JP2010073546A - Switch signal processor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a switch signal processor in which an erroneous operation can be prevented in the case a rotary switch and a pressing switch are mutually arranged in the vicinity. <P>SOLUTION: In the case either one of the rotary switch or a tact switch is operated, from that moment until an elapse of a prescribed time, the switch signal processor inhibits acceptance of an operation signal output by the other switch (Steps F1 to F3, R1 to R3). Accordingly, in the case a user operates one switch and erroneously operates another switch also, if the former operation signal is detected even a little earlier, then the latter operation signal is determined invalid so that occurrence of an unintended operation by the user can be prevented. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a switch signal processing apparatus that processes an operation signal output from a rotary switch and an operation signal output from one or more press switches that are pressed to switch an operation target by the rotary switch.

  In recent years, operation switches such as a vehicle air conditioner, an audio device, and a navigation device tend to be concentrated on the central portion of an instrument panel (instrument panel). However, many of these switches are arranged in a limited and narrow space, so you may accidentally operate another switch or touch the adjacent switch that is in close proximity. It ’s hard.

As a technique for solving such a problem, for example, Patent Document 1 discloses a configuration in which a knob of a dial switch is configured so that not only a rotation operation but also a pressing operation can be performed. And the object of operation by rotation of a knob is switched by pressing operation, and it is made to show with the indicator arrange | positioned on the surface of the knob that the operation object switched. Further, in Patent Document 2, a plurality of operation buttons are provided in the inner area of the dial ring, and by pressing these buttons, the operation target of the ring is switched, and a display indicating the state of each operation object is provided on the ring. A configuration arranged along the outside is disclosed.
JP 2003-54290 A JP 2006-59642 A

  The techniques disclosed in Patent Documents 1 and 2 have been studied for the visibility of the operation state, but are not sufficiently studied for erroneous operations. For example, in Patent Document 1, although it is pointed out in Patent Document 2, there is a possibility that when a knob is rotated, a pressing operation may be detected depending on how a user applies a force. Moreover, in patent document 2, although the operation element which performs rotation operation and press operation is isolate | separated, it does not change that they are arrange | positioned adjacently, and a user will operate both simultaneously carelessly. there is a possibility.

  In the configuration as described above, when two types of operation signals are generated almost simultaneously, what results are obtained depends on what timing the control system processes them. Therefore, if the user accidentally performs a pressing operation when performing a rotating operation, the original intention is to change the state for the current function by the rotating operation, but depending on the processing timing, the pressing operation is detected first. However, a state change due to a rotation operation occurs with respect to the switched function, resulting in an operation result different from that intended by the user.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a switch signal processing device that can prevent an erroneous operation when a rotary switch and a push switch are arranged close to each other.

  According to the switch signal processing device of claim 1, when one of the rotation switch and the push switch is operated, the operation signal output from the other switch until a predetermined time elapses from that point. Is prohibited. Therefore, when the user operates one switch when the other switch is operated by mistake, the latter operation signal becomes invalid if the former operation signal is detected even a little earlier. It is possible to prevent an operation unintended by the user from occurring.

  According to the switch signal processing device of the second aspect, the counter is disposed on each of the rotary switch side and the pressure switch side, and each counter corresponds to the operation signal detected from the other switch first. The counter is configured to start counting for a certain period of time when the operation signal from the switch is prohibited, and to start the count operation when the operation signal from the corresponding switch is detected first. Therefore, the processing of the switch signal can be performed by a logic circuit centered on the counter.

  According to the switch signal processing device of claim 3, the counter outputs data obtained by counting the predetermined time in an initial state, and resets the counting operation when the operation signal from the other switch is detected first. It is configured to start and stop the counting operation when a certain time is counted. Therefore, when a corresponding switch is operated from a default state in which any switch is not operated, the operation signal can be immediately received. When the operation signal of the other switch is detected first, the count operation is reset and started, and a certain period of prohibition period can be generated.

(First embodiment)
A first embodiment of the present invention will be described below with reference to FIGS. FIG. 2 shows the configuration of the switch system of the present invention, which is output from a rotary switch 1 (rotary switch), three tact switches 2a, 2b, and 2c (pressing switches), and these switches 1 and 2. It is composed of a microcomputer 3 (microcomputer, switch signal processing device) for processing operation signals.

