KR101900293B1 - Multiple input device capable of detecting electrostatic touch and induced electromagnetic field - Google Patents

Abstract

A multiple input device for sensing a capacitance type touch input and an induction field type input is disclosed. A multi-input device for sensing a capacitance type touch input and an induction electromagnetic type input according to an exemplary embodiment of the present invention includes a capacitance type sensing unit having a plurality of patterns for sensing touch input of a capacitive type; An inductive electromagnetic field type sensing unit that shares at least a portion of the plurality of patterns and senses an input of an induction electromagnetic field type; A capacitive type control unit for controlling the capacitive type touch input by the capacitive type sensing unit; An induction electromagnetic field type control unit for controlling an induction electromagnetic field type input by the induction electromagnetic field type sensing unit; And a main control unit, connected to at least one of the capacitive type control unit and the induction electromagnetic type type control unit, for performing control on processing of capacitive type touch input or induction electromagnetic type input, wherein the capacitive type control Unit and the induction electromagnetic field type control unit are used to select either a capacitive sensing mode for sensing a capacitive type touch input or an induction electromagnetic sensing mode for sensing an induction electromagnetic field type input Communication.

Description

[0001] MULTIPLE INPUT DEVICE CAPABLE OF DETECTING ELECTROSTATIC TOUCH AND INDUCED ELECTROMAGNET FIELD [0002]

The present invention relates to a multi-input device for sensing a capacitive type touch input and an induction electromagnetic type input, and more particularly, The present invention relates to a capacitive type touch input and a multiple input device for sensing an induction electromagnetic field type input that can prevent mutual interference when a pattern occupation occurs in a sensing mode and an induction electromagnetic field type sensing mode.

Generally, a touch panel is widely used as an input device of various electronic equipments. The touch panel is mainly used together with a video display device such as a flat panel display, and can be operated by touching a specific point of the touch panel.

In recent years, an input device capable of detecting both the touch of a finger of a human body and the touch by an electronic pen, in particular, an input device capable of detecting both input by a capacitance type and input by an electronic pen that emits an induction electromagnetic field Is being developed.

In the capacitive touch panel, a transparent electrode pattern is formed of a transparent conductive material such as indium tin oxide (ITO) on a capacitive touch sensor substrate used for a capacitive touch, and a transparent electrode pattern And the flexible circuit board is electrically connected.

The method of recognizing the electronic pen by the emission of the induction electromagnetic field can be variously arranged such as the case where the battery is built in the electronic pen or the case where the battery is not built in. However, if the battery is not built in, Energy is transmitted by resonance from an input device body to which a coil is connected to an electronic pen in which a capacitor and a coil are also connected to each other. Then, when the connection to the input device body is cut off, Energy is transferred to the input device body.

Here, it is possible to detect the position of the electronic pen by sensing the energy transmitted from the electronic pen to the input device body. In this manner, both the touch input by the finger and the input by the electronic pen can be detected .

Meanwhile, in order to detect both the touch of the human finger and the touch of the electronic pen, each of the detection sensors capable of sensing the touch of the human's finger and the touch of the electronic pen may be used individually, A touch sensor and a sensing sensor for sensing a touch by the electronic pen may be commonly used.

However, when at least a part of the sensing sensors for sensing the touch of the human finger and the touch of the electronic pen are commonly used, that is, sharing at least a part of the sensing sensor for each input, Is an important issue. In this case, there is a problem that interference due to the occupation of the sensing sensor may occur in each mode.

Korea Registered Patent Registration No: 10-0910348 (Date of Notification: 2009.08.04)

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a method and apparatus for controlling a coplanar waveguide in which a capacitive type control unit and an induction electromagnetic type control unit communicate with each other, And thus it is possible to provide a capacitive type touch input capable of smoothly processing both the capacitive touch input and the induction electromagnetic type input and a multiple input device for sensing the induction electromagnetic input type .

