the common electrode of each of these parts, this potential being such that a high-level potential on the electrodes of segments facing the common electrode causes these segments to be energized. During this time, the other five of these six parts receive a potential V2 (which may, for example, be a medium Potential or a high-frequency variable potential) such that neither a high level nor a low level on the electrodes of segments facing the common electrode can cause the corresponding segment to be energized. Under these conditions, multiplexing is easily carried out, whether it be with a liquid-crystal display device, preferred for the watch in question, or possible with another type of display device, e.g., light-emitting diodes. The segments of the different display locations are driven by transcoding and display-control stages 22, 23, and 24.These transcoders do not encode solely as a function of BCD data they receive at their inputs, but as a function of binary data, with sixteen positions, which makes it possible to display characters other than numerals. The two transcoders 22 and 23 are identical only in the way in which they transcode the ten BCD data; they differ, on the other hand, in the way in which they transcode the other six binary combinations possible with four bits, and this makes it possible to have a large number of symbols other than numerals, the same binary composition giving two different characters depending upon whether it is intended for a first display location of one of the six multiplexing zones (first and third display locations of each line, controlled by the transcoder 23) or for the second display location of each multiplexing zone (second and fourth display locations of each line, controlled by the transcoder 22). As for the transcoder 24, it furnishes a seven-segment display for the identification display location plus a two-dot display for indicating summer-time, etc.The transcoder 24 does not receive BCD information at its input but rather digital information over a number of coductors equal to the number of orders it is to receive. However, the left zone/right zone" multiplexing of each line is not carried out, for the third decoder, at the input thereof, but only over two output conductors of the transcoder 24 since the other information to be multiplexed comprises only two conductors, intended for the two dots. As for the multiplexing among the three display lines--upper, middle, and lower--it is carried out directly on the gates which select the various data likewise as a function of the display-cycle registers.

The two transcoders 22 and 23 are multiplexed at their inputs, by a multiplexing stage 25, controlled "modulo two" by the multiplexing timing register 20.

The inputs of the multiplexing circuit 25 therefore consist of four series of BCD inputs, each of which controls one of the display locations of each line. These inputs are asssumed to contain OR gates having a large number of inputs, as symbolized at reference numeral 25a in figure 4A, where it may be seen that a single line shown as entering the circuit 25a actually includes a plurality of conductors grouped at the inputs of an OR gate.

The two groups of BCD inputs supplying the first zones of the lines are provided with two special transcoders 26 and 27 which are put in operation only on command by signal y and x, these special transcoders being intended to convert the non-BCD four-bit data 12 or five-bit data 32, coming from the hour-counters, as well as from the date- and year-counters in the 30-year Moslem cycle, since, for the remainder of the circuit, it is advantageous for these counters to operate according to a simple four- or five-bit system, whereas for the display, it is necessary to split them into two pairs of BCD-type data, for the tens and the units, respectively.

The upper part of Figure 4 shows a whole series of gates which control the input to the display of the various data which are applied to the display-control, multiplexing, and coding circuit, as shown in Figure 3. These gates 28 to 47 effect the input of the various data only upon the fulfillment of conditions which are represented by data combined in at least one AND gate situated at the input of each of the gate circuits 28-47. When all the control conductors are at level "1", the various conductors which supply the data can "cross" the gate circuit, which contains as many data-input control gates as there are conductors to control. In fact, this number might reach sixteen per gate circuit, but there are generally fewer because each item of information leaves certain bits unoccupied.It will be seen that the gate circuits also open the way for a "1" level controlling one of the 19 inputs of the transcoder 24 to cause the appearance of one of 16 identification symbols for the various data (see Figure 2). Otherwise, the diagram in Figure 4 is explicit enough in itself, taking into account what is also shown in Figure 3, so that there is no need of going into its particularities any further here (these being particularities which those skilled in the art will comprehend simply by looking at the diagram).

Figure 5 shows now it is possible to derive three different pulses, which do not interfere with one another, from a single push-button switch, which performance is effected in the display-cycle correction and alarm-cancellation control circuit shown in Figure 3.

