DE2343193A1 - CIRCUIT FOR A SWITCH ACTUATED BY THE TOUCH OF A HUMAN PERSON - Google Patents

Description

DR. MÜLLER-BORE DIPL-PHYS. DR. MANITZ DIPL-CHEM. DR. DEUFEL

DIPL.-lNG. FINSTERWALD dipl.-ing. QRAMKOW

PATENT LAWYERS

Munich, August 27, 1973

Hl / Sv - M 2261

Magic Dot, Inc.

40 Washington Ave., S.,

Minneapolis, Minnesota 55401, USA

Circuit for a switch that can be actuated by touching a human person

The invention relates to an electronic circuit and, more particularly, relates to one which is actuatable by touch electronic switch that has no moving parts and can be actuated by the capacity of an operator that establishes a connection between a provides a vibrating input to the electronic components assigned to the switch and earth or earth ground,

So far, there are different designs of by the capacity brought about by the touch of a human person becomes, actuatable. Switches or versions of part of the electronic circuit of this switch has been proposed. These proposals have different

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Dr. Müllar-Bore Or. Manitz · Dr. Deufel Dipl.-Ing. Finsterwald Dipl.-Ing. Qrfcnkow Braunschweig. Am BOrgerpark · · Munich TZ, Robert-Koeh-StraBa 1 7Stuttgart-BadCannatatt. Marktatra 3 Telephone (0531) 73M7 Telephone (0 * 11) 293 * 45. Tetex 5-22050 mbpat Telephone (0711) 9 * 73 « Bank: Zentralfcaeae Bayer. Volfcabankan, Munich, account no. 9822 Postal check: Manchen 954M

Disadvantages such as high input currents, which can be dangerous for human beings, low noise suppression or immunity to noise, high cost, large size, difficult to manufacture, unreliable actuation to the touch or approach, prior actuation before touch or approach and a generally questionable or minor one Performance reliability.

The aim of the invention is to provide a touch-operated electronic switch in which the switch associated electronic components can also be used in embodiments that require a connection to earth, who works with input currents below a for human beings are of dangerous value, cheap to manufacture, small in size, reliable is in operation, has a high level of noise immunity and is easy to manufacture.

According to the invention, an electronic switch is provided with a series connection of a touch panel, a first amplifier, which is separated from the earth or earth ground, a high impedance and a second amplifier, the are electrically connected to the earth ground. A storage device which, in the preferred embodiment, is available as a The capacitor shown is connected between the junction of the first amplifier with the high impedance and extends to the reference point of the circuit. The arrangement of the circuit is such that one input to the first amplifier is provided by the touch of the touch panel by the operator who Input in the first amplifier is amplified and rectified, the output of the first amplifier the capacitor charges and the charge on the capacitor is passed through the high impedance to the second amplifier, where it has the output the second amplifier between a first state, the

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approximates an electrical short circuit and a second state approximating an electrical circuit interruption, controls.

The invention thus relates to an electronic switch that has no moving parts and by virtue of the capacitance an operator is operable, the connection between the ground and an input to the Provides switch associated electronic elements. The electronic switch comprises in the preferred embodiment a plate which can be touched by a human operator and which is connected to a first amplifier and in particular to the input is electrically connected, which is separated from the earth ground and thus oscillates with respect to this. The exit of the first amplifier is simultaneously with one end of a storage capacitor, the other end with the Ground ground is connected, and connected to one end of a high impedance. A second amplifier is with the other Connected to the end of the high impedance to provide a switched output that has a first state that is an electrical Short circuit approximates, and a second state, which provides an electrical circuit interruption, approximates.

The invention is illustrated below with reference to the drawing, for example described; in this shows:

Fig. 1 is a schematic block diagram of the electronic elements an electronic switch according to the invention,

2 shows a touch panel for use in connection with the electronic switch according to the invention,

Fig. Ο an alternative embodiment of the power source that can be used in the circuit shown in Fig. 1, and

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4 is a more detailed diagram of the electronic elements; in connection with the switch according to the invention can be used with a power source supplied by an AC voltage input, wherein Also arrangements and configurations are shown which increase the reliability and enhancement the noise immunity or noise suppression of the switch.

According to Fig. 1, an electronic circuit 10 of a switch comprises an amplifier 12 with a signal input 14, a signal output 16 and an alternating power input 18.

