DE19632869C1 - Display read-out brightness adjustment method e.g. for motor vehicle dashboard display with dimmer potentiometer - Google Patents

Abstract

A method of adjusting the brightness of an indicator display or read-out(4) in which the pulse duty factor of a PWM control signal is determined and a control or driving signal derived for controlling the brightness of the display (4). A rising or falling edge of the control signal is detected and a timer (9) started, depending on the signal edge. The over-range or off-scale indications of the timer are counted and a falling or rising edge of the control signal is detected, and dependent on this, at an intermediate time point of the counter's state, the counter's over-range readings are stored as an intermediate state. As a result of this, a rising or falling edge of the control signal is detected and dependent on this, at an end time-point of the timer's counter state, the timer's over-range indications are stored as the end state. From the ratio of the end state to the intermediate state, a pulse duty factor proportional to this ratio is determined.

Description

The invention relates to a method for adjusting the hel Ligkeit a display according to the preamble of claim 1. The brightness of a display is e.g. B. with a dimmer tiometer set, depending on its setting a square wave signal with correspondingly long high phases delivers during a predeterminable period of time. A long High phase corresponds to a bright and a short high phase a dark display. The duty cycle between the high phase and the time period of the potentiometer signal forms the Input value, based on which the value ei ner characteristic is read out, the duty cycle of a pulse width modulated signal with which the brightness the display is set.

In the prior art, the duty cycle of the potentiome tersignal for each time period, d. H. for example between two falling edges of the square wave signal, determined, in the one with a high frequency the value of the potentiometer gnals is scanned and the duty cycle is calculated from it becomes. The known method is computationally intensive, however the potentiometer signal is scanned at a high frequency and is evaluated for each time period.

The object of the invention is a simple procedure to determine the brightness of a display len, he only a lower load on the computing unit demands.

The object of the invention is characterized by the features of the spell 1 solved. It is particularly advantageous to use the potentio Do not sample the meter signal, but rather via the stei and the falling edge to determine the duty cycle teln. It is also advantageous to use the potentiometer signal  not for each time period, but in predetermined times Stand to evaluate, which reduces the load on the computing unit is reduced.

Advantageous developments and improvements of the invention are specified in the subclaims.

The invention is explained in more detail with reference to the figures: Show it

Fig. 1 shows an apparatus for performing the method,

Fig. 2 is a potentiometer,

Fig. 3 shows a first example of measurement

Fig. 4 shows a second example of measurement

Fig. 5 shows a third example of measurement

Fig. 6 is a timing protocol

Fig. 7 is a characteristic and

Fig. 8 is a diagram for the brightness setting.

Fig. 1 shows schematically a dashboard 8 of a motor vehicle with a display 4 and a dimmer potentiometer 3 , the dimmer potentiometer 3 via a signal line 6 with a computing unit 1 and the display 4 via a control line 5 with the computing unit 1, which are also connected accesses a memory 2 via a data line 7 and is connected to a timer 9 . Depending on the position, the dimmer potentiometer ter 3 outputs a potentiometer signal with a corresponding pulse duty factor to the computing unit 1 .

Fig. 2 shows the potentiometer signal, which is passed on by the dimmer potentiometer 3 as a control signal via the signal line 6 to the computing unit 1 . At time T1, the potentiometer signal rises from the low value to the high value and falls from the high value to the low value at time T2, and then rises again to the high value at time T3. The dimmer period DP results from the time interval between the time T3 and the time T1. The duty cycle TA of the potentiometer signal is calculated from the time DH in which the potentiometer signal is switched to high in relation to the dimmer period DP. TA = (T2 - T1) / (T3 - T1). Preferably, the duty cycle TA is multiplied by the value 256 and thus relate to a byte.

Fig. 3 shows the schematic program flow of the inventive method. At program point 10 , the signal line 6 is checked by the computing unit 1 to determine whether the potentiometer signal has a rising edge, that is to say a change from low to high, which generates an edge interrupt signal. The computing unit 1 is formed in such a way that a rising or falling edge of the potentiometer signal generates an edge interrupt signal. If this is the case, program point 11 starts computing unit 1 at time T1, timer 9 , which counts up a counter from value 0 to value 256 in 3.072 ms and forwards an overflow interrupt signal to computing unit 1 at value 256 and then starts counting again from 0. The computing unit 1 continuously counts the overflow interrupt signals which are output by the timer 9 .