The diagram in Figure 5 shows a flip-flop FF1 which merely repeats, but eliminating the rebounds, the changes of state of a change-over switch. A flip-flop FF3 changes state when the flip-flop FF1 passes to the "1" state, then the flip-flop FF2 follows the flip-flop FF1, and from then on the flip-flop FF3 remains in the "1" state independently until a four-bit binary counter, which receives a 'clock' input at a frequency of 8c/s via a gate controlled by the flip-flop FF3, has succeeded in causing its last stage to flip, after one second. During this time, the flip-flop FF1 follows any possible new changes of the switch contact; and if the flip-flop FF1 reverts to the "0" state while the flip-flop FF3 is still in the "1" state, a further flip-flop FF4 passes to the "1" state. If, subsequent to that, the contact is actuated once again, the flip-flop FF1 will again pass to the "1" state.The period measured by the counter thereupon reaches its end, and when the "1" level has passed to the output D of the counter, the states of the flip-flops FF4 and FF5 are detected. If neither of these flip-flops has changed state, that means that the contact has not been released during one second, i.e., that there was a long pulse. If the flip-flop FF4 has passed to the "1" state, but the flip-flop FF5 has remained in the "0" state, that means that the switch was released during the period in question but that it was not re-actuated. This means that there was a single short pulse of the switch. Finally, if both flip-flops FF4, 5 have passed to the "1" state, that means that during the period of one second, there was a release of the contact, then another actuation thereof.These three states are detected by three gates 51, 52, and 53, respectively, which supply a pulse until the counter is reset, which happens, a quarter of a second later, as soon as the element B of the binary counter has again passed to the "1" state at the same time as the element D. Therefore, the pulses LP, or CP or DP are present for a fraction of a second before the binary counter is reset. On the other hand, it will be seen that only one of the three outputs can supply a pulse each time, the other two never being able to supply any pulse for the same order. It will be noted that if the flip-flop FF1 is in the "1" state when the flip-flop FF3 reverts to the "0" state, nothing happens since the flip-flop FF2 is also in the "1" state. The switch would first have to be released in order for a new control operation to be able to take place.

Figure 6 illustrates the way in which the coding of the twelve months of the year takes place, precisely in five-bit counters in order to supply BCD data for the tens and the units.

A counter operating according to the diagram shown in Figure 6A is easily produced; this may be done by means of gates, by means of selective inhibitions, or in various ways known to specialists in CMOS integrated circuits (this being the technology intended for use in manufacturing the present watch). With the system shown in Figure 6A, not only is a display in BCD quite convenient, but it is also extremely easy, as shown in Figure 6B, to detect particular cases, e.g., all the short months (February, April, June, September, November), or also just February, or even the period March-December as opposed to the period January-February, which is necessary in order to be able to take into account the effects of the leap-years "beginning March - end February" periods mentioned in connection with Figure 3).

Figure 7 shows, analogously to Figure 3, the way in which it is possible to detect the four "beginning March - end February" periods which, on account of the leap-year cycle, require the addition of different numbers of quanta to the parameters supplied by the matrix in order to obtain the desired parameters considering the annual shift by a quarter of a day. The diagram in Figure 7A uses as a basis information prl, obtained in the manner shown in Figure 6B. Besides that, counting stages F and G count the four-year cycle. It is evident from Figure 7B what a very simple logical arrangement, including two exclusive OR gates, four AND gates, and two inverters, makes it possible to obtain the information concerning these four "beginning March - end February" periods.

Figure 8 illustrates the mode of operation, and immediately suggests the type of design, of the special hour-transcoder 26, shown in Figure 4A. The upper part of Figure 8 shows the simple coding of a four-bit, twelve step counter, and the lower part of Figure 8 shows how transcoding should take place in order always to have "twelve" in place of "zero" and to be able to have the tens and the units displayed separately. The curve A" represents the first element of the following BCD stage (tens). Indicated beside the curves A', D', and A" are the relatively simple logical equations which make it possible to obtain the transcoded curves starting from the original curves. These logical equations indicate to those skilled in the art beyond any possible doubt how it is possible to make up the transcoder by means of logical gates.

Figure 9 is the transcoding diagram of the special transcoder 27 shown in Figure 4A.