The electronic circuit further comprises a second amplifier 30 with a signal input 32, a signal output 34, a power input 36 and a reference or circuit-earth or ground input 38. The power input 36 is through a conductor 42 is connected to a power terminal or mains terminal 40 and the circuit ground input 38 is through a conductor 44 connected to the circular mass 26.

The output 16 of the Veuäbärkers 12 is connected to the anode of a diode 45 connected, the cathode of which is connected to a connection point 46. The connection point 46 is connected to the input 32 of the second amplifier 30 by a high impedance or resistance value, connected through a resistor 48, for example. The connection point 46 is also through a memory, Integrating or smoothing element that acts as a capacitor 50 is shown, connected to the circular ground 26.

The input 14 of the amplifier 12 of the circuit 10 is shown by a connecting line 54 with a circuit input terminal 52 is connected. The circuit input terminal 52 is, as shown in Fig. 2, further by a conductor 58 with a contact

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plate or touch plate 56 connected. The touch plate 56 is one or another metal plate conductive material, which is an actual plate, a patch of conductive or semiconductive material or like that can be.

The signal output 34 of the amplifier 30 is through a Conductor 60 connected to output terminal 59 of circuit 10. The electrical impedance or the electrical Resistance between the output terminal 59 and the circular ground 26 is then in a manner explained below provided so that she or he is an electrical short circuit in a first state and in a second state approximates an open electrical circuit, the state depending on whether the finger of an operator the Bertihrungsplatte 56 touches or not touched.

A power supply for circuit 10 is shown generally at 61. The power supply or power source shown in Fig. 1 comprises a transformer 62 with a primary winding 64. The primary winding 64 includes transformer primary winding terminals 66 and 68, the with an AC power source labeled "Input Power" are shown connected. The transformer 62 further includes a secondary winding 72, the secondary winding terminals 74 and 76 has. Terminals 68 and 76 are shown connected to ground 70.

The secondary terminal 74 is connected to the AC power input 18 of the amplifier 12 through a conductor 24 and through a Diode 78 connected to a power source terminal 80 · The Another power source terminal 82 is to the circular ground 26 and thus connected to ground ground 70 · A filter capacitor 84 is connected between power source terminals 80 and 82 in a conventional manner.

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The power source terminal 80 is still with the circuit 10 and in particular with the power supply terminal 40 of the second amplifier 30 are connected by a conductor 88.

3 shows one of many alternative embodiments of the power source 61 in which a series connection of resistors 101 and 10p is connected between a terminal 104 and a further terminal 106, the terminals 104 and 106 providing an alternating frequency power source. Terminal 106 is also connected to ground 70. The resistors 101 and 103 are connected to one another at a connection point 107 which is connected directly to the terminal 74. Thus, the power source shown in Fig. 3 operates in the manner of a voltage divider in parallel with the AC voltage source. The power source 61 shown in Fig. 3 can be used as a replacement for the power source 61 shown in Fig. 1 or 4, or the voltage divider network shown in Fig. J alone can be used in conjunction with the power source 61 shown in Fig. 1 or 4, so that the voltage divider network provides the AC power to terminal 74 and DC power is supplied by the power source 61 shown in Fig. 1 or 4 or its equivalent.

The embodiment shown in Fig. 4 is similar to that embodiment shown in Fig. 1, wherein the electronic components are added that in the dashed Lines are bordered by the amplifiers 12 and 30 and the Designate power source 61.

The amplifier 12 includes a PNP transistor 154, whose Emitter with the power input 18 of the amplifier 12, the collector with the signal output 16 of the amplifier 12 and its base with the signal input 14 of the amplifier 12

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connected is. A resistor 156 is between the AC power input 18 and the signal input 14 · switched in order to prevent the leakage current of the transistor 154- from the Make transistor 154- conductive.

According to Fig. 4- the connection includes line 54- a resistor 160 with a high resistance value, which is used to prevent the person touching the touch plate 56 from receiving the alternating voltage of the circuit 10 and to protect the input of the amplifier 12 against damage by overcurrents to protect by the touch plate 56, for example by a direct connection to a high voltage source or static electricity induced by the operator.

The amplifier 30 comprises a Darlington arrangement of HPN transistors 162 and 164-, which with their common collectors with the power input 36 of the amplifier 30 through a current limiting resistor 166 are connected. The base of the transistor 162 is connected to the signal input 32 of the Amplifier 30 connected, while the emitter of transistor 164- to the base of another NPN transistor 168 and the Reference input 38 of amplifier 30 through a series connection a resistor 170, a diode 172, a connection point 174 and a resistor 176 is connected.