According to an aspect of the present invention, there is provided a capacitive sensing unit including a plurality of patterns for sensing touch input of a capacitive type; An inductive electromagnetic field type sensing unit that shares at least a portion of the plurality of patterns and senses an input of an induction electromagnetic field type; A capacitive type control unit for controlling a capacitive type touch input by the capacitive type sensing unit; An induction electromagnetic field type control unit for controlling an induction electromagnetic field type input by the induction electromagnetic field type sensing unit; And a main control unit connected to at least one of the capacitance type control unit and the induction electromagnetic field type control unit and performing control on the processing of the input of the capacitive type or the input of the induction electromagnetic field type, Wherein the capacitance type control unit and the induction electromagnetic field type control unit are connected to each other by a capacitance type sensing mode for sensing the capacitive type touch input and an induction electromagnetic type sensing mode for sensing the induction electromagnetic type input, And a plurality of input devices for sensing the capacitive type touch input and the induction electromagnetic type input may be provided.

At least one of the capacitance type control unit and the induction electromagnetic field type control unit may be provided to control the selection of the sensing mode of the capacitive type and the sensing mode of the induction electromagnetic field type.

And the capacitance type control unit may be provided to control the selection of the sensing mode of the capacitance type and the sensing mode of the induction electromagnetic field type.

The capacitance type control unit may be configured to transmit a mode selection signal to the induction electromagnetic field type control unit to inform a selected mode of the capacitance sensing mode and the induction electromagnetic field sensing mode.

The mode selection signal may be a signal based on the sensing mode of the capacitance type and the sensing mode per unit time of the induction electromagnetic field type.

In addition, the mode selection signal may be provided as a pattern occupancy time notification signal indicating a time limit for occupying the pattern in the selected mode.

And a time allocated for occupying the pattern in the sensing mode of the capacitive type and a time allocated for occupying the pattern in the sensing mode of the induction electromagnetic field type are preset in accordance with the unit time, The signal may be provided as a preset assignment time notification signal that indicates the time allocated to the pattern occupation in the selected mode.

The mode selection signal may be set such that the occupancy rate per unit time of the sensing mode of the detected input may be set higher when any one of the input of the capacitive type and the input of the induction electromagnetic field type is detected .

The induction electromagnetic field type control unit may be configured to transmit a signal indicating that the electronic pen input is detected to the capacitance type control unit when the electronic pen input signal corresponding to the input of the induction electromagnetic field type is detected.

The capacitance type sensing unit and the induction electromagnetic field sensing unit may include a plurality of first patterns formed in a first direction within a predetermined sensing area; A plurality of second patterns formed to intersect the plurality of first patterns and formed in a second direction in the predetermined sensing area; And a ground loop surrounding at least a portion of the sensing area, wherein the plurality of first patterns and the plurality of second patterns are switchably connected to the capacitive type control unit and the inductive electromagnetic type type control unit, respectively, And may be arranged to commonly use the plurality of first patterns and the plurality of second patterns in the touch input of the capacitive type and the input of the induction electromagnetic field type.

The input of the induction electromagnetic field type may further include an electromagnetic pen, and may further include a coil-shaped power coil surrounding at least a part of the sensing area to emit an induction electromagnetic field with respect to the resonant circuit of the electronic pen.

In the case of the sensing mode of the capacitive type sensing touch of the capacitive type, the capacitive type control unit or the induction electromagnetic type type control unit may open one side of the plurality of first patterns, Connecting one side of the pattern to the other side of each of the plurality of first patterns, opening one side of the plurality of second patterns, applying a voltage through the plurality of first patterns, The touch position of the capacitive type may be determined by detecting a change in the voltage appearing in the plurality of second patterns by an applied voltage.

In the case of an induction electromagnetic field sensing mode for sensing the input of the induction electromagnetic field type, one side of the plurality of first patterns and one side of the plurality of second patterns are connected to the ground loop, The output position of the induction electromagnetic field based on the difference between the voltage output from the first pattern of the first pattern and the voltage of the ground loop and the difference between the voltage output from the plurality of second patterns and the voltage of the ground loop by the induction electromagnetic field May be provided.