Owing to the use of a strictly binary code for counting, it is possible not only to dispense with a counter stage but also--and this is important, for example, for supplying the calculator from the date-counter--to have available "quartet" information which can be obtained by taking into account only the last three bits, without having to consider the first two. For the display, on the other hand, the situation is different, and it will be obvious that in particular, the first state must necessarily be the "1" position and not the "0" position.

The right-hand part of Figure 9 shows how the transcoding may be obtained by providing five standard adder stages which transpose the "1" information, after which a conventional CMOS "five-bit binary/2 x BCD" decoder may be used.

Figure 10 shows the make-up of the reset circuits for determining the lengths of the months, taking into account the 30-year cycle of the Moslem years, already mentioned above. In Figure 10, it should be noted that the date- and year-counters operate in the manner shown in the upper part of Figure 9, transcoding taking place only afterwards in the special transcoder 27 of Figure 4. Furthermore, it will be seen that with a relatively small number of gates, it is possible to detect the eleven intercalary years among the thirty of the Moslem cycle. Other than that, the diagram of Figure 10 is explicit enough in itself for those skilled in the art and requires no extensive comment.

Figure 11 illustrates diagrammatically, in agreement with what is shown in the lower right-hand part of Figure 3, the manner in which the two direction correction-control and tables-control registers display their state by means of three tiny segments disposed in the shape of an N at the right-hand side of the watch. It will be seen that when the correction register is not at zero, it automatically energizes the cross-bar of the N. Moreover, depending upon whether it is in the positive or negative correction position, it energizes one or the other of the two uprights, causing the appearance of either an upward-pointing arrow (positive correction) or a downward-pointing arrow (negative correction .As for the register controlling the tables operating condition, which is in any case reset whenever the correction register is not itself at zero position, it energizes either a single one of the uprights of the N or both of these uprights, thereby furnishing the display I or II.

As concerns the coding of the various symbols other than the numerals which may be seen in Figure 2, it should be noted that for the display locations which are first of all controlled in four-bit binary form (16 possibilities), it is important to reserve a possibility of causing an absence of display; for example, 0000 is represented by a single "0". The principle adopted is the following: the second-place figures, i.e., the second and fourth figures of a line, display the zero when it is present, whereas the others do not display zero unless zero is a digit in an indication of minutes, of seconds, or in indications of local corrections.On the other hand, when two particular characters are possible at the same location of a certain item of information, e.g., C or L to indicate "common year" or "long year", it is important that the difference between the combinations controlling these characters applies to only one bit so that the other three bits can be permanently established; besides, this follows from the legends appearing in Figure 4B at the location of the gate circuit 33.

It will also be noted that the auxiliary display location, although having seven segments, is slightly different from those usually encountered. The upper right-hand vertical segment is slanted for the purpose of more easily simulating the letter D (date). In addition, the upper and lower horizontal bars are slightly shorter than the middle horizontal bar, making it easier to simulate the letter s (south).

Finally, as concerns the display, it should be noted that there is some difficulty in displaying the letter W. This difficulty has been avoided by providing a supplementary segment at the level of the lower horizontal segments between the last two display locations at the right of the lower display line. It is only for displaying the letter W that this segment is used, as may be particularly understood from the upper left-hand part of Figure 4A. At the same time that the transcoder 23 energizes this special segment, it gives a command to the transcoder 22 so that the latter, although receiving an order not to energize any of the segments it controls, does energize the two left-hand vertical segments of the display location situated just to the right of the special segment, and this makes it possible to obtain the configuration W as it appears, for instance, in Figures 2K and 2P.

The various controls brought about by the alarm circuit especially concern all the gates 28-47. Those which do not control one of the three data which the alarm causes to appear are all made non-conducting by the alarm, whereas those which must transmit information to be displayed at the time of the alarm receive a command which makes them conducting at that time (naturally only in the phase of the multiplexing cycle which corresponds to them).