The collector of the transistor 168 is also connected to the power output 40 through a further current limiting resistor 180, connection point 36 and conductor 4-2.

The connection point 174- is also connected to the emitter of the Transistor 168 and the base of transistor 178 connected, its collector to the signal output 59 and its emitter is connected to the reference input 38.

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The series connection of resistor 170, diode 172 and resistor 176 provides a bias for the Transistors 168 and 178 in amplifier 30. In particular the series connection acts as the emitter resistor of the Darlington pair 162 and 164.

Furthermore, the resistor 170, the diode 172 and the resistor 176 help to prevent leakage currents from the Making transistor 178 conductive.

The operation will now be described. Basically the electrical switch according to the invention works in the following way: The electrical circuit 10 is for example connected through transformer 62 to an AC frequency power source which causes the input of amplifier 62 oscillates with respect to ground ground at the frequency of the power input. The capacity of the Pingers of an operator then sees a reference value between the amplifier when touching the touch panel 56 12 of the circuit 10 and the earth ground in front of the amplifier 12 as an alternating frequency power input with an amplitude is seen which is substantially equal to the amplitude with which the input of the amplifier 12 oscillates with respect to the earth ground. When this signal indicates an operator touching the touch panel 56, the circuit 10 provides a switched output or a switched output signal that is a transition from a circuit break to a closed circuit or, if desired, a transition from a closed one Circle can be a broken circle. I.e. the output of circuit 10 shows the effect of an electrical switch .

Since the emitter of transistor 154 is connected to terminal 74 of the Secondary winding 72 of transformer 62 is connected, the emitter swings in in a positive and negative manner

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with respect to the earth ground 70 in .Synchronization with, however, as will be explained below, in phase opposition to the power input frequency. Likewise oscillate due to the connection of the resistor 156 between the emitter and the base of the transistor the emitter and the base essentially coincide.

Due to the oscillation of the emitter and the base of transistor 154- with respect to ground ground 70 »of Seeing the frame of reference of the circular input 52 and the earth ground 70, an oscillating or oscillating voltage between the earth ground 70 and the circle input 52. As a result, it has been found to see the touch of the plate 56 by an operator a capacitive coupling between the contact plate 56 and thus the circular input 52 and the Ground mass 70, which causes the vibrating Signal is applied to the circuit input 52.

During half the period of power input, the is positive with respect to ground ground 70, assuming that an operator's finger is applied to input 52, the emitter-base connection of transistor 154- forward biased, to charge the capacitance presented by the operator between input 52 and the earth ground will. That is, the operator presents a capacitance at input 52, which thus establishes a connection between the previously separated input 52 and the earth ground, thus a current flows from the power source terminal 74 -through the emitter-base connection of transistor 154 » the resistor 160, the input 52 and the capacitance of the Operator to earth ground, thus increasing the operator's capacity during the positive half-cycle of the Load power input.

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As a result, charges due to this emitter-base current and the gain inherent in a transistor the collector current of transistor 154 drives capacitor 50.

During the half-cycle of the power input, which is negative with respect to earth ground, if an operator's finger is still placed on input 52, the emitter-base junction of transistor 154 is reverse-biased and the base-collector ^Getting Connected of transistor 154- is biased in the forward direction.

Since the impedance path from capacitor 50 is through the in Forward biased collector-base connection and resistor 156 to terminal 74 © in path with relative is high impedance, the capacitor 50 does not discharge appreciably due to this effect.

However, the capacitor 50 can be used as the emitter-collector connection of a transistor does not have a significant reverse bias breakdown voltage through the collector and emitter connections of transistor 154 discharged in a reverse bias manner, except when the diode 45 is inserted to the capacitor 50 during this time to separate and to prevent unloading.

The placement of diode 4-5 is another feature of the invention in that it has normally been considered possible to place diode 45 between junction 18 and junction 74 of amplifier 12. When the diode 45 is arranged d ^{e <i o} ch so, it prevents the discharge of the capacitance of the operator through the resistors 160 and 156 to the terminal 74- and does not allow the circuit according to the invention,

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to work, as can be seen from the discussion of the effects below, as far as the operator's capacity is concerned.