The rotary switch 1 includes a rotary operation type operator, and outputs a two-phase signal having a different phase relationship depending on the rotation direction of the operator as an operation signal. The tact switches 2a, 2b, 2c are provided with a push-type operation element, and output an operation signal whose level changes only during a period in which the operation element is pressed.
The microcomputer 3 includes a CPU 4, a ROM 5, a RAM 6, a timer 7, and an input unit 8, which are connected to each other via an address and data bus 9. The input unit 8 is an I / O port of the microcomputer 3 and outputs an operation signal output from the switches 1 and 2 to the CPU 4 via the bus 9.

  The switches 1 and 2 are used to input an operation of an air conditioner mounted on the vehicle, for example, and are arranged on an instrument panel in the passenger compartment. A mode in which the user presses the tact switches 2a, 2b, and 2c so that the operation target of the rotary switch 1 switches the temperature setting (TEMP) and the blowing position (wind direction) to the face / foot / windshield, etc. MODE) and air volume (FAN). When the user rotates the rotary switch 1, the set value of each operation target changes according to the operation amount. That is, in the case of “temperature setting”, the level of the set temperature is changed, in the “mode”, the blower blowing position is switched as described above, and in the case of “air volume”, the rotation speed and the blowing amount of the blower fan are switched. .

  In order to realize the above function, the microcomputer 3 receives the operation signals of the switches 1 and 2 by scanning (switch scanning) through the input unit 8 and according to the control program stored in the ROM 5. Each operation signal is processed, and a control command is output to a main body of an air conditioner (not shown). When the microcomputer 3 recognizes that any of the tact switches 2a, 2b, and 2c has been operated, the LEDs 10a, 10b, and 10c disposed on the operation elements of the switches 2 are connected via an output unit (not shown). Lighting control is also performed (in FIG. 2, the state where the LED 10a is lit is indicated by hatching).

  Next, the operation of the present embodiment will be described with reference to FIG. FIG. 1 is a flowchart showing the switch signal processing performed by the CPU 4, where (a) shows processing related to function switching of the rotary switch 1 when the tact switch 2 side is operated, and (b) shows when the rotary switch 1 side is operated. This is related to the count processing of the operation signal.

In FIG. 1A, when any of the tact switches 2a to 2c is operated, the CPU 4 determines whether or not the “function switching prohibition time counter” is operating (counting) at that time. (Step F1). The “function switching prohibition time counter” is a counter that starts a counting operation in the processing on the side of FIG. If the “prohibited time counter” is in operation at step F1 (YES), the processing is ended as it is and invalidated without receiving the operation signals of the tact switches 2a to 2c.
On the other hand, if the “function switching prohibition time counter” is not operating in step F1 (NO), the operation signals of the tact switches 2a to 2c are received and recognized, and according to the operation amount when the rotary switch 1 is operated. , “Temperature setting”, “Mode”, or “Air volume” to be changed is determined (step F2).

  Then, when the rotary switch 1 is operated, the CPU 4 causes the timer 7 to start detection, that is, to count a time corresponding to a period during which reception of the operation signal is prohibited (step F3). In this case, the prohibition time is set to, for example, about several hundreds μs to several ms, and the operation signal of the rotary switch 1 can be accepted when the time has elapsed. When the timer 7 is a system timer that causes the CPU 4 to generate a timer interrupt, the number of timer interrupts generated may be counted in step F3. In subsequent step F4, related data such as count data for counting the rotational operation amount of the rotary switch 1 is cleared, the count data for the function before switching is erased, and the processing is terminated.

  In FIG. 1B, when the rotary switch 1 is operated, the CPU 4 determines whether or not the “rotary SW switching prohibition time counter” is operating at that time (step R1). The “rotary SW switching prohibition time counter” is a counter that starts the counting operation in step F3 described above. If the “prohibited time counter” is in operation at step R1 (YES), the processing is terminated as it is and invalidated without accepting the operation signal of the rotary switch 1.

  On the other hand, if the “rotary SW switching prohibition time counter” is not operating in step R1 (NO), an operation signal for the rotary switch 1 is accepted and a rotation operation is performed according to the phase relationship between the two-phase signals (for example, ± 90 degrees). The direction, that is, up / down is determined (step R2). Then, when the tact switch 2 is operated, the CPU 4 causes the timer 7 to start detection, that is, to count the time corresponding to the period during which the reception of the operation signal is prohibited (step R3). Also in this case, the prohibition time is set to a time of about several hundreds μs to several ms. In subsequent step R4, the rotational operation amount of the rotary switch 1 is counted and recorded in accordance with the detection result in step R2.