Subsequently, the computing unit 1 recognizes from an edge interrupt signal at program point 12 that the potentiometer signal is performing a falling edge, that is to say a transition from high to low. If this is the case, the counter reading of the Ti mers 9 is recorded at the time of the edge interrupt signal. Subsequently, the counter reading of the timer 9 and the number of overflow interrupt signals of the timer 9 determined up to that point are written into the memory 2 as the intermediate time T2.

The computer 1 then monitors at program point 13 whether the signal line 6 again carries a rising edge. If this is the case, an edge interrupt signal is generated in the computing unit 1 and the counter reading of the timer 9 at the time of the edge interrupt and the number of overflow interrupts determined in the memory 2 since the start time are entered as the end time T3 .

Finally, at program point 14, the potentiometer signal is evaluated by the computing unit 1 , the dimmer period DP being calculated as follows: DP = T3 - T1. The time during which the potentiometer signal has a high status DH is determined using the following formula: TH = T2 - T1. The normalized duty cycle DT of the potentiometer signal is calculated as follows: DT = (T2 - T1) _* 256 / (T3 - T1).

The normalized duty cycle DT of the potentiometer signal is then used by the computing unit 1 at program point 15 to read the y-value of a dimmer characteristic from a diagram, which represents the duty cycle, in particular the high time, of the pulse-width-modulated signal with which the computing unit 1 the brightness of the display 4 controls. The computing unit 1 reads out the brightness value from the diagram and controls the display 4 with a corresponding pulse-width-modulated signal. The program then branches back to program point 10 .

Fig. 4 shows schematically the signal course of a first measurement example, Fig. 4a shows the course of the pulse width modulated potentiometer signal and the arrows of Fig. 4b, the overflow interrupt signals of the timer 9 , the arrows of Fig. 4c edge interrupt Represent signals as start time T1 for a rising edge, as intermediate time T2 for a falling edge and as end time T3 for a rising edge of the pulse-width modulated potentiometer signal.

The counter values of the timer 9 are shown at the top in FIG. 4b without the number of overflow interrupts and are read out by the computing unit 1 at times T1, T2 and T3, stored in the memory 2 and subsequently taken into account, taking into account the number of overflow interrupts. Interrupt signals, which are shown in FIG. 4b below, and the clock time of the timer 9 calculates the dimmer period DP in accordance with the values of FIG. 4c, in which the counter readings with the overflow interrupts are represented as hexadecimal numbers: DP = (0535H - 0040H) × 12 µs = 1269 × 12 µs = 15.3 ms. The cycle time is 12 µs. The high phase TH is calculated as follows: TH = (0280H - 0040H) × 12 µs = 576 × 12 µs = 6.9 ms. The normalized duty cycle DT then results in: DT = TH _* 256 / DP.

Fig. 5 shows a second measurement example, Fig. 5a shows the pulse width modulated potentiometer signal, Fig. 5b the overflow interrupt signals (overflows) and the counter readings of the timer 9 and Fig. 5c the counter readings of the timer 9 on a rising edge (edges -Interrupt) at time T1, with a rising edge (edge interrupt) at time T2 and with a rising edge (edge interrupt) at time T3.

The dimmer period DP is calculated as follows: DP = (T3 - T1) × ZT = (04C0H - 0010H) × ZT = 1200 × 1245 = 14.4 ms, the time clock ZT of the timer 9 being 12 µs. The high phase DH of the potentiometer signal is calculated as follows: DH = (T2 - T1) × ZT = (0315H - 0010H) × ZT = 773 × 12 µs = 9.3 ms.

Since the falling edge (edge interrupt) occurs at the time T2 almost simultaneously with the third overflow (overflow interrupt) of the timer 9 and the edge interrupt and the overflow interrupt are stored at the same address in the memory 2 , the Computing unit 1 does not differentiate which interrupt took place first. It is therefore necessary to carry out a plausibility check which can be used to determine whether the overflow (overflow interrupt) of the timer 9 or the falling edge (edge interrupt) of the potentiometer signal has taken place first.

This is achieved in that the count of the timer 9 is taken into account when deciding whether an overflow interrupt or an edge interrupt has taken place in such a way that the overflow interrupt signal is first adopted when the count is smaller as a predeterminable count value, in particular 127, and it is assumed that the edge interrupt took place first when the count of the timer 9 is greater than or equal to 127.