Another feature of the invention has been discussed above in that the operator's capacity without locking the voltage of capacitor 50 or without artificially discharging this voltage Must be able to during the negative half cycle of the power in the preferred circuit shown to discharge, so that during the next positive half-cycle the capacity of the operator again charged and a base current can be supplied, which in turn is amplified to provide the charging current for the Provide capacitor 50. Thus, the discharge path must for the operator's capacitance through resistor 160, resistor 156 and the remainder of the power source 61 can be provided so that the capacity of the operator can be discharged.

If a person's worst-case capacity is assumed to be 10 picofarads or less, one is Power frequency of 60 Hz makes the capacitive reactance approximately 266 megohms. Assuming that the Signal input 14 to amplifier 12 with respect to earth ground 70 with a voltage of approximately 10 volts oscillates, there is a current input to the amplifier 12 in FIG. 1 on the order of at most 20 nanoamps. A strengthening of currents in this The order of magnitude is contrary to the way of thinking of the average person skilled in the art, who consider the currents in this area to be considered in the middle of the range of noise currents and thus lying below the current threshold at which a Electricity can be usefully amplified.

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This extremely small input current of 20 nanoamps is then amplified and rectified by the amplifier 12, which is designed with a gain factor of at least 10 and used to charge the capacitor 50 connected to the output of the amplifier 12.

The capacitor 50 is, for example, for various Storage devices shown, which are possible according to the teaching of the invention, and has a size or dimensioning that can be easily mass-produced in a small size. That is, the one shown in FIG Embodiment, the capacitor 50 is on the order of 1000 picofarads, which is achievable by integration or thick film technology, so that it is in sizes

2 on the order of a few thousands of an inch square.

The capacitor 50, once charged, approaches one Power source for the amplifier 30 with high gain by the high impedance path provided by the large value resistor 48. In the case of the in Fig. 1 illustrated preferred embodiment of the switch the value of the resistor 48 is on the order of 10 megohms and the current gain of the amplifier 30 on the order of 10 or 10 '. Resistance 48 may also have a voltage controlled resistance value, for example a field effect transistor or can be in the input impedance of amplifier 30, be included, for example, as a first stage of a field effect transistor.

The high resistance of resistor 48 is used together with sufficient gain in the amplifiers 12 and 30 to ensure that the capacitor 50

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is not discharged in the manner that would be sufficient to cause a hum at the switch output 59 to appear. I.e. in connection with the parameters given above, the operator puts the finger on the touch panel 56 rapidly charges the capacitor 50 with the effect of changing the state of the amplifier 30 allows. If the gain of amplifier 12 is insufficient, capacitor 50 in one charged state, or if the resistance of resistor 48 with respect to the power frequency is not is sufficiently large or if the gain of the amplifier 30 is not sufficiently high, the output impedance at output 59 deviate from the desired circuit interruption or circuit closure to an intermediate value that is not acceptable. That is, assuming that the operator's finger touching the touch panel 56 the output impedance at the output terminal 59 leads to a short circuit, i.e. the transistor 178 in Ex.4 leads to the saturated state, an insufficient gain of the amplifier 12 or 30 or an insufficient Impedance of resistor 48 allow the impedance from output terminal 59 to circuit ground 26 of increase essentially 0 ohms, i.e. transistor 178 Put them in a conductive but unsaturated state and create an impedance that must be taken into account.

Now that the basic operation of the invention electronic switch has been explained, the various parameters for a correct operation to be selected. In the preferred embodiment, the first parameter selected is the value of the memory device 50, in this case the capacity. As stated above, the value of the capacitance is chosen so that simple manufacture in mass production is possible is.

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Next, the operating supply voltages, i.e. the voltage E between the supply terminals 80 and 82 elected.

The output current requirements for the switch are then chosen. I.e. the current at the output terminal 59 flow and is thus to be switched by the electronic switch according to the invention »must in specific areas.

Then the gain factor for the amplifier is calculated by dividing the output current with the period of the AC frequency power multiplied and by the product of the supply voltage multiplied by the value of the capacitor 50 is divided. I.e. the equation can be set up in the following way:

Gain factor (amplifier 30) ■

7 2 Gain factors between 10 'and 10 have been used for T equal to 20 milliseconds, I equal to 150 milliamps, E equal to 5 volts and C _n -Q equal to 1000 picofarads.

Next, the resistance value of the resistor is calculated by dividing the time period of the AC frequency power is divided by the value of capacitor 50. This value prevents assuming a sufficient one Gain in an amplifier 12, the complete discharge of the capacitor 50.