Although the watch described exhibits a plurality of functions which are of interest as a whole, it would also be possible to produce the watch in a simpler embodiment comprising only some of these functions, e.g., a watch comprising only the hours which are not easy to calculate namely, those relating directly to the sun, or possible even only those of sunrise, meridian transit, and sunset. As concerns the geographical position, it would also be possible to envisage the introduction of a matrix automatically giving the point of the principal cities of the word, such as Cairo, Teheran, Baghdad, Algiers, Paris, London, New York, San Francisco, Tokyo, etc. At present, the wearer of the watch will use a chart indicating for each city the positions to adjust for the longitude, the latitude, and the local corrections of latitude and longitude.Even without such a chart, the system described makes it possible to find the positions to enter in the registers, simply with the aid of a map.

It would not be absolutely necessary to store in the matrix the directions of Mecca for points which are not on land but rather, e.g., on the high seas. In this way, a certan number of bits could be dispensed with in the part of the memory giving the direction of Mecca.

As concerns the display M1 of the Moslem hours, it would also be possible to provide for counting of exactly 60 minutes at the beginning of the chain, or even for counting starting directly from the seconds. For that purpose, it would suffice (Figure 3) to replace the modulo 6 counter by a 60-minute counter, or even by a cascade comprising a 60-second counter and a 60-minute counter.

A further possibility would be to provide, parallel to the bidirectional standard-time counters shown in Figure 3, a second, analogous counter counting the minutes and the hours, or as a variation, only the hours, of a different time selected at will by the wearer (e.g., New York time when the wearer is in Paris). This different-time information might advantageously be interposed in the cycle of the upper display line between the present last position, H5, which gives the next Moslem ritual hour, and the present penultimate position, H4, which gives the years of the 30-year Moslem cycle. As a variation, this different-time information might be introduced instead in the second position of the cycle of the upper display line, the present positions H2 to H5 then being shifted down one step each.

Whenever the calculator is no longer in a position to calculate the ritual hours exactly and must keep to the indicated limits (minimum interval of three hours and maximum of nine hours for sunrise and sunset, minimum interval of two hours and maximum of seven and one-half hours for the time of the sinking sun), it might be advantageous to indicate this fact when these ritual hour indications are displayed. For that purpose, it would be very simple just to replace the last figure of the indication (the minutes) by a dash, this replacement being made for the display but naturally not for the coincidence detection.

The watch may be still further improved by adding the possibility of causing a supplementary table to appear. This table, which may be called up in a similar way to the tables TI and TII, will given the elevation of the sun at the present moment on the top line, the elevation of the sun at meridian transit on the middle line, and the azimuth of the sun's present position on the bottom line. These values are expressed in arc degrees.The two upper values will be composed of two figures forming a whole number, followed by a point, followed by a figure representing tenths of degrees, followed by a small square standing for the degrees sign (" "). The azimuth will be expressed in degrees counted from the north towards the east, the south, and the west: it will be indicated by a three-figure number representing a whole number of degrees followed by the same sign standing for " ". The identification symbol in the right-hand field will be a "L" (square s without its upper and lower horizontal bars) for the top line (present elevation of sun), the same symbol as for the third ritual hour (meridian transit) for the middle line (elevation of sun at meridian transit), and finally a b-shaped symbol for the bottom line (azimuth of the sun).

This table will be of great advantage, for instance, to persons who design and operate installations for the collection of solar energy, and it may also be very useful to architects who design buildings all over the word and are obliged to calculate the length of shadows cast in different locations and on different dates. As it is above all the middle indication which will be of interest to them (elevation of the sun at meridian transit), they will be able to retain just the center value of the table and cause the date or zone (latitude) indications to appear on another line in the manner described in connection with the first two tables.

Under these conditions, by modifying the date or the zone displayed jointly with the meridian elevation of the sun, they will automatically cause a corresponding correction of the latter indication, a possibility which will be very convenient for their planning. On the other hand, if it is desired to know the characteristics of a shadow at some time other than true noon, it will suffice to cause the local time to appear in the middle field, and the other two indications of the supplementary table in question will make it possible to learn the size and direction of the shadow at that time (for a predetermined date and region).

The proposed watch may also be very useful to airplane pilots who continually have to find out when they will encounter sunrise or sunset during flights which take them to different latitudes and longitudes. The Moslem ritual hours corresponding to sunrise, meridian transit of the sun, and sunset will then be of great use to them. They need only adjust their watch to the zone of the location in question and they will know when the sun will rise or set there, just as they will simultaneously be able to find out the local time there automatically.

