CN102253772B - Touch sensing method and related touch device - Google Patents

Abstract

The invention relates to a touch sensing method for a touch device. The touch device comprises a touch panel; the touch sensing method comprises the following steps of: checking whether charging capacity and discharging capacity of a capacitor to be detected in the touch panel have been set; when the charging capacity and the discharging capacity have been set, charging and discharging the capacitor to be detected, and receiving a count value corresponding to the capacitance of the capacitor to be detected; when a basic count value has been set, calculating variation between the count value and the basic count value, and judging whether the touch panel is touched according to the variation; and when the count value is not in a preset range, performing a charging and discharging capacity setting program to update the charging capacity and the discharging capacity.

Description

Touch detection method and relevant contactor control device

Technical field

The present invention relates to a kind of touch detection method and relevant contactor control device, particularly relevant for a kind of method and the relevant contactor control device that can accurately detect touch action.

Background technology

Touch Screen is comprised of a transparent touch-control panel and a display screen, is used for various consumption electronic products, as user's operation-interface.Projected capacitive (Projected Capacitive) contact panel (Touch Panel) is one of most widely used contact panel technology, has high sensitivity and durable advantage, and can realize the multi-point touch function.Please refer to Fig. 1, Fig. 1 is the functional block diagram of a known contactor control device 10.Contactor control device 10 includes a contact panel 100, a multiplexer 102, an electric capacity measuring device 104, a processing unit 106 and an internal memory 108.Contact panel 100 is a projected capacitive touch panel, has staggered ITO (tin indium oxide) sense wire of ranks with the induction touch action, each sense wire equivalence is the circuit that a resistance and an electric capacity form, when human body touch touched control panel 100, the equivalent capacity amount of touched sense wire changed.Multiplexer 102 is coupled to many sense wires of contact panel 100, is used for binding between each sense wire of timesharing conducting and the electric capacity measuring device 104, to finish the scanning of whole contact panel 100.For electric capacity measuring device 104, the equivalent capacity of the sense wire that connects by multiplexer 102 namely is testing capacitance, electric capacity measuring device 104 is converted to recordable numerical value with the testing capacitance amount, such as analog voltage or digital count value, exports processing unit 106 to.

Testing capacitance when contact panel 100 is not touched is environment electric capacity (EnvironmentCapacitor), and its electric capacity is converted to corresponding one basic count value by electric capacity measuring device 104, is stored in the internal memory 108.The size of environment electric capacity is different along with the characteristic of contact panel, the environment electric capacity accurately whether, also affect the correctness of touch detection.When contact panel 100 is touched, the testing capacitance amount can change because body capacitance amount (Human Capacitance) adds, the New count value that processing unit 106 produces electric capacity measuring device 104 conversion testing capacitance amounts with corresponding to the basic count value of environment electric capacity relatively, can judge whether that human body touch touches control panel 100.

The mode that electric capacity measuring device 104 measures the testing capacitance amount has different several modes, wherein the most easy mode is to connect testing capacitance with resistance or constant current source, measure the time that discharges and recharges according to the principle that discharges and recharges time τ=R * C, with estimation testing capacitance amount.The equivalent capacity of the sense wire of contact panel 100 self is minimum, approximately is tens of extremely hundreds of picofarads (pF), and when testing capacitance was environment electric capacity, it was very short to discharge and recharge the time, and the measurement of testing capacitance amount may produce very large error.Another way shifts (Charge Transfer) for carrying out electric charge, electric charge on the testing capacitance is shifted the integrating capacitor (Integrating Capacitor) that is stored to than high capacitance, and carry out one shift the voltage levvl that makes integrating capacitor to for several times electric charge and arrive a predetermined voltage level after, integrating capacitor is discharged, repeat again above-mentioned electric charge transfer step, until obtain accurate testing capacitance amount.Above-mentioned electric charge branch mode only utilizes estimates the testing capacitance amount discharge time of utilization to the time of integrating capacitor charging, and it is lower to measure efficient.

The mode of another known measurement testing capacitance amount is the combination of above two kinds of modes, is called trigonometric integral (Delta-sigma) method.Please refer to Fig. 2, Fig. 2 is the synoptic diagram of a known trigonometric integral formula electric capacity measuring device 20, and electric capacity measuring device 20 can be used to the electric capacity measuring device 104 as Fig. 1.Electric capacity measuring device 20 is comprised of an integrating capacitor 200, a discharge circuit 202, a comparer 204, a digital signal processing unit 206 and interrupteur SW 1, SW2.Please refer to Fig. 3, Fig. 3 is the sequential chart that the electric capacity measuring device 20 of Fig. 2 discharges and recharges the coherent signal of program, and it is described under the different situation of the electric capacity of testing capacitance 22, the voltage V on the signal S1 of gauge tap SW1 and SW2 and S2, the integrating capacitor 200 _CMAnd the sequential of the signal SB that exports of comparer 204, wherein dotted line and solid line represent that respectively the electric capacity of testing capacitance 22 reaches more greatly less situation.

Signal S1, S2 respectively gauge tap SW1, SW2 make power supply V in not simultaneously conducting _CCTo testing capacitance 22 chargings, then carry out electric charge and shift, the electric charge on the testing capacitance 22 is transferred to integrating capacitor 200.When carrying out the electric charge transfer, comparer 204 is with the voltage V on the integrating capacitor 200 _CMWith a reference voltage V _REFCompare, produce a signal SB, simultaneously, digital signal processing unit 206 is converted to a count value Dx with signal SB.As voltage V _CMGreater than reference voltage V _REFThe time, 202 pairs of integrating capacitors 200 of signal SB controlled discharge circuit are discharged.As shown in Figure 3, when the electric capacity of testing capacitance 22 is larger, the electric weight that is transferred to integrating capacitor 200 is also more, so the dutycycle of signal SB (DutyCycle) is larger.

In brief, electric capacity measuring device 20 is the electric capacitys that represent testing capacitance 22 with the dutycycle of signal SB, and signal SB is converted to count value Dx, for the electric capacitance change of back-end processing circuit judges testing capacitance 22.Mode compared to the time that discharges and recharges of direct measurement testing capacitance 22 or the number of times estimation testing capacitance amount that only shifts according to electric charge, when testing capacitance is the minimum environment electric capacity of electric capacity, the result who measures environment electric capacity gained with electric capacity measuring device 20 is more accurate, it is also higher to measure efficient, but still have many shortcomings on the implementation, be described as follows.