The capacitance type sensing unit and the induction electromagnetic field sensing unit may include a plurality of first patterns formed in a first direction within a predetermined sensing area; A plurality of second patterns formed to intersect the plurality of first patterns and formed in a second direction in the predetermined sensing area; A plurality of third patterns arranged in a second direction in the predetermined sensing area, the third patterns being arranged in proximity to the plurality of second patterns to cross the plurality of first patterns; And a ground loop surrounding at least a part of the sensing area, wherein the plurality of first patterns are switchably connected to the capacitive type control unit and the induction electromagnetic type type control unit, respectively, 2 pattern is switchably connected to the capacitive type control unit and one end of the plurality of third patterns is connected to the ground loop and the other end of the third pattern is switchably connected to the induction electromagnetic type control unit.

The electrostatic capacity type sensing unit and the induction electromagnetic field sensing unit may include a plurality of first patterns formed in a first direction within a predetermined sensing area; A plurality of second patterns formed to intersect the plurality of first patterns and formed in a second direction in the predetermined sensing area; A plurality of third patterns arranged in a second direction in the predetermined sensing area, the third patterns being arranged in proximity to the plurality of second patterns to cross the plurality of first patterns; And a ground loop enclosing at least a portion of the sensing area, wherein the plurality of first patterns are switchably connected to the capacitive type control unit, and the plurality of second patterns are capacitive type control Unit and the induction electromagnetic field type control unit, and the plurality of third patterns may be connected to the ground loop on one side and the induction electromagnetic field type control unit on the other side so as to be switchable.

The input of the induction electromagnetic field type may further include an electromagnetic pen, and may further include a coil-shaped power coil surrounding at least a part of the sensing area to emit an induction electromagnetic field with respect to the resonant circuit of the electronic pen.

In the case of a sensing mode of a capacitive type that senses a touch input of a capacitive type, the capacitive type control unit or the induction electromagnetic type type control unit may open one side of the plurality of first patterns or a plurality of first patterns And a second voltage is applied to the second pattern by applying a voltage across the plurality of first patterns after connecting one side of each of the plurality of first patterns to the other side of each of the plurality of first patterns, It is possible to detect the change of the voltage and judge the touch position of the capacitive type.

In the case of an induction electromagnetic field sensing mode for sensing an input of an induction electromagnetic field type, one side of the plurality of first patterns is connected to ground, and a voltage output from the plurality of first patterns Of the induction electromagnetic field based on the difference between the voltage of the first electromagnetic field and the voltage of the second electromagnetic field and the difference between the voltage output from the plurality of third patterns and the voltage of the ground loop by the induction electromagnetic field.

And one of the capacitive type control unit and the inductive electromagnetic type type control unit is set as a master control unit and the other is set as a slave control unit and the master control unit is connected to the main control unit have.

Further, the slave control unit may be arranged to perform at least one of transmission and reception to the main control unit via the master control unit.

The detection result in the sensing mode of the capacitance type and the sensing result in the sensing mode of the induction electromagnetic field type may be transmitted to the main control unit through the master control unit.

Embodiments of the present invention are directed to a method and apparatus for sensing mutual interference when occupying a common pattern in both a capacitive sensing mode and an inductive electromagnetic field sensing mode through the communication between the capacitive type control unit and the inductive electromagnetic field type control unit Thus, both the touch input of the capacitive type and the input of the induction electromagnetic field type can be smoothly processed.

Also, the effect of being able to prevent signal interference between a plurality of patterns by previously setting the time allocated for pattern occupation in the sensing mode of the capacitance type and the time allocated for occupying the pattern in the sensing mode of the induction electromagnetic field type have.

Since only the mast control unit is connected to the main control unit and communication is performed, it is possible to prevent the main control unit from being overloaded, thereby improving the performance of the main control unit by increasing the communication speed.