The gain of amplifier 12 is then chosen to ensure that the input is 20 nanoamps the capacitor 50 in the period of the AC frequency power loads so as to provide for a quick turn-on of the switch. The required for the amplifier 12

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7343193

The current output is approximately the product of the supply voltage multiplied by the value of the Capacitor 50 and divided by the period of the alternating frequency power. That means the equation is:

Io (amplifier 12) - ^E ° 50

Gain factors between 10 and 100 have been used for E equal to 5 volts, C ₅₀ equal to 1000 picofarads and T equal to 20 milliseconds.

It has been found that the circuit when the gain of amplifier 12 decreases and the gain of the amplifier 30 is correspondingly enlarged, works in a satisfactory manner. It has also been found that as the gain of amplifier 12 increases and so does the gain of the amplifier 30 is correspondingly degraded, the circuit is more satisfactory Way works. Thus, it has been found that the gains of amplifier 12 are between

10 and 10 * gain factors of amplifier 30 between

7 2
see 10 'and 10 correspond.

Another feature of the invention will now be explained. The phase alignment between the AC frequency power input and the vibration of the circular mass 26 must be considered under the following conditions. When an induced Voltage at the operator is assumed from the source of AC power, then when the induced voltage approximately in the .Amplitude is equal to the oscillation amplitude of the input 52, no Signal between the circuit input 52 and the earth ground 70 induced. I.e. the operator swings simultaneously with the amplifier 12 and there is no input signal

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73A3193

delivered. This apparent disadvantage can be used to advantage, as shown in FIG. Of the Transformer 62 is designed so that the alternating frequency voltage appearing between the secondary terminals 74 and 76 phase shifted by 180 ° with respect to the alternating frequency voltage which is applied between the primary terminals 66 and 68 is pending. This is from the "point convention" that has been applied to transformer 62, too see. Thus, due to this technique, the vibrations of the amplifier 12 with respect to the earth ground 70 be provided so that the amplifier 12 with respect to the earth ground at the frequency of the AC power oscillates in phase opposition to the oscillation of the alternating frequency power source to be more reliable Provide switching by changing the signal input amplitude induced at terminal 52 assuming the same Tension on the operator is effectively doubled.

It has also been found that by including resistor 51 in parallel with capacitor 50, discharging the voltage across the capacitor 50 ihkL thus the Turn-off time of the circuit can be greatly improved. The resistor 51 has a resistance value in Magnitude of 50 megohms and thus discharges the Capacitor 50 is not essential in the active operation of circuit 10.

Furthermore, it was found that by including the resistor 51, fewer problems from transient oscillations or Transients, heat generation and transistor leakage currents occur and a generally increased noise suppression or noise immunity is achieved.

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" ¹⁷ " 7343193

Thus, an electronic switch that can be actuated by touch is advantageously provided, which switches into other Mass production techniques can be easily integrated or adapted to the extent that it does not require large capacitors, Has coils or other parts that prevent such mass production. In addition, the invention requires Switch no standby power as with other types of touch-operated switches.

- patent claims -

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Claims (3)

" ¹⁸ " 7343193 Claims Circuit for a switch which can be actuated by touching a human person, characterized by means of providing AC power to the circuit having a first output, which provides a reference value coupled to the ground ground, and having a second output which is a AC voltage source is provided by a first amplifying device having an input device which receives a signal to be amplified, and an output device, by a second amplifying device an input device which receives a signal to be amplified, and an output device which receives a switched Provides output, the switched output having a first state approximating an electrical short circuit, and a second state, which approximates an electrical circuit interruption, by a memory device, by a contact plate separated from the earth ground, by a first device, the one electrical connection between the first amplifying device and the second output of the device for Provision of power to the circuit is provided by a second device that provides an electrical connection provides between the output device of the first amplification device and the storage device, by a third device which provides an electrical connection between the storage device and the input the second reinforcement means and a fourth means providing an electrical connection between the input device of the first amplification device and the touch panel so that the human person's capacitance provides a ground reference to the first amplification means and thereby 4098 11/1089 ^19th 7343193 the output of the second amplification device to a
Change between its first and second state is caused. 2. Circuit according to claim 1, characterized in that the memory device comprises a capacitor. 3. A circuit according to claim 2, characterized in that the memory device has a resistor
high resistance in parallel with the capacitor. 409811/1089