Electric capacity measuring device 20 is 22 pairs of known integrating capacitors of testing capacitance, 200 chargings with the unknown., electric capacity measuring device 20 measures the contact panel of various characteristics for being applicable to, the electric capacity of known integrating capacitor 200 must be much larger than the electric capacity of testing capacitance 22, approximately be tens of how farads (nF), therefore, no matter integrating capacitor 200 is to be integrated in the integrated circuit or as external module, all to need very high cost.If integrating capacitor 200 is external modules, integrating capacitor 200 is disturbed by external electromagnetic ripple signal easily, causes the voltage V on the integrating capacitor 200 _CMUnstable, therefore, the signal SB that comparer 204 produces contains noise, affects the degree of accuracy of back-end processing circuit judges electric capacitance change.

On the implementation, when finish discharge time, the voltage V on the integrating capacitor 200 _CMMust return the initial voltage level in duration of charging; In other words, discharge capability must be greater than charging ability.When the electric capacity of testing capacitance 22 is very large, the quantity of electric charge that is transferred to integrating capacitor 200 by testing capacitance 22 electric charges is also large, if the deficiency of time of 200 pairs of discharge circuits of integrating capacitor this moment, 202 discharges, the voltage V on the integrating capacitor 200 _CMCan't when finish discharge time, return the initial voltage level and additive effect occur.Please refer to Fig. 4, Fig. 4 is the sequential chart that electric capacity measuring device 20 discharges and recharges the coherent signal of program.As shown in Figure 4, as voltage V _CMAdditive effect occurs, finally may reach current potential identical when being full of electricity with testing capacitance 22, electric charge shifted and can not occur this moment, and electric capacity measuring device 20 can't be brought into play the measurement effect.When the problems referred to above cause charging ability greater than discharge capability in the environmental factor drift, also occur easily.

On the other hand, when testing capacitance 22 during much smaller than integrating capacitor 200, the voltage variety that at every turn carries out on the rear integrating capacitor 200 of electric charge transfer is minimum, relatively the discharge capability of discharge circuit 202 is larger, need the longer time that integrating capacitor 200 is charged to effective scalable voltage levvl, cause the measurement waste of time.Moreover, to judge the electric capacitance change of testing capacitance 22 too short discharge time, the acquired results out of true.

As from the foregoing, in known electric capacity measuring device, charging and discharging capabilities is the adjustable elasticity of tool not, can't reach identical degree of accuracy when being used for the contact panel of different qualities.In addition, when same contact panel uses or environmental factor when causing the environment electric capacity to change because of long-time, known electric capacity measuring device and method for measurement can't flexibly measure new environment electric capacity.Thus, when contact panel was touched, the back-end processing circuit may be because there be accurate environment electric capacity for relatively, can't correctly detect touch action.

Summary of the invention

Therefore, fundamental purpose of the present invention namely is to provide a kind of touch detection method and relevant contactor control device.

The invention provides the touch detection method for a contactor control device, this contactor control device includes a contact panel, this touch detection method includes: check whether a charging ability and a discharge capability are set, this charging ability and this discharge capability are in order to discharge and recharge a testing capacitance in this contact panel; When this charging ability and this discharge capability have been set, this testing capacitance is discharged and recharged, and receive a count value, this count value is corresponding to the electric capacity on this testing capacitance; Check whether a basic count value is set, the electric capacity of this testing capacitance when this basis count value is not touched corresponding to this contact panel; When this basis count value has been set, calculate the variable quantity between this count value and this basis count value, to judge according to this variable quantity whether this contact panel is touched; Check whether this count value is positioned at a preset range; And when this count value is not in this preset range, carry out a charging and discharging capabilities setting program, to upgrade this charging ability and this discharge capability.

Description of drawings

Fig. 1 is the functional block diagram of a known contactor control device.

Fig. 2 is the synoptic diagram of a known trigonometric integral formula electric capacity measuring device.

Fig. 3 and Fig. 4 are the sequential charts that the electric capacity measuring device of the 2nd figure discharges and recharges the coherent signal of program.

Fig. 5 is the synoptic diagram of the embodiment of the invention one electric capacity measuring device.

Fig. 6 is that the electric capacity measuring device of Fig. 5 is set as and fills first under the situation of putting afterwards configuration the sequential chart of coherent signal when discharging and recharging program.

Fig. 7 is that the electric capacity measuring device of Fig. 5 is set as and puts first under the situation of filling afterwards configuration the sequential chart of coherent signal when discharging and recharging program.

Fig. 8 is the synoptic diagram of the embodiment of the invention one flow process.

Fig. 9 is that the electric capacity measuring device of Fig. 5 is set as and fills first under the situation of putting afterwards configuration, the sequential chart of coherent signal when discharging and recharging program, and it describes the adjustment of charging ability.

Figure 10 is that the electric capacity measuring device of Fig. 5 is set as and fills first under the situation of putting afterwards configuration, the sequential chart of coherent signal when discharging and recharging program, and it describes the adjustment of discharge capability.

Figure 11 is that the electric capacity measuring device of Fig. 5 is set as and fills first under the situation of putting afterwards configuration, the sequential chart of coherent signal when discharging and recharging program, and it describes the relation of testing capacitance amount and coherent signal.

Figure 12 is the synoptic diagram of the embodiment of the invention one flow process.

Figure 13 is the synoptic diagram of the embodiment of the invention one electric capacity measuring device.

Figure 14 is that the electric capacity measuring device of Figure 13 is set as and fills first under the situation of putting afterwards configuration, the sequential chart of coherent signal when discharging and recharging program, and it describes the relation of testing capacitance amount and coherent signal.

The 15th is that the electric capacity measuring device of Figure 13 is set as and puts first under the situation of filling afterwards configuration, the sequential chart of coherent signal when discharging and recharging program, and it describes the relation of testing capacitance amount and coherent signal.

Figure 16 is the synoptic diagram of the embodiment of the invention one electric capacity measuring device.