With the above-mentioned supplementary table, moreover, another variation of the watch may exhibit an interesting simplification. This will consist in replacing the two tables TI and TII of Moslem ritual hours by a single table simply giving the time of sunrise at the top, the time of the meridian transit of the sun (true noon) in the middle, and the time of sunset at the bottom. With these three indications, Moslems will already know three of their ritual hours, viz., the second, third, and fifth. To calculate the first and sixth, they have only to subtract or add an hour and a half with respect to the second or fifth, respectively.Finally, to learn the fourth ritual hour at least approximately, they may adopt the following very simple rule based upon the indication of the elevation of the sun at meridian transit: if the elevation is less than 30 , the fourth ritual hour will be one-third of the way through the afternoon; if the elevation is between 30 and 45 , the fourth hour will be in the middle of the afternoon; if the elevation is between 45" and 70 , the fourth ritual hour will be two-thirds of the way through the afternoon; and if the elevation is greater than 70 , the fourth ritual hour will be three-quarters of the way through the afternoon.In this context, afternoon is understood to comprise the period between the sun's meridian transit and sunset.

In such a case, both the alarm function and the indication of the next ritual hour are eliminated. The function H5, indicating the next ritual hour, is preferably replaced by the display of the sun's elevation at the present moment. By leaving this indication in function, the Moslem can recognize the second ritual hour (the elevation of the sun ceasing to be zero), the third ritual hour (the elevation of the sun ceasing to increase and starting to decrease, or the elevation of the sun equalling the elevation of the sun at meridian transit, indicated in the table), the fourth ritual hour (elevation of the sun equal to 26.5 ), and the fifth ritual hour (the elevation of the sun becoming zero).The first and sixth ritual hours can also easily be shown by the fact that from sunset to the sixth ritual hour and from the first ritual hour to sunrise, the elevation indicated will be 00.0 , while during the rest of the night it will be 0.0 .

With this solution, it will be preferable to add a third position to the middle display cycle in order to repeat the indication of the geographic zone, so that a pilot, having introduced the time of sunrise on the top line and the time of sunset on the bottom line by means of the table TI, can cause the local time and the zone in question to appear on the middle line. By effecting a correction of zone, he will bring about corresponding modifications of the displayed times of sunrise and sunset.

In a still further simplified version, the indication of the direction of Mecca might be eliminated. In this case, it would be preferable to put the indication of the seconds at the end of the bottom cycle of indications, after the date and geographical indications.

Finally, in a last version intended more for pilots, for example, than typically for Moslems, the watch would no longer exhibit the cycle of indications of the Moslem calendar, nor the indication of Moslem time. The date indications (date and month, day of the week, year) will then preferably be assigned to the positions H2 to H4, and the geographical indications, latitude and longitude, fine latitude, fine longitude, to the positions B2 to B4. As for the position M1, it would be preferable to repeat there the seconds information which never need appear in the tables but which it would be of interest to be able to present separately, without any other indications on the watch, for greater convenience in carrying out timing operations, for instance requiring rapid and accurate reading of the running seconds.

With such a watch, an architect who had caused the supplementary table to appear could retain there only the indication of the elevation of the sun at meridian transit, on the middle line, and he could cause the date (including the month) to be displayed on the top line and the zone (latitude and longitude) to be displayed on the bottom line.

The three indications proposed as variations, viz., the elevation of the sun at meridian transit, the present elevation of the sun, and the present azimuth of the sun, are very easily determined. It has been seen that the elevation of the sun at meridian transit is equal to a X, a being given by the matrix for the indicated orbital position and X being the longitude.

As for the azimuth angle, it is easily calculated starting from the position of true noon, given by the matrix, by counting 1" of arc per 4 min., true noon being at 1800. Finally, the present elevation of the sun is easily calculated by the calculator on the basis of previously acquired data; it will be equivalent to a - 90" - (90 - B) cos t T being the aximuth angle of the sun, counted from the north, like its display.