FIG. 1 is a schematic structural diagram of a multi-input device for sensing a capacitance type touch input and an induction electromagnetic type input according to a first embodiment of the present invention.
2 (a) and 2 (b) are schematic views for explaining the capacitive type touch input according to the first embodiment of the present invention.
3 is a schematic diagram illustrating an induction electromagnetic field type input according to a first embodiment of the present invention.
4A and 4B are schematic views for explaining detection of an induction electromagnetic field type input according to the first embodiment of the present invention.
FIG. 5 is a schematic structural view of a multiple input pad capable of sensing both a capacitive type touch input and an induction electromagnetic type input according to a first embodiment of the present invention.
FIG. 6 is a diagram for allocating time through time division per unit time in a multiple input apparatus for sensing a capacitance type touch input and an induction electromagnetic type input according to the first embodiment of the present invention.
FIG. 7 is a schematic structural diagram of a multiple input pad capable of sensing both a capacitance type touch input and an induction electromagnetic type input according to a second embodiment of the present invention.
FIG. 8 is a schematic structural diagram of a multi-input device for sensing a capacitance type touch input and an induction electromagnetic type input according to a third embodiment of the present invention.

In order to fully understand the present invention, operational advantages of the present invention, and objects achieved by the practice of the present invention, reference should be made to the accompanying drawings and the accompanying drawings which illustrate preferred embodiments of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Like reference symbols in the drawings denote like elements.

The terms " one side " and " other side " used in this specification may mean a specified side, or do not mean a specified side, but any side of a plurality of sides may be referred to as one side, And the other side is referred to as the other side.

Also, as used herein, the term " bond " or " connection " refers to the case where one member and another member are directly 'coupled' or directly 'connected', as well as one member is indirectly Or indirectly connected to each other.

The electronic pen used in the present invention will be described on the premise that it is provided with an induction electric field type in which a coil and a capacitor are built in. In the case of a battery, the electronic pen may be built in the electronic pen, Or may be provided in such a manner that energy is transmitted from the outside through the through hole.

FIG. 1 is a schematic structural view of a multiple input device for sensing capacitive type touch input and induction electromagnetic type input according to a first embodiment of the present invention. FIGS. 2 (a) and 2 (b) FIG. 3 is a schematic view for explaining an induction electromagnetic field type input according to the first embodiment of the present invention, and FIGS. 4 (a) and 4 FIG. 4B is a schematic view for explaining detection of an induction electromagnetic field type input according to the first embodiment of the present invention, and FIG. 5 is a schematic view for explaining the sensing operation of the capacitance type touch input according to the first embodiment of the present invention. FIG. 6 is a schematic structural view of a multiple input pad capable of performing both sensing and sensing of an induction electromagnetic field type input. FIG. 6 is a schematic diagram illustrating a touch input of a capacitive type and an induction electromagnetic field type input according to a first embodiment of the present invention The diagram relates to the assigned time with time per unit time divided by the input device.

Referring to these figures, a multi-input device for sensing a capacitance type touch input and an induction electromagnetic type input according to the first embodiment of the present invention includes a capacitive type control unit 100 for controlling a touch input of a capacitive type, An induction electromagnetic field type control unit 200 which is connected to the capacitive type control unit 100 so as to communicate with the induction electromagnetic field type control unit 200 and controls the input of the induction electromagnetic field type, And a main control unit 300 which communicates with one of the units 200 and performs control on the processing of a capacitive type touch input or an induction electromagnetic type input.

The multi-input device for sensing the capacitance type touch input and the induction electromagnetic type input according to the first embodiment of the present invention includes a capacitive type sensing unit 400a having a plurality of patterns for sensing touch input of a capacitive type, An induction electromagnetic field sensing unit 400b for sensing an input of an induction electromagnetic field type sharing at least a part of a plurality of patterns and an electrostatic capacity sensing unit 400b for sensing capacitive type touch input by the electrostatic capacitance sensing unit 400a, Type sensing mode for controlling the input of the induction electromagnetic field type by the type control unit 100 and the induction electromagnetic field sensing unit 400b and for sensing a touch input of the capacitive type and a sensing mode of the induction electromagnetic field type Type control unit 100 in order to select any one of the sensing modes of the inductive-electromagnetic-field-type sensing unit, A conductive magnetic field type control unit 200 connected to at least one of the capacitive type control unit 100 and the inductive electromagnetic field type control unit 200 for controlling the input of capacitive type touch input or induction electromagnetic type input And a main control unit 300 for performing control.