Wherein, description of reference numerals is as follows:

10,50 contactor control devices 510,610,710 cycle control circuits

100 contact panels 512,612,712 voltage generation units

102 multiplexers 514,516,614, discharge and recharge control module

616、714、716

104 electric capacity measuring devices 518,618,718 analog to digital converters

106,504 processing units 520,620,720 cycle detection circuit

108,506 internal memories 522,622,722 analog to digital converters

20,502,602,702 electric capacity measuring device SW1～SW3 switches

22,500,600,700 testing capacitance S1～S3, SB, SD, signal

SD2

200 integrating capacitor Dx, DL, DU count value

202 discharge circuit V _CMVoltage

204 comparer V _REF, V _U, V _L, reference voltage

V _REF1～V _REF3

206,524,624, single 80,120 flow processs of digital signal processing

724 yuan

800,802,804, step

806、808、810、

812、1200、1202、

1204、1206、1208、

1210、1212、1214、

1216

Embodiment

Please refer to Fig. 5, Fig. 5 is the synoptic diagram of the embodiment of the invention one contactor control device 50.Contactor control device 50 includes a testing capacitance 500, an electric capacity measuring device 502, a processing unit 504 and an internal memory 506.In fact, contactor control device 50 comprises a contact panel and a multiplexer in addition, omit to indicate the equivalent capacity of the sense wire of the contact panel that testing capacitance 500 couples by multiplexer for electric capacity measuring device 502 in Fig. 5.Electric capacity measuring device 502 includes a cycle control circuit 510 and a cycle detection circuit 520.Cycle control circuit 510 includes a voltage generation unit 512, discharges and recharges control module 514,516, an analog to digital converter (Analog-to-digital Converter) 518 and interrupteur SW 1～SW3.Cycle detection circuit 520 includes an analog to digital converter 522 and a digital signal processing unit 524.

Electric capacity measuring device 502 is used for measuring the electric capacity of testing capacitance 500, and the measurement mode is that testing capacitance electricity 500 is discharged and recharged, simultaneously with the voltage V on the testing capacitance 500 _CMBe converted to a count value Dx, count value Dx represents testing capacitance 500 electric capacitys.The basic count value that internal memory 506 stores corresponding to the environment electric capacity of contact panel.Processing unit 504 is coupled to electric capacity measuring device 502 and internal memory 506, be used for according to the variable quantity between count value Dx and the basic count value, judged whether that touch action occurs, when variable quantity greater than a predetermined value, judge that touch action occurs, otherwise judge that then touch action does not occur.In addition, processing unit 504 is according to count value Dx, adjusts charging ability and the discharge capability of 502 pairs of testing capacitances 500 of electric capacity measuring device, but not as the fixedly charging and discharging capabilities of electric capacity measuring device 20 among the 2nd figure.

Electric capacity measuring device 502 is described in detail as follows.Cycle control circuit 510 is coupled to testing capacitance 500 and processing unit 504, is used for testing capacitance 500 is discharged and recharged.Voltage generation unit 512 is used for producing reference voltage V _REF1, V _REF2And V _REF3Discharge and recharge control module 514 and 516 according to its hardware design, wherein a control module is set as the charging configuration, and in order to testing capacitance 500 is charged, another control module is set as the discharge configuration, in order to testing capacitance 500 is discharged, charging and discharge capability are adjusted by processing unit 504.Adjustment to the charging and discharging capabilities of testing capacitance 500 can be illustrated in the variation in the cycle of discharging and recharging.The hardware implementation mode that discharges and recharges control module 514 and 516 is not limited to any ad hoc rules, but need guarantee that both chargings and discharge capability are capable of regulatings, for example can use simple switch and adjustable electric capacity, adjustable electric capacity is precharged to carries out electric charge behind the suitable voltage levvl and shift, or with adjustable electric current source, or discharge and recharge control module (or claiming charging control unit) with what the modes such as voltage source resistance in series realized charging configuration.In like manner, the discharging and recharging control module (or claim control of discharge unit) and can use adjustable electric current source to realize of discharge configuration, or directly pass through resistance eutral grounding.

It should be noted that the electric capacity that discharges and recharges control module for the charging configuration, its electric capacity can be very little and be integrated in the integrated circuit of electric capacity measuring device 502, and is different from the integrating capacitor of known external high capacitance.Therefore, electric capacity measuring device 502 has been saved the cost of external capacitor, and because the electric capacity that discharges and recharges in the control module is not external module, is not easy to be disturbed by electromagnetic wave signal, and then guarantees the degree of accuracy of electric capacity measuring.

Interrupteur SW 1 is coupled to voltage generation unit 512 and testing capacitance 500, is used for according to a signal S1 control reference voltage V _REF1And the binding between the testing capacitance 500.When signal S1 gauge tap SW1 conducting, 512 pairs of testing capacitances of voltage generation unit 500 carry out pre-charge, make the voltage of testing capacitance 500 equal reference voltage V _REF1, purpose is to reduce error in measurement.Interrupteur SW 2 is coupled to and discharges and recharges control module 514 and testing capacitance 500, be used for according to a signal S2, control discharges and recharges the binding between control module 514 and the testing capacitance 500, make and discharge and recharge 514 pairs of testing capacitances of control module 500 charging (or discharge, decide according to discharging and recharging the configuration of control module 514).

Analog to digital converter 518 is one 1 (bit) analog to digital converters, is equivalent to a comparer, is coupled to voltage generation unit 512 and testing capacitance 500, is used for according to reference voltage V _REF2With the voltage V on the testing capacitance 500 _CMBe converted to a signal S3.In other words, analog to digital converter 518 is with voltage V _CMWith reference voltage V _REF2Compare, signal S3 represents comparative result.Interrupteur SW 3 is coupled to analog to digital converter 518, discharges and recharges control module 516 and testing capacitance 500, be used for according to signal S3, control discharges and recharges the binding between control module 516 and the testing capacitance 500, make 516 pairs of testing capacitances of control module 500 discharge (or charging, decide according to discharging and recharging the configuration of control module 516).

Analog to digital converter 522 is one 1 analog to digital converters, is equivalent to a comparer, is coupled to voltage generation unit 512 and testing capacitance 500, is used for according to reference voltage V _REF3With the voltage V on the testing capacitance 500 _CMBe converted to a signal SB.Digital signal processing unit 524 is coupled to analog to digital converter 522, is used for signal SB being converted to count value Dx after through a plurality of runnings that discharge and recharge the cycle, exports processing unit 504 to.Digital signal processing unit 524 can be considered a totalizer, is with a predetermined sampling frequency signal SB to be taken a sample, and the accumulative total sampling result.In brief, cycle detection circuit 520 is with the voltage V on the testing capacitance 500 _CMBe converted to count value Dx.Because voltage V _CMWaveform represent that cycle that discharges and recharges of testing capacitance 500 and count value Dx are according to voltage V _CMAnd produce, so count value Dx represents the cycle that discharges and recharges of testing capacitance 500, also represents the electric capacity of testing capacitance 500.

Note that to discharge and recharge control module 514 and discharge and recharge control module 516 to be set as charging configuration or discharge configuration, the sequencing that carries out charge or discharge with electric capacity measuring device 502 is relevant.Are charging configurations and to discharge and recharge control module 516 are discharges during configuration when discharging and recharging control module 514,502 pairs of testing capacitances 500 of electric capacity measuring device charge first and discharge afterwards, are called to fill first and put afterwards configuration.Are discharge configurations and to discharge and recharge control module 516 are chargings during configuration when discharging and recharging control module 514,502 pairs of testing capacitances 500 of electric capacity measuring device discharge first and charge afterwards, are called to put first and fill afterwards configuration, with Fig. 6 and Fig. 7 explanation.