For the calculation of a, the co-ordinates of date and place will be taken, as indicated in the part of this description relating thereto. In order to account for the orbital path during the fractions of a day in the case of the "present elevation of the sun", one quantum will be added if the present time is more than 1 hr. 30 min. after true noon, two quanta if it is more than 4 hr. 30 min. after true noon, and three quanta if it is more than 7 hr. 30 min. after true noon. Conversely, one, two, or three quanta will be subtracted when the present time precedes true noon by more than 1 hr. 30 min., 4 hr. 30 min., or 7 hr. 30 min., respectively.

Therefore, among other possibilities still existing within the scope of the present invention, the proposed watch can be produced in three variations, one typically intended for Moslems, the second intended for both Moslems and pilots, and the third typically intended for pilots. It will be noted that with this last version, the Moslem can still easily recognize his ritual hours nonetheless, owing to the indication of the present elevation of the sun. For the non-Moslem, the moment when the indication passes from 0.0 to 00.0", and vice versa, will approximately correspond to the beginning of dawn (1 hr. 30 min.

before sunrise) and the end of dusk (1 hr. 30 min. after sunset), respectively.

WHAT I CLAIM IS: 1. An electronic timepiece, comprising a digital display and electronic logic for establishing and digitally displaying information relative to particular positions of the sun.

2. An electronic timepiece according to claim 1, comprising means for determining and displaying particular times of day when the sun occupies certain given positions, said times of day being determined as a function of the geographical position and of the moment of the year.

3. An electronic timepiece according to claim 2, wherein said means are arranged for determining and displaying one or more of the following particular times of day: the time preceding sunrise by approximately 90 min., the time of sunrise, the time at which the sun passes the meridian, the time of the sinking sun, the time of sunset, and the time following sunset by approximately 90 min.

4. An electronic timepiece according to claim 3, wherein said means are arranged for determining and displaying at least the following three times of day: the time of sunrise, the time at which the sun passes the meridian, and the time of sunset.

5. An electronic timepiece according to claim 3, wherein said means are arranged for determining and displaying all six of said times of day.

6. An electronic timepiece according to any preceding claim, comprising three display lines, each having a capacity of at least four characters.

7. An electronic timepiece according to claim 3 and claim 6, comprising means for

**WARNING** end of DESC field may overlap start of CLMS **.

Claims (33)

**WARNING** start of CLMS field may overlap end of DESC **. eliminated. In this case, it would be preferable to put the indication of the seconds at the end of the bottom cycle of indications, after the date and geographical indications. Finally, in a last version intended more for pilots, for example, than typically for Moslems, the watch would no longer exhibit the cycle of indications of the Moslem calendar, nor the indication of Moslem time. The date indications (date and month, day of the week, year) will then preferably be assigned to the positions H2 to H4, and the geographical indications, latitude and longitude, fine latitude, fine longitude, to the positions B2 to B4. As for the position M1, it would be preferable to repeat there the seconds information which never need appear in the tables but which it would be of interest to be able to present separately, without any other indications on the watch, for greater convenience in carrying out timing operations, for instance requiring rapid and accurate reading of the running seconds. With such a watch, an architect who had caused the supplementary table to appear could retain there only the indication of the elevation of the sun at meridian transit, on the middle line, and he could cause the date (including the month) to be displayed on the top line and the zone (latitude and longitude) to be displayed on the bottom line. The three indications proposed as variations, viz., the elevation of the sun at meridian transit, the present elevation of the sun, and the present azimuth of the sun, are very easily determined. It has been seen that the elevation of the sun at meridian transit is equal to a X, a being given by the matrix for the indicated orbital position and X being the longitude. As for the azimuth angle, it is easily calculated starting from the position of true noon, given by the matrix, by counting 1" of arc per 4 min., true noon being at 1800. Finally, the present elevation of the sun is easily calculated by the calculator on the basis of previously acquired data; it will be equivalent to a - 90" - (90 - B) cos t T being the aximuth angle of the sun, counted from the north, like its display. For the calculation of a, the co-ordinates of date and place will be taken, as indicated in the part of this description relating thereto. In order to account for the orbital path during the fractions of a day in the case of the "present elevation of the sun", one quantum will be added if the present time is more than 1 hr. 30 min. after true noon, two quanta if it is more than 4 hr. 30 min. after true noon, and three quanta if it is more than 7 hr. 30 min. after true noon. Conversely, one, two, or three quanta will be subtracted when the present time precedes true noon by more than 1 hr. 30 min., 4 hr. 30 min., or 7 hr. 30 min., respectively. Therefore, among other possibilities still existing within the scope of the present invention, the proposed watch can be produced in three variations, one typically intended for Moslems, the second intended for both Moslems and pilots, and the third typically intended for pilots. It will be noted that with this last version, the Moslem can still easily recognize his ritual hours nonetheless, owing to the indication of the present elevation of the sun. For the non-Moslem, the moment when the indication passes from 0.0 to 00.0", and vice versa, will approximately correspond to the beginning of dawn (1 hr. 30 min. before sunrise) and the end of dusk (1 hr. 30 min. after sunset), respectively. WHAT I CLAIM IS:

1. An electronic timepiece, comprising a digital display and electronic logic for establishing and digitally displaying information relative to particular positions of the sun.

2. An electronic timepiece according to claim 1, comprising means for determining and displaying particular times of day when the sun occupies certain given positions, said times of day being determined as a function of the geographical position and of the moment of the year.

3. An electronic timepiece according to claim 2, wherein said means are arranged for determining and displaying one or more of the following particular times of day: the time preceding sunrise by approximately 90 min., the time of sunrise, the time at which the sun passes the meridian, the time of the sinking sun, the time of sunset, and the time following sunset by approximately 90 min.

4. An electronic timepiece according to claim 3, wherein said means are arranged for determining and displaying at least the following three times of day: the time of sunrise, the time at which the sun passes the meridian, and the time of sunset.

5. An electronic timepiece according to claim 3, wherein said means are arranged for determining and displaying all six of said times of day.

6. An electronic timepiece according to any preceding claim, comprising three display lines, each having a capacity of at least four characters.

7. An electronic timepiece according to claim 3 and claim 6, comprising means for

causing to appear simultaneously, in the form of a first table and on said three display lines, the time of day preceding sunrise by approximately 90., the time of sunrise, and the time at which the sun passes the meridian, and for causing to appear other than simultaneously with the foregoing times, in the form of a second table and on said three display lines, the time of the sinking sun, the time of sunset, and the time following sunset by approximately 90 min.

8. An electronic timepiece according to claim 7, wherein said means are arranged for displaying, simultaneously and in alignment with each of said particular times of day, an identification symbol associated with each of said particular times of day, said symbol appearing flashingly for that one of said particular times of day which is next to come.

9. An electronic timepiece according to claim 2, comprising means for determining as a function of the geographical position, and for displaying with reference to the cardinal points, an indication of the approximate direction in which Mecca situated.

10. An electronic timepiece according to claim 2 or any claim dependant on claim 2, wherein said means are capable of causing the standard or official time of day, determined on the basis of a precision crystal oscillator, to appear on the middle one of three display lines.

11. An electronic timepiece according to any of claims 2 to 10, comprising coincidence detection means for detecting a coincidence between the standard or official time and one of said particular times of day, and upon detection of said coincidence, for displaying said one of said particular times of day, accompanied by an identification symbol associated therewith, on the upper one of three display lines.

12. An electronic timepiece according to claim 11 when dependent on claim 9, wherein said coincidence detection means cooperate with display-control means for further causing said indication of the approximate direction of Mecca to appear on the lower one of three display lines upon the occurrence of a said coincidence.

13. An electronic timepiece according to claim 11 or claim 12, wherein said coincidence detection means cooperate with display-control means for causing the display of the corresponding said particular time of day to flash upon the occurrence of a said coincidence.

14. An electronic timepiece according to any preceding claim, comprising means capable of determining and supplying an indication of the current hour with respect to the beginning of the Moslem day starting at sunset.

15. An electronic timepiece according to any preceding claim, comprising means for determining and displaying the dates of the Moslem calendar.

16. An electronic timepiece according to claim 15, wherein said means are capable of causing to appear, on the upper line of a plurality of display lines, at one time an indication of the Moslem month and day of the month, and at another time an indication of the ordinal number of the current Moslem year in the astronomical cycle of 30 Moslem years, the last mentioned said indication also supplying information as to whether said year is a common year of a long year.