  Here, when the user tries to switch the function of the rotary switch 1 from “TEMP” to “FAN” by operating the tact switch 2 c from the state shown in FIG. 2, the user touches the rotary switch 1 by mistake. A description will be given of how the state changes between the conventional configuration and the configuration of the present embodiment when both switches are operated almost simultaneously (case A).

(A1) When the change of the rotary switch 1 is recognized first <Conventional configuration>
In this case, since the function is switched to “FAN” after changing the temperature setting of the air conditioner while the function of the rotary switch 1 remains “TEMP”, the user undoes the unintended change in the temperature setting. It is necessary to operate the tact switch 2a after operating the tact switch 2a to set the function to "TEMP" and operating the rotary switch 1 to return the temperature setting to the original setting. Therefore, a total of three switch operations are required.

<In the case of the switch signal processing device 3>
Since the function of the rotary switch 1 remains “TEMP” and the temperature setting of the air conditioner is changed, reception of the operation signal of the tact switch 2 is prohibited for a certain period of time, so that the function is not switched to “FAN”. In order to reverse the change in temperature setting as described above, the user simply operates the rotary switch 1 to restore the temperature setting, and then operates the tact switch 2c. Just operation.

(A2) When the change of the tact switch 2c is recognized first <Conventional configuration>
In this case, after the function of the rotary switch 1 is switched to “FAN”, the operation of the rotary switch 1 is recognized and the air volume of the air conditioner changes. However, there is a high possibility that the operation amount of the rotary switch 1 is not what the user planned to change later, or the operation direction is assumed to be reversed. Therefore, for example, the user has planned to reduce the air volume, but if the air volume increases greatly against that intention, the user may be surprised.

<In the case of the switch signal processing device 3>
After the function of the rotary switch 1 is switched to “FAN”, since the operation of the rotary switch 1 is not recognized for a certain time, the air volume does not change, and as a result, only the operation intended by the user is reflected.

  As another case, when the function of the rotary switch 1 is “FAN” and the user tries to change the air volume by operating the rotary switch 1 (case B), the tact switch 2b is erroneously set. A case will be described in which both switches are operated almost simultaneously with contact.

(B1) When the change of the tact switch 2b is recognized first <Conventional configuration>
In this case, since the operation of the rotary switch 1 is recognized after the function of the rotary switch 1 is switched to “MODE”, the “MODE” state is switched from “face” to “front glass”, for example. In order to perform an originally intended operation, the user operates the rotary switch 1 to return to “face”, operates the tact switch 2c to set the function to “FAN”, and then operates the rotary switch 1 to “air volume”. Need to change. Therefore, a total of three switch operations are required.

<In the case of the switch signal processing device 3>
Since the operation of the tact switch 2 is not recognized for a certain time after the function of the rotary switch 1 is switched to “MODE”, the setting is not switched from “face” to “windshield”, and the user switches the tact switch 2c. After operating to set the function to “FAN”, the rotary switch 1 may be operated to change the air volume. Therefore, only a total of two switch operations are required.

(B2) When the change of the rotary switch 1 is recognized first <Conventional configuration>
In this case, after the air volume of the air conditioner is changed by operating the rotary switch 1, the operation of the tact switch 2b is recognized and “MODE” is switched. Therefore, when the user tries to change the air volume further, “MODE” has been switched, and therefore it is necessary to operate the tact switch 2 c to return the function to “FAN”.

<In the case of the switch signal processing device 3>
After the air volume of the air conditioner is changed by the function of the rotary switch 1, the operation of the switch 2 is not recognized for a certain period of time, so the function is not switched to “MODE”, and only the operation intended by the user is reflected as a result. . When the user further changes the air volume, the rotary switch 1 may be operated as it is.

As described above, according to the present embodiment, when one of the rotary switch 1 and the tact switch 2 is operated, the CPU 2 of the microcomputer 3 switches the other switch until a certain time elapses from that point. Since the operation signal output is prohibited, when the user operates one switch, if the other switch is operated by mistake, the former operation signal is detected even a little earlier. For example, since the latter operation signal is invalid, it is possible to prevent an operation unintended by the user from occurring.
The above signal processing by the microcomputer 3 is extremely effective in an environment in which an erroneous operation is likely to occur because the switches 1 and 2 are arranged close to a narrow area like an instrument panel in a vehicle interior.