Please refer to Fig. 6, Fig. 6 is that electric capacity measuring device 502 is set as and fills first under the situation of putting afterwards configuration, and the sequential chart of coherent signal when discharging and recharging program is wherein described signal S1～S3, voltage V _CMAnd signal SB.Are charging configurations and to discharge and recharge control module 516 are discharge configurations when discharging and recharging control module 514, and reference voltage is set as V _REF3〉=V _REF2≈ V _REF1The time, by signal shown in Figure 6 as can be known, interrupteur SW 1 is closed after conducting a period of time when the program that discharges and recharges is initial, and testing capacitance 500 is precharged to reference voltage V _REF1When interrupteur SW 2 conducting, discharge and recharge control module 514 and carry out the electric charge transfer, to testing capacitance 500 chargings.Because reference voltage V _REF2Approximate reference voltage V _REF1, so voltage V _CMRise to soon and be greater than or equal to reference voltage V _REF2, the signal S3 gauge tap SW3 conducting that this moment, analog to digital converter 518 was exported discharges and recharges 516 pairs of testing capacitances 500 of control module and discharges.Discharging action continues to signal S3 gauge tap SW3 and closes, that is voltage V _CMBe less than or equal to reference voltage V _REF2The time till.Discharging and recharging control module 514 and begin to carry out electric charge and be transferred to and discharge and recharge control module 516 and stop to discharge during this period of time, is one to discharge and recharge the cycle.After a plurality of runnings that discharge and recharge the cycle, digital signal processing unit 524 is converted to count value Dx with signal SB.

Be set as in electric capacity measuring device 502 and fill first when putting configuration afterwards, above-mentioned reference voltage is set V _REF3〉=V _REF2≈ V _REF1Only be one embodiment of the invention, reference voltage also can be designed to V _REF3〉=V _REF2〉=V _REF1, to be applicable to the great situation of testing capacitance amount.In this case, discharging and recharging control module 514 need to shift through electric charge repeatedly, with voltage V _CMCharge to and be higher than reference voltage V _REF3And reference voltage V _REF2

Please refer to Fig. 7, Fig. 7 is that electric capacity measuring device 502 is set as and puts first under the situation of filling afterwards configuration the sequential chart of coherent signal when discharging and recharging program.Are discharge configurations and to discharge and recharge control module 516 are charging configurations when discharging and recharging control module 514, and reference voltage is set as V _REF3≤ V _REF2≈ V _REF1The time, by signal shown in Figure 7 as can be known, interrupteur SW 1 is closed after conducting a period of time when the program that discharges and recharges is initial, and testing capacitance 500 is precharged to reference voltage V _REF1When interrupteur SW 2 conducting, discharge and recharge control module 514 and carry out the electric charge transfer, to testing capacitance 500 discharges.Voltage V on testing capacitance 500 _CMDrop to and be less than or equal to reference voltage V _REF2The time, signal S3 gauge tap SW3 conducting discharges and recharges 516 pairs of testing capacitances 500 of control module and charges.The charging action continues to signal S3 gauge tap SW3 and closes, that is the voltage V on the testing capacitance 500 _CMBe greater than or equal to reference voltage V _REF2Till.After a plurality of runnings that discharge and recharge the cycle, digital signal processing unit 524 is converted to count value Dx with signal SB.Be set as in electric capacity measuring device 502 and put first when filling configuration afterwards, above-mentioned reference voltage is set V _REF3≤ V _REF2≈ V _REF1Only be one embodiment of the invention, reference voltage also can be designed to V _REF3≤ V _REF2≤ V _REF1, to be applicable to the great situation of testing capacitance amount.

Processing unit 504 is coupled to and discharges and recharges control module 514,516, digital signal processing unit 524 and internal memory 504.As aforementioned, processing unit 504 is used for according to the variable quantity between count value Dx and the basic count value, has judged whether that touch action occurs, and according to count value Dx, charging ability or the discharge capability of 510 pairs of testing capacitances 500 of adjustment cycle control circuit.In addition, signal S1, the S2 of gauge tap SW1, SW2 are produced by processing unit 504.

Processing unit 502 is adjusted the mode of charging and discharging capabilities, illustrates that such as Fig. 8 Fig. 8 is the synoptic diagram of the embodiment of the invention one flow process 80.Flow process 80 is used for adjusting charging ability or the discharge capability of electric capacity measuring device 502 for the treatment of unit 504.Flow process 80 includes following steps:

Step 800: beginning.

Step 802: receive corresponding to the voltage signal V on the testing capacitance 500 _CMCount value Dx.

Step 804: check that count value Dx is whether less than a higher limit of a preset range.If carry out step 808; If not, carry out step 806.

Step 806: downgrade the charging ability of electric capacity measuring device 502 or increase the discharge capability of electric capacity measuring device 502, get back to step 802.

Step 808: check that count value Dx is whether greater than a lower limit of this preset range.If carry out step 812; If not, carry out step 810.

Step 810: increase the charging ability of electric capacity measuring device 502 or downgrade the discharge capability of electric capacity measuring device 502, get back to step 802.

Step 812: finish.

By flow process 80 as can be known, processing unit 504 judges with a predetermined count value scope DL～DU whether count value Dx is too high or too low, correspondingly to adjust charging ability or discharge capability, the too high or too low expression environment of count value Dx electric capacity may change because of the laying dust on external factor such as temperature, humidity or the contact panel.Predetermined count value scope can be set according to the maximum count value that processing unit 504 may receive, and for example upper limit count value DU is set as 80% of maximum count value, and lower limit count value DL is set as 20% of maximum count value.

Step 804 and step 808 can be summarized as: check whether count value Dx is positioned at preset range, and step 806 and step 810 can be summarized as: charging ability or the discharge capability of adjusting electric capacity measuring device 502.When count value Dx greater than upper limit count value DU, processing unit 504 judges that count value Dx are too high, must downgrade charging ability or increase discharge capability; When count value Dx less than lower limit count value DL, processing unit 504 judges that count value Dx are excessively low, must increase charging ability or downgrade discharge capability.The adjustment of 504 pairs of charging and discharging capabilities of processing unit is carried out until count value Dx is positioned at predetermined count value scope DL～DU, and the charge or discharge ability of this moment is the most applicable setting.Note that when carrying out step 806 and step 810 processing unit 504 can be adjusted charging ability and the discharge capability of electric capacity measuring device 502 simultaneously, or select an adjustment.