17. An electronic timepiece according to claim 2, comprising means including a matrix supplying for each day, or for successive periods of several days, the necessary astronomical calculation data accompanied by an interpolation quantum, said timepiece further comprising a calculator for calculating said particular times of day on the basis of information contained in said matrix.

18. An electronic timepiece according to claim 1, comprising means for causing to appear stored geographical information concerning longitude, expressed in terms of time zones and of minutes ahead or behind, and concerning latitude, expressed in terms of zones of 10 degrees and of plus or minus correction-distance units, said information displayed by said timepiece being calculated as a function of the geographical location thus stored.

19. An electronic timepiece according to claim 3, comprising means for causing the appearance on one of a plurality of display lines of the next said particular time of day to come.

20. An electronic timepiece according to claim 6, comprising means for causing to appear simultaneously, in the form of a table and on said three display lines, an indication of the elevation of the sun at the current time of day of said timepiece, an indication of the elevation of the sun at the time at which it passes the meridian, and an indication of the azimuth of the sun at the current time of day of said timepiece, said three indications being dependent upon calendar and place information established in said timepiece.

21. An electronic timepiece according to claim 20, comprising means for causing to appear simultaneously, in the form of another table but not simultaneously with the first one and on said three display lines; an indication of the time of sunrise, an indication of the time at which the sun passes the meridian, and an indication of the time of sunset, these three indications being dependent upon calendar and place information established in said timepiece.

22. An electronic timepiece according to claim 21, wherein means are provided for enabling the causing of the appearance of information concerning the elevation of the sun at the current time of day of said timepiece on said upper display line also independently of the table function.

23. An electronic timepiece according to claim 21, wherein means are provided for selectively displaying either time of day or place information on the middle one of said three display lines thereby making it possible to know the times of sunrise and sunset at any point on earth on the date established in said timepiece.

24. An electronic timepiece according to claim 6, wherein said display information is multiplexed starting from the electronic logic circuitry in order to arrive at the display device with a reduced member of electrical connections.

25. An electronic timepiece according to claim 24, wherein the multiplexing device comprises binary decoders, compatible with the BCD system, as well as transcoders put into and out of operation according to the type of information to be displayed, so that the information of the twelve hours may be processed in a four-bit binary system for twelve positions.

26. An electronic timepiece according to claim 25, wherein a matrix, the binary decoders and other information-calculating and display-control members, in order to supply supplementary characters, process binary combinations greater than the "ten" combination.

27. An electronic timepiece according to claim 25, wherein, for the correct operation of the multiplexing device, the back electrode of the display means is subjected to an intermediate potential each time the line in question is not just then being displayed, this intermediate potential being such that no display results therefrom whether the potential of the control electrodes corresponds to the operating state or the resting state.

28. An electronic timepiece according to either claim 24 or 27, wherein said display is a liquid crystal display.

29. An electronic timepiece according to any of claims 6, 7, 10, 14, 15, 16, 20, 21, 22 or 23, comprising on one side three control push buttons, each associated mainly with a display line and making it possible to cause the information displayed on this line to change according to a cycle provided for that purpose.

30. An electronic timepiece according to claim 29, wherein the said push buttons are used to establish the display operating condition and also make it possible to return to the beginning of the cycle of the various functions displayed on each line, each of these push buttons being associated with a corresponding discriminator circuit which defines three pulses to cause them to give different orders according to whether the respective push button has been pressed with a long pressure, pressed rapidly a single time, or pressed rapidly twice in succession.

31. An electronic timepiece according to claim 30, wherein the same push buttons which relate to the display lines are used to make necessary corrections or amendments of the information displayed on their respective lines, this correction, in one direction or the other, being conditioned by the state of a correction register controlled by a push button situated elsewhere on the timepiece, and the slow, quick, or double manipulation of the push button associated with each display line causing a correction of the last digit, a correction of the penultimate digit, or a correction of the first two digits, as the case may be.

32. An electronic timepiece according to any preceding claim in which the timepiece is a wrist watch.

33. An electronic timepiece, substantially as disclosed heretofore with reference to and as illustrated in the accompanying drawings.