(Second embodiment)
FIG. 3 shows a second embodiment of the present invention. The same parts as those of the first embodiment are denoted by the same reference numerals and the description thereof is omitted. Hereinafter, different parts will be described. The second embodiment is a case where the function realized by the CPU 3 in software in the first embodiment is realized by hardware logic. As shown in FIG. 3A, the operation signal output by the switches 1 and 2 is given to the switch signal processing device 11.
The switch signal processing device 11 corresponds to an up / down detection unit 12 that detects that the rotary switch 1 has been operated, and an edge detection unit 13 that detects that the tact switches 2a to 2b have been operated. The timers 14R and 14F and the switch control unit 15 are arranged.

The up / down detection unit 12 outputs, to the timers 14R and 14F, a switch detection signal that becomes active (high) when, for example, the edge of the two-phase signal output from the rotary switch 1 is output within a predetermined interval. To do. In addition, the edge detection unit 13 operates the one of the tact switches 2a to 2c so that the one-shot pulse that becomes active (high) by the edge when the level of the operation signal changes, and the switch detection signal as a timer Output to 14R and 14F.
The timers 14 </ b> R and 14 </ b> F operate together with switch detection signals output from the up / down detection unit 12 and the edge detection unit 13, respectively, and output a switch change confirmation signal to the switch control unit 15.

  The switch control unit 15 is directly supplied with a two-phase signal output from the rotary switch 1 and an operation signal output from the tact switches 2a to 2c, and uploads data corresponding to the amount of rotation operation of the rotary switch 1. The hardware logic is configured to select a control object that reflects the rotational operation of the rotary switch 1 in accordance with the operation signals of the tact switches 2a to 2c while down-counting and holding.

  FIG. 3B shows the internal configuration of the timer 14. Although the timers 14R and 14F have the same configuration, the timer 14R will be described with respect to input / output signals. The AND gate 16 receives the switch detection signal from the up / down detection unit 12, outputs a switch change confirmation signal to the switch control unit 15, and sends the same signal to another AND gate 18 via the NOT gate 17. Is also output. The other input terminal of the AND gate 18 is supplied with a switch detection signal from the edge detection unit 13, and the output signal of the AND gate 18 is supplied to the counter 19 as a clear signal.

The counter 19 starts resetting when the clear signal becomes active, and measures the detection prohibition time of the rotary switch 1 by the internal clock (a time of about several hundred μs to several ms as in the first embodiment). Moreover, the counter 19 is configured to continue outputting data when the count of the detection inhibition time is completed even in the initial state.
The count data of the counter 19 is given to a comparator (magnitude comparator) 20 and compared with the data of the register 21 in which data corresponding to the detection inhibition time is set. When the two data match, the comparator 20 outputs a match signal (comparison result) to the other input terminal of the AND gate 16.

  Next, the operation of the second embodiment will be described. In a default state in which neither of the switches 1 and 2 is operated, the switch detection signals from the detection units 12 and 13 are inactive, so that the switch change confirmation signal is also inactive. Since the output signal of the AND gate 18 is also at a low level, the clear signal of the counter 19 is also inactive. However, since the counter 19 outputs count completion data of the detection inhibition time in the initial state, the comparator 20 outputs a coincidence signal to the AND gate 16.

<When rotary switch 1 is operated first>
When the rotary switch 1 is rotated from the above state, the output signal of the AND gate 16 immediately becomes a high level, and the switch change confirmation signal becomes active. Therefore, the switch control unit 15 can generate count data corresponding to the amount of rotation operation of the rotary switch 1. In this case, the operation target (function) by the rotary switch 1 corresponds to the tact switches 2a to 2c operated previously.

  In the above case, when the switch change confirmation signal on the rotary switch 1 side becomes active, one of the input terminals of the AND gate 18 becomes low level. Therefore, even if the switch detection signal of the tact switch 2 is output from the edge detection unit 13 thereafter, the clear signal of the counter 19 is not output and is blocked. Therefore, even if the tact switches 2a to 2c are operated with a momentary delay after the rotary switch 1 is operated first, the operation target by the rotary switch 1 is not switched halfway.

<When tact switch 2 is operated first>
In the default state, since the switch change confirmation signal is inactive, one of the input terminals of the AND gate 18 is at a high level. If any of the tact switches 2a to 2c is operated first from this state and a switch detection signal is output from the edge detection unit 13, a clear signal of the counter 19 is output. Then, the counter 19 resets and starts the count operation, so that the comparator 20 does not output a coincidence signal.
In this case, since the switch change confirmation signal corresponding to the tact switch 2 is output to the switch control unit 15 on the timer 14F side, the switch control unit 15 receives the confirmation signal and determines the operation target of the rotary switch 1. Switch.