Please refer to Fig. 9, Fig. 9 is that electric capacity measuring device 502 is set as and fills first when putting configuration afterwards, a sequential chart of the coherent signal when discharging and recharging program, and processing unit 504 is adjusted the pattern of charging abilities according to flow process 80 as shown in Figure 9.In Fig. 9, to suppose to discharge and recharge control module 514 and have three sections charging ability CC1, CC2, CC3 can select, the charging ability size order is CC1＜CC2＜CC3; Signal waveform corresponding to charging ability CC1, CC2, CC3 represents with long dotted line, solid line, short dash line respectively.Charge with charging ability CC2 when discharging and recharging control module 514, processing unit 504 checks and learns that the count value Dx of reception is greater than the upper limit of preset range simultaneously, be that the dutycycle of signal SB is when excessive, the charging ability that processing unit 504 will discharge and recharge control module 514 comes down to charging ability CC1, reduces and carries out the electric weight that electric charge shifts at every turn.As shown in Figure 9, when charging with charging ability CC1, the voltage V on the testing capacitance 500 _CMIf that climbs is originally so not high, the dutycycle of signal SB diminishes, and cycle detection circuit 520 is correspondingly exported less count value Dx.

Similarly, charge with charging ability CC2 when discharging and recharging control module 514, processing unit 504 checks and learns that the count value Dx of reception is less than the lower limit of preset range simultaneously, be the dutycycle of signal SB when too small, the charging ability that processing unit 504 will discharge and recharge control module 514 increases and is charging ability CC3.At this moment, the dutycycle of signal SB correspondingly becomes greatly, and cycle detection circuit 520 is correspondingly exported larger count value Dx.Processing unit 504 through one to for several times judgement count value Dx and adjust charging ability after, the charging ability that discharges and recharges control module 514 is set in the most applicable state.

Please refer to Figure 10, Figure 10 is that electric capacity measuring device 502 is set as and fills first when putting configuration afterwards, a sequential chart of the coherent signal when discharging and recharging program, and processing unit 504 is adjusted the pattern of discharge capabilities according to flow process 80 as shown in Figure 10.In Figure 10, to suppose to discharge and recharge control module 516 and have three sections discharge capability DC1, DC2, DC3 can select, the discharge capability size order is DC1＞DC2＞DC3; Signal waveform corresponding to discharge capability DC1, DC2, DC3 represents with long dotted line, solid line, short dash line respectively.Discharge with discharge capability DC2 when discharging and recharging control module 516, processing unit 504 checks and learns that count value Dx prescribes a time limit greater than the upper of preset range simultaneously, the discharge capability that processing unit 504 will discharge and recharge control module 516 increases and is discharge capability DC1, to increase discharge capacity, shortens discharge time.As shown in Figure 10, when increasing, discharge capability is discharge capability DC1, the voltage V on the testing capacitance 500 _CMComparatively fast drop to and be lower than voltage V _REF3, the dutycycle of signal SB diminishes, and cycle detection circuit 520 is correspondingly exported less count value Dx.

Similarly, discharge with discharge capability DC2 when discharging and recharging control module 516, processing unit 504 checks and learns that count value Dx is less than the lower limit of preset range simultaneously, the discharge capability that processing unit 504 will discharge and recharge control module 516 comes down to discharge capability DC3, to reduce discharge capacity, increase discharge time, the dutycycle of signal SB correspondingly becomes greatly, and cycle detection circuit 520 is correspondingly exported larger count value Dx.Processing unit 504 is set in the most applicable state with the discharge capability that discharges and recharges control module 516 after adjusting to discharge capability for several times through one.

Fig. 9 and Figure 10 have shown and have filled first in the electric capacity measuring device 502 of putting afterwards configuration that charging ability and discharge capability are corresponding to the relation of the dutycycle of signal SB.When being set as to put first, electric capacity measuring device 502 fills afterwards configuration, processing unit 504 also capable of regulating discharges and recharges the discharge capability of control module 514 and discharges and recharges the charging ability of control module 516, this area tool knows that usually the knowledgeable is when according to aforementioned understanding correlation timing figure, not describing in detail at this.

As from the foregoing, when checking, processing unit 504 learns that the count value Dx that receives is positioned at preset range, expression processing unit 504 will discharge and recharge the charging ability of control module 514 or discharge and recharge the discharge capability of control module 516, be adjusted to and be applicable under the new environment electric capacity condition, avoid because unaccommodated charge or discharge ability causes count value Dx too high or too low, and the judgement of follow-up touch-control action was lost efficacy.

In known contactor control device, when the environment electric capacity of contact panel changes because of external factor, the count value that the electric capacity measuring device produces may be too high or too low, has not been suitable for the judgement of touch event, yet can not changed the charging and discharging capabilities of testing capacitance.In this case, the count value that processing unit obtains can't represent correct testing capacitance amount, and whether the touch action that also just can't judge rightly occurs.In comparison, in contactor control device 50, the count value Dx that produces when electric capacity measuring device 50 is because of environment electric capacitance change when too high or too low, processing unit 504 is according to count value Dx, adjust the charge or discharge ability of 50 pairs of testing capacitances 500 of electric capacity measuring device, charging ability or discharge capability are applicable under the condition of new environment electric capacity.Thus, count value Dx can get back in the predetermined count value scope, and electric capacity measuring device 50 measures the function of testing capacitance amounts and replys, so whether processing unit 504 touch action that can judge rightly occurs.

Please refer to Figure 11, Figure 11 is that electric capacity measuring device 502 is set as to fill first and puts afterwards configuration, the sequential chart of the coherent signal when discharging and recharging program.In Figure 11, with long dotted line, solid line, short dash line represent respectively that corresponding to the signal waveform of testing capacitance amount C1, C2, C3 testing capacitance amount size order is C1＜C2＜C3.According to the V=Q/C principle, suppose that testing capacitance amount originally is C2, the testing capacitance quantitative change the C3 greatly if electric weight that the electric charge that charges shifts is constant, voltage V _CMStep-down; Otherwise, if the electric weight that electric charge shifts is constant the testing capacitance quantitative change little be C1, voltage V _CMImprove.If measure discharge time according to discharging and recharging time τ=R * C principle, when the testing capacitance amount was increased to C3 by C2, increased discharge time, and it is large that the dutycycle of signal SB becomes; Otherwise when the testing capacitance amount was reduced to C1 by C2, shortened discharge time, and the dutycycle of signal SB diminishes.By the 11st figure as can be known, the variation of the dutycycle of signal SB represents the electric capacity of testing capacitance 500.In like manner, if measure different testing capacitance amounts to put first the electric capacity measuring device 502 that fills afterwards configuration, also the dutycycle of signal SB represents to be not repeated herein the electric capacity of testing capacitance 500 as can be known.