Although the main control unit 300 is connected to the induction electromagnetic field type control unit 200 in the present embodiment, the scope of the present invention is not limited thereto, and the main control unit 300 may include the capacitive type control unit 100, As shown in FIG.

1, the capacitance type sensing unit 400a is connected to the capacitance type control unit 100 and is configured to sense capacitive type touch input. The capacitive type touch input is connected to a multi- When a finger or the like of a user is touched, a change in the amount of charge accumulated in a pattern formed in various directions may be sensed and a corresponding signal may be input.

Referring to FIG. 5, the capacitance type sensing unit 400a may be provided with a plurality of patterns. That is, accumulation of the charge amount and change detection can be made through a plurality of patterns.

Referring to FIG. 1, the capacitance type control unit 100 controls the capacitive type touch input when a capacitive type touch input is sensed in the capacitance type sensing unit 400a, as described above.

2 (a) and 2 (b), a touch input of a capacitive type will be described. A signal input pattern Tx provided for inputting a signal to multiple input pads is arranged, The signal sensing pattern Rx may be arranged in a direction crossing the direction Tx.

Referring to FIG. 2A, the signal input pattern Tx and the signal sensing pattern Rx are disposed in close proximity to each other. The signal input pattern Tx and the signal sensing pattern Rx are electrically insulated from each other Therefore, no short occurs.

Here, when the pulse signal 50 by AC voltage is input to the signal input pattern Tx after one side of the signal sensing pattern Rx, that is, the right side of the signal sensing pattern Rx is opened with reference to FIG. 2 (a) A predetermined range of charge is accumulated in the signal sensing pattern Rx arranged close to the signal input pattern Tx (see X in FIG. 2 (b)).

When the finger of the human body approaches the signal sensing pattern Rx, the amount of charge accumulated in the signal sensing pattern Rx is changed by a finger or the like (see Y in FIG. 2 (b)), The position information of the finger can be detected. This type of touch input method is a capacitive type.

The capacitive type control unit 100 senses the change in the amount of charge accumulated in the signal sensing pattern Rx through touching the multiple input pads of the human body to detect the exact position of the finger The detected position information of the finger or the like is transmitted to the main control unit 300, processed by the main control unit 300, and various outputs corresponding thereto are enabled.

On the other hand, in the first embodiment of the present invention, it is possible to input not only the capacitive type touch input by the finger, but also the induction magnetic field type input by the electronic pen 900 or the like.

Referring to FIG. 1, an induction electromagnetic field sensing unit 400b is connected to an induction electromagnetic field sensing unit 200 to sense an induction electromagnetic field type sensing unit 400b, Unit 400a of the first embodiment.

Here, the induction electromagnetic field type control unit 200 is connected to the capacitive type control unit 100 to be able to communicate with each other. When the induction electromagnetic field type sensing unit 400b detects an induction electromagnetic field type input, Type input.

The induction electromagnetic field type control unit 200 selects one of a sensing mode of a capacitive type for sensing a capacitive type touch input and an induction electromagnetic type sensing mode for sensing an input of an induction electromagnetic field type And is provided to mutually communicate with the capacitance type control unit 100. First, the input of the induction electromagnetic type will be described with reference to Fig.

3, a line antenna 20 is connected to a closed loop. When the electronic pen 900 approaches the line antenna 20, an induced voltage is applied to the line antenna 20 by the electronic pen 900 .

The coil L1 is wound around the line antenna 20 and the coil L1 is connected to the capacitor C1 and the coil L2 and the capacitor C2 are also connected to the inside of the electronic pen 900, When the LC resonance occurs, the LC resonance (L1 * C1 = L2 * C2) is generated. When the LC resonance occurs, the LC resonance occurs from the electronic pen 900 to the line antenna 20 Energy is transferred and an induced voltage is generated.

3, the induction currents i1 and i2 flow through the line antenna 20, and when the electronic pen 900 is positioned at the center of the line antenna 20, The induced current i1 and the induced current i2 are the same in size and the induction current i1 has a value larger than the induced current i2 when the electronic pen 900 is located on the left side of the line antenna 20, The induced current i2 is greater than the induced current i1 when the antenna 20 is located on the right side.