  Even if the switch detection signal of the rotary switch 1 is output from the up / down detection unit 12 thereafter, the switch change confirmation signal is not output from the AND gate 16 in the timer 14R. Therefore, even if the rotary switch 1 is operated with a momentary delay after the tact switches 2a to 2c are operated first, the rotational operation amount of the rotary switch 1 is reflected immediately after the operation target is switched, and the user An unintended operation amount is not given.

  As described above, according to the second embodiment, the timers 14R and 14F having the counters 19 are arranged on the rotary switch 1 side and the tact switch 2 side, respectively, and the counter 19 receives the operation signal from the other switch. When it is detected first, it starts counting for a certain period of time to prohibit the reception of the operation signal from the corresponding switch, and when the operation signal from the corresponding switch is detected first, the start of the counting operation is prohibited. I did it. Therefore, the switch signal can be processed by a logic circuit centered on the counter 19.

  In addition, the counter 19 outputs data indicating that the prohibition time has been counted in the initial state, and when the operation signal from the other switch is detected first, the count operation is reset to start counting of the prohibition time. Since the operation is stopped when completed, when the corresponding switch is operated from the default state in which any switch is not operated, the operation signal can be immediately accepted. When the operation signal of the other switch is detected first, the count operation is reset and started, and a certain period of prohibition period can be generated.

(Third embodiment)
FIG. 4 shows a third embodiment of the present invention, and different parts from the first embodiment will be described. In the third embodiment, instead of the tact switches 2a to 2c in the first embodiment, only one tact switch 22 (press switch) is provided, and when the tact switch 22 is turned on, the operation target of the rotary switch 1 is sequentially switched. It is configured as follows. In this case, the control program of the CPU 4A in the microcomputer 3A corresponds to perform the switching control as such.

  In the first embodiment, instead of the LEDs 10a to 10c arranged on the operators of the tact switches 2a to 2c, the LEDs 23a to 23c are arranged independently of the tact switch 22, and the CPU 4A Each time the is turned on, the lighting states of the LEDs 23a to 23c are sequentially switched corresponding to the function switching of the rotary switch 1. The control contents of the first embodiment can be similarly applied to the third embodiment configured as described above.

The present invention is not limited to the embodiments described above and shown in the drawings, and the following modifications or expansions are possible.
The number of pressing switches may be two or four or more.
The configuration of the second embodiment may be combined with the configuration of the first embodiment. That is, the CPU performs software up / down counting according to the amount of operation of the rotary switch 1 by software, and the switch change confirmation signals output from the timers 14R and 14F are replaced with the switch control unit 15 and the CPU. May be given to.
The switch is not limited to a switch arranged on the instrument panel in the vehicle interior, but may be a combination of a rotation switch and one or more push switches to switch the former operation target according to the latter, for example, AV (Audio Visual) It can be widely applied to devices, other home appliances, remote controllers, etc.

The flowchart which is 1st Example of this invention and shows the switch signal processing which CPU performs. Diagram showing the configuration of the switch system FIG. 2 shows a second embodiment of the present invention, where (a) is a diagram corresponding to FIG. FIG. 2 equivalent view showing a third embodiment of the present invention.

Explanation of symbols

  In the drawings, 1 is a rotary switch (rotary switch), 2a, 2b and 2c are tact switches (press switches), 3 and 3A are microcomputers (switch signal processing devices), 11 is a switch signal processing device, and 14R and 14F are timers. , 19 is a counter, and 22 is a tact switch (press switch).

Claims (3)

An operation signal output from a rotary switch having an operation element to be rotated, and an operation signal output from one or more press switches having an operation element to be pressed to switch an operation target by the rotation switch. In the switch signal processing device to process,
When either one of the rotation switch and the push switch is operated, the operation signal output from the other switch is prohibited until a predetermined time has elapsed from that point. Signal processing device. Arranged on each of the rotary switch side and the pressure switch side,
When the operation signal from the other switch is detected first, it starts counting for a certain period of time to prohibit the reception of the operation signal from the corresponding switch,
2. The switch signal processing apparatus according to claim 1, further comprising a counter that is prohibited from starting the counting operation when an operation signal from a corresponding switch is detected first.   The counter outputs data obtained by counting the predetermined time in an initial state. When the operation signal from the other switch is detected first, the counter starts resetting, and when the predetermined time is counted, the counting operation is performed. The switch signal processing device according to claim 2, wherein the switch signal processing device is configured to stop.

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