Please refer to Figure 12, Figure 12 is the synoptic diagram of the embodiment of the invention one flow process 120.Flow process 120 is used for detecting touch action and whether occurs for the treatment of unit 504.Flow process 120 includes following steps:

Step 1200: beginning.

Step 1202: whether the charging and discharging capabilities that checks electric capacity measuring device 502 is set.If not,

Carry out step 1204; If carry out step 1210.

Step 1204: testing capacitance 500 is discharged and recharged with predetermined charging ability and discharge capability.

Step 1206: carry out a charging and discharging capabilities setting program.

Step 1208: according to the count value that receives at present, reset the basic count value corresponding to the environment electric capacity.

Step 1210: use charging ability and the discharge capability set that testing capacitance 500 is discharged and recharged, and receive the count value that electric capacity measuring device 502 is exported.

Step 1212: check whether basic count value is set.If carry out step 1214; If not, get back to step 1208.

Step 1214: calculate the count value of reception and the variable quantity between the basic count value, and judge whether to occur touch action according to variable quantity.

Step 1216: check whether count value is positioned at preset range.If get back to step 1210; If not, get back to step 1206.

When electric capacity measuring device 502 was connected with testing capacitance 500 first, the charging and discharging capabilities that is applicable to testing capacitance 500 may not yet be set and finish.According to step 1202, processing unit 504 checks first whether the charging and the discharge capability that discharge and recharge control module 514 and 516 are set; If not yet set, processing unit 504 will charge first and discharge capability is set as predetermined value, testing capacitance 500 is discharged and recharged, and carry out a charging and discharging capabilities setting program, be i.e. the flow process 80 of the 8th figure.By flow process 80, charging and discharge capability that processing unit 504 will discharge and recharge control module 514 and 516 are set in the state that measures testing capacitance 500 that is best suited for.Next, according to step 1208, processing unit 504 resets basic count value according to count value Dx.Please note, if previous charging and discharging capabilities setting program is to carry out for the first time, expression electric capacity measuring device 502 is to be connected with testing capacitance 500 first, may not store the basic count value corresponding to testing capacitance 500 in the internal memory 506, therefore, processing unit 504 directly is set as basic count value with count value Dx.

When charging and discharging capabilities setting program first finish and basic count value set finish after, or processing unit 504 checks when having learnt that charging and discharging capabilities has been set according to step 1202, according to step 1210, processing unit 504 receives the count value Dx that electric capacity measuring device 502 is exported.By as can be known aforementioned, electric capacity measuring device 502 is periodically to export count value Dx, and step 1212 and step 1214 are namely carried out in receive count value Dx at every turn.According to step 1212, processing unit 504 checks whether basic count value is set, if basic count value is not set, the count value Dx that processing unit 504 will receive at present is set as basic count value; If basic count value is set, processing unit 504 calculates the count value Dx of reception and the variable quantity between the basic count value, judges whether to occur touch action according to variable quantity.

When judging whether touch action occurs, according to step 1216, processing unit 504 checks whether count value Dx is positioned at preset range, i.e. employed predetermined count value scope DL～DU in the flow process 80.If count value Dx is positioned at preset range, the expression charging and discharging capabilities is applicable to the present testing capacitance that measures 500 is discharged and recharged, can not cause the time of discharging and recharging too short or long and make the misjudgment of touch action, therefore, processing unit 504 control capacitance measuring devices 502 discharge and recharge testing capacitance 500 with identical charging and discharging capabilities, and getting back to step 1210, count pick up value Dx and the touch action of proceeding step 1212 and step 1214 are judged.Relatively, if count value Dx is positioned at outside the preset range, the environment electric capacity of expression contact panel may change because of external factor, uses the resulting count value Dx of original charging and discharging capabilities, can't be used for correctly judging touch action.At this moment, processing unit 504 carry out step 1206, that is carries out flow process 80 described charging and discharging capabilities setting programs, resets the charging and discharging capabilities of electric capacity measuring device 502.

It should be noted that, under the situation that the charging and discharging capabilities setting program carries out the non-first time, when processing unit 504 finishes the charging and discharging capabilities setting program, when wanting to reset basic count value (such as step 1208), the count value Dx that processing unit 504 will receive at present and present basic count value compute weighted, producing new basic count value, rather than the count value that receives directly is set as basic count value.Thus, basic count value is to follow the variation of environment electric capacity and leniently change, and can not make because violent change of temporary transient environment the setting mistake of basic count value.

In brief, according to flow process 120, processing unit 504 not only can carry out the judgement of touch-control action and when environment electric capacity changes, adjustment is to the charging and discharging capabilities of testing capacitance 500, and can be when environment electric capacity changes, upgrade basic count value, make the judgement of touch-control action have the most accurate basic count value to compare according to this.The charging and discharging capabilities of the electric capacity measuring device of known contactor control device can not be adjusted, basic count value corresponding to the environment electric capacity also can't be upgraded, in comparison, according to flow process 80 and flow process 120, the charging and discharging capabilities of the electric capacity measuring device 502 of contactor control device 50 can be adjusted with environmental change, the basis count value is renewable, so the judgement of touch-control action is more accurate, and also can be used for measuring the contact panel of different qualities.

The electric capacity measuring device 502 of Fig. 5 is one embodiment of the invention, and this area tool knows that usually the knowledgeable is when doing according to this different variations and modification.Please refer to Figure 13, examine the synoptic diagram that Figure 13 is the embodiment of the invention one electric capacity measuring device 602.Electric capacity measuring device 602 includes a cycle control circuit 610 and a cycle detection circuit 620.Cycle control circuit 610 includes a voltage generation unit 612, discharges and recharges control module 614,616, an analog to digital converter 618 and interrupteur SW 1～SW3, and cycle detection circuit 620 includes an analog to digital converter 622 and a digital signal processing unit 624.Note that analog to digital converter 622 is a N position analog to digital converter, different from the analog to digital converter 522 among Fig. 5, corresponding unit class seemingly is not repeated herein in other unit and the electric capacity measuring device 502.