4 is for explaining a change in the magnitude and phase of the output voltage when a plurality of line antennas 20 are provided. 4 (a) shows the arrangement of the line antenna 20, the switch 10 and the differential amplifier 30, and Fig. 4 (b) shows the arrangement of the line antenna 20, the switch 10 and the differential amplifier 30. Fig. And phase.

Assuming that the electronic pen 900 is located at the right side relative to the center with reference to FIG. 4A, when the switch 10 is at the first position, as shown in FIG. 4B, But as the switch 10 is moved from the first position to the fourth position, the voltage value increases in the positive direction and decreases again, and the electronic pen 900 is moved to the position The value of 0 [V] is increased from the position of the electronic pen 900 to the position of the switch 40, and then the direction of the electronic pen 900 is increased from the position of the electronic pen 900 to the position of the switch 10 at the 4th position on the right side.

That is, when a plurality of line antennas 20 are arranged and the plurality of line antennas 20 are sequentially scanned through the switch 10, the voltage varies according to the position of the electronic pen 900, The unit 200 can recognize that the electronic pen 900 is positioned 40 at a point where the voltage value is 0 [V].

Therefore, the induction electromagnetic field type control unit 200 detects the accurate position of the electronic pen 900 from the point where the voltage value is 0 [V], and the positional information of the electronic pen 900 thus detected is transmitted to the main control unit 300 So that the main control unit 300 can process the signals and various output corresponding thereto can be performed.

3, when a battery is built in the electronic pen 900, energy can be transferred from the electronic pen 900 to the line antenna 20 by LC resonance.

4A, when a battery is not built in the electronic pen 900, a coil-shaped power coil 600 is provided on a side surface of the line antenna 20, The energy transmitted to the electronic pen 900 can be transmitted to the line antenna 20 again.

When the electronic pen 900 with the coil L2 and the capacitor C2 connected to each other approaches the line antenna 20 although the battery is not built in, the LC resonance from the power coil 600 to the electronic pen 900 The energy is transmitted by the antenna.

When the connection of the power coil 600 is released, energy can be transferred from the electronic pen 900, which stores energy, to the line antenna 20 side by LC resonance.

Hereinafter, the electromagnetic pen 900 of the induction electromagnetic field type, in which the energy is transferred by the LC resonance without a built-in battery, will be mainly described.

1, the main control unit 300 may be connected to and communicate with one of the capacitive type control unit 100 and the induction electromagnetic type control unit 200, or may be connected to the capacitive type control unit 100, And may be connected to and communicate with both of the induction electromagnetic type control units 200.

And the main control unit 300 is provided to perform control on processing of a capacitance type touch input or an input of the induction electromagnetic field type.

In the related art, in particular, in the conventional art in which both the input by the finger touch and the input by the touch of the electronic pen are detected, the signal input pattern Tx and the signal sensing pattern Rx for inputting by finger touch , And a pattern of two directions for inputting by the touch of the electronic pen.

In this case, since both the signal input pattern Tx and the signal sensing pattern Rx for inputting by the finger touch and the two patterns for the touch input by the electronic pen are both provided, the cost is increased and the transparency is reduced .

In order to solve such a conventional problem, that is, in order to reduce the cost and improve the transparency, in the first embodiment of the present invention, the capacitive touch input and the first The pattern 410 and the second pattern 420 corresponding to the signal sensing pattern Rx may be shared and used in common.

In this connection, in the capacitance input type touch input, the induction electromagnetic field type input and the connection of the first pattern 410 and the second pattern 420 should be properly released. In the induction electromagnetic type input, The connection between the touch input and the first pattern 410 and the second pattern 420 should be properly released. Hereinafter, a capacitive touch input, an induction electromagnetic input, and a first pattern 410 and a second pattern 420 And the connection and disconnection of the connector 420 will be described in detail.