Fig. 6 6c shows a third example of measurement, Fig. 6a, the Po tentiometersignal, Fig. 6b, the times of the overflow (overflow interrupt) and the counts of the timer 9 and Fig. Timings of rising or falling edges (edge interrupts) of the potentiometer signal with the counter was taking into account the overflows of the timer 9 at times T1, T2 T3 and the number of overflows of the Ti mers 9 represents. The dimmer period DP is calculated as follows: DP = (T3 - T1) × ZT = (0510H - 00E0H) × ZT = 1072 × 12 µs = 12.9 ms. The high phase DH of the potentiometer signal is calculated as follows: DH = (T2 - T1) × ZT = (02C5H - 00E0H) × ZT = 485 × 12 µs = 5.8 ms.

This results in the following duty cycle DT: DT = (DH _* 256) / DP.

In this embodiment, the falling edge (edge interrupt) of the potentiometer signal at time T2 and an overflow (overflow interrupt) of the timer 9 have occurred almost simultaneously, so that it is necessary to check whether the overflow of the timer 9 or 9 is first the falling edge has occurred. Here, as already described, it is assumed that the overflow interrupt first took place when the counter reading of the timer 9 is less than the predeterminable counter reading 127. The edge interrupt is recognized as the first in time when the count of timer 9 is greater than or equal to 127.

If an event occurs during the determination of the duty cycle, which the computing unit 1 claims, so that the monitoring of the overflows (overflow interrupts) can no longer be carried out, the determination of the duty cycle is interrupted, the already determined values are discarded and the computing unit 1 starts the determination of the duty cycle again.

The determined duty cycle is used to read a brightness value for controlling the display 4 from a dimmer characteristic stored in the memory 2 . In this exemplary embodiment, the pulse duty factor is used as the x value, with which a y value is read from the dimmer characteristic curve shown in FIG. 7, which represents a brightness value with which the display 4 is controlled by the computing unit 1 becomes. Preferably, the display 4 is controlled by a pulse width modulated signal having a duty cycle vorgebba ren, wherein the brightness of the Dis is 4 plays proportional to the duty cycle, which in turn is proportional to the y value of the dimming characteristic (Fig. 7).

A particularly efficient structure of the dimmer characteristic is to divide the dimmer characteristic into four value ranges, as shown in FIG. 7, the first value range defining a minimum brightness which defines the value y1 = 21 for an x value range of x = 0 to x = 55. In this way, for x values that correspond to a duty cycle of the potentiometer signal less than 55, the y value 21 is always passed on to the display 4 .

The second range of values is defined by the two pairs of values (x1 = 55; y1 = 21) and (x2 = 148, y2 = 84), which are connected to each other via a straight line. In the second value range, corresponding to the straight line that runs between the first and the second pair of values, a corresponding y value is read out on the basis of an x value, with which the display 4 is activated.

The y value taken from the diagram is multiplied by the time unit of 12 μs and the pulse duty factor for the pulse-width-modulated signal with which the display 4 is controlled is obtained. With a period of the pulse width modulated signal of 3.072 ms, a time for the high phase of 50 _* 12 µs results at a y value of 50, which leads to a duty cycle of the control of the display of (50 _* 12 µs) / 3.072 ms.

The third range of values extends from the second pair of values (x2 = 148, y2 = 84) to the third pair of values (x3 = 202, y3 = 255). The second and third pair of values are also connected by a straight line with a constant slope. In the second range of values of Verbindungsge is read out in accordance raden between the second and the third pair of values, the dis play 4 starting from the x-value of a corresponding y-value, after which the brightness of the display 4 is set.

The fourth range of values applies to x values that are greater than 202 and to which a constant brightness value of y = 255 is assigned. Each duty cycle of the potentiometer signal, which corresponds to an x value that is greater than 202, is assigned a y value of y = 255, with which the display 4 is controlled.

The brightness of the display 4 is determined according to the following method: the first, the second and the third pair of values are stored in the memory 2 . Likewise, the slope between the first and second pair of values and the second and third pair of values is stored in memory 2 . If the evaluation of the duty cycle of the potentiometer signal shows that the duty cycle has a value less than 55, the display 4 is always activated with a y value of 21. Likewise, the display 4 is activated for a pulse duty factor, the value of which is above the value of 202, with a y value of 255.

Results in the evaluation of the duty cycle of the potentiome tersignals an x-value of 120, so the difference is first between the x-value of the second pair of values that has an up represents point and the determined x-value of 120 ge forms. In this case, the difference is 28.

Then the slope per an x value of the diagram of the first straight line s1, which is stored in the memory 2 and is 0.68 in this exemplary embodiment, is subtracted 28 times from the y2 value of the second pair of values and the brightness value is thus determined with which the display 4 is controlled by the control unit. A continued addition is thus carried out.