Analog to digital converter 622 is coupled to a testing capacitance 600 and digital signal processing unit 624, is used for the voltage V on the testing capacitance 600 _CMBe converted to a N position signal SD, export digital signal processing unit 624 to.The scope of analog to digital converter 622 employed sampling voltages is a reference voltage V _LTo a reference voltage V _UBe similar to reference voltage V in the electric capacity measuring device 502 _REF3Setting means, put afterwards configuration when electric capacity measuring device 602 is set as to fill first, above-mentioned sampling voltage scope V _L～V _UMust be greater than the reference voltage V to testing capacitance 600 precharge _REF1And analog to digital converter 618 is used for and voltage V _CMReference voltage V relatively _REF2When being set as to put first, electric capacity measuring device 602 fills afterwards configuration, sampling voltage scope V _L～V _UMust be less than reference voltage V _REF1And reference voltage V _REF2Digital signal processing unit 624 is converted to a count value Dx with signal SD, exports the back-end processing unit to.

Please refer to Figure 14 and Figure 15, Figure 14 and Figure 15 are respectively that electric capacity measuring device 602 is set as to fill first and puts afterwards configuration and put first under the situation of filling afterwards configuration, and the sequential chart of coherent signal when discharging and recharging program is wherein described signal S1～S3, voltage V _CMAnd signal SD.In expression signal S3 and voltage V _CMThe time, with long dotted line, solid line, short dash line represent respectively that corresponding to the signal waveform of testing capacitance amount C1, C2, C3 testing capacitance amount size order is C1＜C2＜C3.By Figure 14 and Figure 15 as can be known, the testing capacitance scale shows that the dutycycle by signal SD represents, so the processing unit of electric capacity measuring device 602 rear ends can according to count value Dx, be adjusted the charging and discharging capabilities that discharges and recharges control module 614 or 616.

In the electric capacity measuring device 502 of Fig. 5, the charging ability or the discharge capability that discharge and recharge control module 516 are to be adjusted according to count value Dx by the processing unit 504 of rear end.The present invention proposes another embodiment, the charging ability that order is filled first the discharge capability of the electric capacity measuring device of putting afterwards configuration or put first the electric capacity measuring device that fills afterwards configuration is directly according to the voltage on the testing capacitance, Self-adjustment in the electric capacity measuring device need not be by the processing unit of rear end.Please refer to Figure 16, Figure 16 is the synoptic diagram of the embodiment of the invention one electric capacity measuring device 702.Electric capacity measuring device 702 includes a cycle control circuit 710 and a cycle detection circuit 720.Cycle control circuit 710 includes a voltage generation unit 712, discharges and recharges control module 714,716, an analog to digital converter 718 and interrupteur SW 1～SW3.Cycle detection circuit 720 includes an analog to digital converter 722 and a digital signal processing unit 724.

Note that electric capacity measuring device 702 is N position analog to digital converters from the different analog to digital converters 718 that are of electric capacity measuring device 502.Analog to digital converter 718 is coupled to a testing capacitance 700 and discharges and recharges control module 716, is used for the voltage V on the testing capacitance 700 _CMBe converted to a N position signal SD2, export to and discharge and recharge control module 716.The scope of analog to digital converter 718 employed sampling voltages is a reference voltage V _LTo a reference voltage V _UDischarge and recharge control module 716 according to signal SD2, by 2 ^NIn the charging ability of individual different brackets or the discharge capability (deciding on the configuration that discharges and recharges control module 716), select corresponding charging ability or a discharge capability, testing capacitance 700 is discharged and recharged.Compared to Fig. 5, the charging ability or the discharge capability that discharge and recharge control module 716 directly determine according to signal SD2, but not are determined according to the count value that cycle detection circuit 720 produces by the processing unit of rear end.

It is noted that the binding that discharges and recharges between control module 716 and the testing capacitance 700 is still by interrupteur SW 3 controls, but the signal of gauge tap SW3 is to discharge and recharge the signal S3 that control module 716 is exported, but not the signal SD2 that analog to digital converter 718 is exported.The mode that configuration and setting and the adjustment of back-end processing unit discharge and recharge the charging and discharging capabilities of control module 714 that discharges and recharges about electric capacity measuring device 702 please refer to aforementioned electric capacity measuring device 502, is not repeated herein.

The above only is the preferred embodiments of the present invention, and all equalizations of doing according to claim of the present invention change and modify, and all should belong to covering scope of the present invention.

Claims (32)

1. a touch detection method that is used for a contactor control device is characterized in that this contactor control device includes a contact panel, and this touch detection method includes:

Check whether a charging ability and a discharge capability are set, this charging ability and this discharge capability are in order to a testing capacitance in this contact panel is discharged and recharged;

When this charging ability and this discharge capability have been set, this testing capacitance is discharged and recharged, and receive a count value, this count value is corresponding to the electric capacity on this testing capacitance;

Check whether a basic count value is set, the electric capacity of this testing capacitance when this basis count value is not touched corresponding to this contact panel;

When this basis count value has been set, calculate the variable quantity between this count value and this basis count value, to judge according to this variable quantity whether this contact panel is touched;

Check whether this count value is positioned at a preset range; And

When this count value is not in this preset range, carry out a charging and discharging capabilities setting program, to upgrade this charging ability and this discharge capability.

2. touch detection method as claimed in claim 1 is characterized in that this charging and discharging capabilities setting program includes:

Receive this count value;

Check whether this count value is positioned at this preset range, to produce a check result; And

And according to this check result, adjust this charging ability and this discharge capability.

3. touch detection method as claimed in claim 2 is characterized in that the step of adjusting this charging ability and this discharge capability according to this check result includes:

When this check result represents this count value greater than a higher limit of this preset range, downgrade this charging ability.

4. touch detection method as claimed in claim 2 is characterized in that the step of adjusting this charging ability and this discharge capability according to this check result includes:

When this check result represents this count value greater than a higher limit of this preset range, increase this discharge capability.

5. touch detection method as claimed in claim 2 is characterized in that the step of adjusting this charging ability and this discharge capability according to this check result includes:

When this check result represents this count value less than a lower limit of this preset range, increase this charging ability.

6. touch detection method as claimed in claim 2 is characterized in that the step of adjusting this charging ability and this discharge capability according to this check result includes:

When this check result represents this count value less than a lower limit of this preset range, downgrade this discharge capability.

7. touch detection method as claimed in claim 1 is characterized in that this touch detection method also includes:

When upgrading this charging ability and this discharge capability, reset this basis count value according to this count value.

8. touch detection method as claimed in claim 7, it is characterized in that resetting according to this count value the step of this basis count value, be that this count value and this basis count value are computed weighted, produce an operation result, and this operation result is set as this basis count value.

9. touch detection method as claimed in claim 1 is characterized in that this touch detection method also includes:

When this charging ability and this discharge capability are not set, with a predetermined charging ability and a predetermined discharge ability this testing capacitance is discharged and recharged;

Carry out this charging and discharging capabilities setting program; And

This count value that will receive in the time of will carrying out this charging and discharging capabilities setting program is set as this basis count value.