5, the capacitance type sensing unit 400a and the induction electromagnetic field sensing unit 400b include a plurality of first patterns 410, a plurality of second patterns 420, a ground loop 500, . ≪ / RTI >

Referring to FIG. 5, a plurality of first patterns 410 are formed in a first direction within a predetermined sensing region, where the first pattern 410 is a signal input pattern Tx or a signal sensing pattern Rx For convenience of explanation, a description will be made below of a case where a plurality of first patterns 410 are signal input patterns Tx.

The first direction in which the plurality of first patterns 410 are formed may be an X-axis direction or a Y-axis direction with reference to FIG. 5. For the sake of convenience of explanation, the first direction is referred to as X Axis direction will be described.

The plurality of second patterns 420 may be formed to cross the plurality of first patterns 410 and may be formed in a second direction within a predetermined sensing area. The second pattern 420 may be a signal input pattern Tx or a signal sensing pattern Rx. If the first pattern 410 is provided as the signal input pattern Tx, The second pattern 420 may be provided with the sensing pattern Rx and the second pattern 420 may be provided with the signal input pattern Tx when the first pattern 410 is provided with the signal sensing pattern Rx.

As described above, the case where the plurality of first patterns 410 are the signal input patterns Tx will be described below, so that the plurality of second patterns 420 will be described as the signal sensing patterns Rx do.

A description will be given of a case where a plurality of first patterns 410 are provided as a signal input pattern Tx and a plurality of second patterns 420 is a signal sensing pattern Rx.

The second direction in which the plurality of second patterns 420 are formed may be an X-axis direction or a Y-axis direction with reference to FIG. 5, but for convenience of description, The case of the Y axis direction will be described with reference to Fig.

Referring now to FIG. 5, the ground loop 500 is provided to surround at least a portion of the sensing area. Here, the ground loop 500 can be understood as a concept of grounding. The grounding may be set to 0 [V] corresponding to the reference point of the voltage, or may be set to a specific voltage or open state, May be provided so as to be the reference voltage.

That is, the ground loop 500 may be set to a state where it is connected to ground, a specific voltage is applied, or is open.

5, a plurality of first patterns 410 and a plurality of second patterns 420, that is, a signal input pattern Tx and a signal sensing pattern Rx are connected to the capacitance type control unit 100 and the induction electromagnetic field Type control unit 200, respectively.

Here, the switch 10 may be disposed between the signal input pattern Tx and the signal sensing pattern Rx and between the capacitive type control unit 100 and the induction electromagnetic type control unit 200, The switch 10 may be built in the capacitance type control unit 100 and the induction electromagnetic field type control unit 200.

Such a switching function can be implemented by a multiplexer (MUX) having various channels.

The plurality of first patterns 410 and the plurality of second patterns 420, that is, the signal input patterns Tx and the signal sensing patterns Rx are commonly used for inputting capacitive touch inputs and induction electromagnetic field types. May be provided for use.

The signal input pattern Tx and the signal sensing pattern Rx may be connected to or disconnected from the capacitive type control unit 100 and the induction electromagnetic type control unit 200 respectively, There is an effect that the number of films for the film can be reduced.

First, a description will be given of the case of the capacitive sensing mode in which capacitive type touch input is detected.

Here, a single routing method and a double routing method can be considered as a method of inputting the pulse signal 50 by the AC voltage through the signal input pattern Tx. In the single routing method, one side of the signal input pattern Tx is opened The pulse signal 50 is input by the alternating voltage through the other side of the signal input pattern Tx located on the opposite side of the signal input pattern Tx. The pulse signal 50 is input to the other side of the signal input pattern Tx via the one side and the other side of the signal input pattern Tx after the connection.

Hereinafter, a description will be given of a double routing method based on a method of inputting a pulse signal 50 by an AC voltage by a single routing method.

The capacitance type control unit 100 or the induction electromagnetic field type control unit 200 may be configured to include a plurality of first patterns 410, that is, one side of the signal input pattern Tx and a plurality of second patterns 420 releases one side of the signal sensing pattern Rx and disconnects the induction electromagnetic field type control unit 200 from the other side of the plurality of first patterns 410, that is, the signal input pattern Tx.