The pair of values is preferably used as the starting point, that is closest to the x value of the potentiometer signal.

If the evaluation of the duty cycle of the potentiometer signal results in an x value that lies between the x value of the second and third pair of values, the difference between the determined x value and the second x value is determined. The difference value represents the number that determines how often the slope of the second straight line s2, which is stored in the memory 2 and has the slope 3.16 in this exemplary embodiment, is added to the second y value and the final sum of the continued additions represents the corresponding brightness value with which the display 4 is controlled. If the difference value has the value 10, the slope of the second straight line is added to the second y value ten times. The principle of continued addition is also applied here.

The principle of continued addition can also be used in the process Ren are used, in which the duty cycle to a other way is determined or specified directly becomes. The advantage of computing savings is with every procedure  given, based on an input value (x value) a characteristic curve which, based on a pair of values, has a con constant slope, an initial value (y value) is determined or should be read out.

It is of particular advantage to always start with the second, ie the middle pair of values (x2, Y2) when calculating the brightness, because in this way a simple calculation of the brightness is possible, which also offers the advantage that for the first straight line s1 and the second straight line s2 do not have to be stored in the memory 2 with any graded gradients, but a predetermined number of gradients m is sufficient, as shown in FIG. 8, with which the gradients m between the pairs of values are approximated , whereby the storage requirement for the slopes is reduced.

Due to the limited number of given slopes shown in FIG. 8 for the first and second straight lines s1, s2 and the procedure that the first or second straight line always starts from the second pair of values x2, y2, it is not always possible to that the first pair of values x1, y1 and the third pair of values x3, y3 are precisely controlled. It can thus occur that in the area of the first pair of values x1, y1 and in the area of the third pair of values x3, y3 there is a jump in brightness when driving the display, which is determined by the slope m of the straight line s1, s2 and that of the brightness, which is predetermined by the minimum brightness Smin and by the maximum brightness Smax. However, since this occurs in the area of the minimum brightness and in the area of the maximum brightness, these brightness jumps are, on the one hand, relatively rare and, on the other hand, barely perceptible to the user.

A limited number of different gradients m are specified for the control of the display 4 , which saves memory space in the memory 2 and also the calculation of the brightness of the display 4 using the first, the second and the third pair of values for a simple continued addition or subtraction is reduced. The slopes are stored in a table in memory 2 , which is accessed by the computing unit.

Claims (7)

1. A method for setting the brightness of a display ( 4 ), the pulse duty factor of a pulse-width-modulated control signal being determined and a control signal being determined as a function of the pulse duty factor, with which the brightness of the indicator ( 4 ) is controlled, characterized in that
that a rising or falling edge of the control signal is detected and, depending on this, a timer ( 9 ) is started at a start time,
that the overflows of the timer ( 9 ) are counted,
that a rising or a rising edge of the control signal is detected and depending on it at an intermediate time the counter reading of the timer ( 9 ) and the overflows of the timer ( 9 ) are stored as an intermediate state that thereupon a rising or falling edge of the control signal is detected and depending on it at an end time the counter reading of the timer ( 9 ) and the overflows of the timer ( 9 ) are stored as the final reading, and that a duty cycle proportional to the ratio of the final reading to the intermediate reading is determined from the ratio of the final reading to the intermediate reading. 2. The method according to claim 1, characterized in that at an overflow occurring almost simultaneously and one rising or falling edge the counter reading of the Timers is checked and the time overflow first is detected if the meter reading is below a predeterminable meter reading that the edge is recognized first in time when the Meter reading at this time above a predeterminable meter reading lies. 3. The method according to claim 1, characterized in that with a brightness value from the control signal from a diagram it is read that the dependence between the brightness  value and the control signal is defined by two straight lines, connect the three specified pairs of values. 4. The method according to claim 1, characterized in that for a lower value range and for an upper value range a constant brightness value of the control signal is specified. 5. The method according to claim 3, characterized in that for the straight lines only use a predetermined number of slopes be det. 6. The method according to claim 3, characterized in that the two straight lines with predetermined slopes starting from the middle pair of values towards the third or first pair of values. 7. The method according to claim 3, characterized in that first the value range is determined, in which the duty cycle of the control signal falls, that a pair of values, preferably the closest pair of values, is then selected that the difference between the duty cycle of the control signal and the x- The value of the selected pair of values is determined so that the slope of the straight line of the area into which the duty cycle falls is added or subtracted as often as the value of the difference specifies to the y value of the selected pair of values and thus obtain a y value which specifies the brightness of the display ( 4 ).