10. contactor control device is characterized in that including:

One contact panel;

One electric capacity measuring device is coupled to this contact panel, is used for a testing capacitance in this contact panel is discharged and recharged, and produces a count value according to the voltage on this testing capacitance, and this count value is corresponding to the electric capacity of this testing capacitance; And

One processing unit, be coupled to this electric capacity measuring device, be used for carrying out a touch detection program, to judge whether this contact panel is touched, in this touch detection program, this processing unit is adjusted a charging ability and the discharge capability of this electric capacity measuring device in order to this testing capacitance is discharged and recharged according to this count value.

11. contactor control device as claimed in claim 10 is characterized in that this touch detection routine package that this processing unit carries out contains:

Check whether this charging ability and this discharge capability are set;

When this charging ability and this discharge capability have been set, control this electric capacity measuring device this testing capacitance is discharged and recharged, and receive this count value;

Check whether a basic count value is set, the electric capacity of this testing capacitance when this basis count value is not touched corresponding to this contact panel;

When this basis count value has been set, calculate the variable quantity between this count value and this basis count value, to judge according to this variable quantity whether this contact panel is touched;

Check whether this count value is positioned at a preset range; And

When this count value is not in this preset range, carry out a charging and discharging capabilities setting program, with this charging ability and this discharge capability that upgrades this electric capacity measuring device.

12. contactor control device as claimed in claim 11 is characterized in that this charging and discharging capabilities setting program that this processing unit carries out includes:

Receive this count value;

Check whether this count value is positioned at this preset range, to produce a check result; And

And according to this check result, adjust this charging ability and this discharge capability of this electric capacity measuring device.

13. contactor control device as claimed in claim 12 is characterized in that this processing unit when this check result represents this count value greater than a higher limit of this preset range, downgrades this charging ability.

14. contactor control device as claimed in claim 12 is characterized in that this processing unit when this check result represents this count value greater than a higher limit of this preset range, increases this discharge capability.

15. contactor control device as claimed in claim 12 is characterized in that this processing unit when this check result represents this count value less than a lower limit of this preset range, increases this charging ability.

16. contactor control device as claimed in claim 12 is characterized in that this processing unit when this check result represents this count value less than a lower limit of this preset range, downgrades this discharge capability.

17. contactor control device as claimed in claim 11 is characterized in that this processing unit when upgrading this charging ability and this discharge capability, resets this basis count value according to this count value simultaneously.

18. contactor control device as claimed in claim 17 is characterized in that this processing unit computes weighted this count value and this basis count value, produces an operation result, and this operation result is set as this basis count value.

19. contactor control device as claimed in claim 11 is characterized in that this processing unit when this charging ability and this discharge capability are not set, carries out following steps:

With a predetermined charging ability and a predetermined discharge ability this testing capacitance is discharged and recharged;

Carry out this charging and discharging capabilities setting program; And

This count value that will receive in the time of will carrying out this charging and discharging capabilities setting program is set as this basis count value.

20. contactor control device as claimed in claim 11 is characterized in that this electric capacity measuring device includes:

One charging control unit is used for to this testing capacitance charging;

One control of discharge unit is used for to this testing capacitance discharge;

One first switch is coupled to this testing capacitance and this charging control unit, is used for controlling the binding between this charging control unit and this testing capacitance according to one first switching signal;

One second switch is coupled to this testing capacitance and this control of discharge unit, is used for controlling the binding between this control of discharge unit and this testing capacitance according to a second switch signal;

One first analog to digital converter is coupled to this testing capacitance, and being used for the voltage transitions on this testing capacitance is a first signal; And

One cycle detection circuit is coupled to this testing capacitance, and being used for the voltage transitions on this testing capacitance is a count value, exports this processing unit to, and this count value represents the electric capacity of this testing capacitance.

21. contactor control device as claimed in claim 20 is characterized in that this electric capacity measuring device includes in addition:

One voltage generation unit is coupled to this first analog to digital converter and this cycle detection circuit, is used for producing a plurality of reference voltages, for this first analog to digital converter and this cycle detection circuit; And

One the 3rd switch is coupled to this testing capacitance and this voltage generation unit, is used for controlling the binding between this voltage generation unit and this testing capacitance according to one the 3rd switching signal.

22. contactor control device as claimed in claim 21 is characterized in that this voltage generation unit is used for before this charging control unit and this control of discharge unit discharge and recharge this testing capacitance this testing capacitance being precharged to a predetermined voltage in addition.

23. contactor control device as claimed in claim 22 is characterized in that this predetermined voltage is similar to the employed reference voltage of this first analog to digital converter.

24. contactor control device as claimed in claim 20 is characterized in that this first analog to digital converter is one 1 analog to digital converters, other is coupled to this second switch, and this first signal that this first analog to digital converter produces is this second switch signal.

25. contactor control device as claimed in claim 20 is characterized in that this first analog to digital converter is one 1 analog to digital converters, other is coupled to this first switch, and this first signal that this first analog to digital converter produces is this first switching signal.

26. contactor control device as claimed in claim 20, it is characterized in that this first analog to digital converter is a multidigit analog to digital converter, other is coupled to this control of discharge unit, and this control of discharge unit is according to this first signal, by selecting a corresponding discharge capability in a plurality of discharge capabilities, in order to this testing capacitance is discharged.

27. contactor control device as claimed in claim 26 is characterized in that this first switching signal is that this processing unit produces, and this second switch signal is that this control of discharge unit produces.

28. contactor control device as claimed in claim 20, it is characterized in that this first analog to digital converter is a multidigit analog to digital converter, other is coupled to this charging control unit, and this charging control unit is according to this first signal, by selecting a corresponding charging ability in a plurality of charging abilities, in order to this testing capacitance is charged.

29. contactor control device as claimed in claim 28 it is characterized in that this first switching signal is that this charging control unit produces, and this second switch signal is that this processing unit produces.

30. contactor control device as claimed in claim 20 is characterized in that this cycle detection circuit includes:

The second analog to digital converter is coupled to this testing capacitance, and being used for the voltage transitions on this testing capacitance is a secondary signal; And

One digital signal processing unit is coupled to this second analog to digital converter, is used for this secondary signal is converted to this count value.

31. contactor control device as claimed in claim 30 is characterized in that this second analog to digital converter is one 1 analog to digital converters.

32. contactor control device as claimed in claim 30 is characterized in that this second analog to digital converter is a multidigit analog to digital converter.

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