5, the right side of the signal input pattern Tx and the lower side of the signal sensing pattern Rx are connected to the switch 10 and the switch 10 is connected to the induction electromagnetic field type control unit 200, The type control unit 200 controls the switch 10 to open the right side of the signal input pattern Tx and the lower side of the signal sensing pattern Rx. Then, the left side of the signal input pattern Tx is disconnected from the induction electromagnetic field type control unit 200.

Here, the switch 10 may be provided as a multiplexer (MUX) as described above and may be disposed outside the induction electromagnetic field type control unit 200 and connected to the induction electromagnetic field type control unit 200, Or may be embedded inside the unit 200. [

5, when the right side of the signal input pattern Tx and the lower side of the signal sensing pattern Rx are opened by switching, the input of the induction electromagnetic field type becomes the sleep mode. In this case, the capacitive type touch input is detected Be able to

That is, since the right side of the signal input pattern Tx and the lower side of the signal sensing pattern Rx are opened, a plurality of the first patterns 410, that is, the AC voltage inputted through the signal input pattern Tx, A charge of a predetermined range is accumulated in the second pattern 420 or the signal sensing pattern Rx. The capacitance type control unit 100 controls the amount of charge accumulated in the signal sensing pattern Rx The touch position of the capacitance type can be determined by detecting the change of the voltage due to the change in the amount of charge.

On the other hand, the double routing method can be used depending on the size of the multiple input pad. That is, when the size of the multiple input pad is increased, the signal can be weakened by the resistance component of the signal input pattern Tx when the single routing scheme is used.

In the case where the pulse signal 50 based on the alternating voltage input through the other side of the signal input pattern Tx is transmitted along the signal input pattern Tx, And when reaching one end of the signal input pattern Tx located on the opposite side of the other side of the signal input pattern Tx, that is, the end of the signal input pattern Tx, It may be difficult for a predetermined range of charges to accumulate in the pattern Rx.

In order to solve this problem, the double routing scheme connects one side of the signal input pattern Tx to the other side of the signal input pattern Tx, and connects one side of the signal input pattern Tx and the other side of the signal input pattern Tx The pulse signal 50 by the AC voltage is input.

As a result, the pulse signal 50 due to the AC voltage is not weakened at both ends of the signal input pattern Tx. Therefore, even when the size of the multiple input pad is increased, the touch input of the capacitance type can be sufficiently detected.

Next, the case of an inductive electromagnetic field sensing mode for detecting the input of the induction electromagnetic field type will be described.

First, the capacitance type control unit 100 or the induction electromagnetic field type control unit 200 connects one side of the plurality of first patterns 410 and one side of the plurality of second patterns 420 to the ground. In this case, the capacitive type control unit 100 releases the connection of the other side of the plurality of first patterns 410 with the other side of the plurality of second patterns 420 by the switch 10 incorporated therein.

5, the right side of the plurality of first patterns 410 and the lower side of the plurality of second patterns 420 are connected to the ground by the switch 10, and the left side of the plurality of first patterns 410 And the upper side of the plurality of second patterns 420 are disconnected from the capacitance type control unit 100 by the switch 10 incorporated in the capacitance type control unit 100.

The left side of the plurality of first patterns 410 and the upper side of the plurality of second patterns 420 are connected only to the induction electromagnetic field type control unit 200 and the right side of the plurality of first patterns 410 and the plurality The lower side of the second pattern 420 is connected to the ground.

Here, when the electronic pen 900 is approached, an induced voltage is generated. By the difference between the voltage output from the plurality of first patterns 410 and the voltage of the ground loop 500 by the induction electromagnetic field, The originating position of the induction electromagnetic field in the X direction is determined through the difference between the voltage output from the plurality of second patterns 420 and the voltage of the ground loop 500. [

A detailed description of a method of detecting the input of the induction electromagnetic field type will be replaced with the description in Figs. 3 and 4 described above.

The electromagnetic pen 900 used in the method of detecting the input of the induction electromagnetic field type uses the electromagnetic pen 900 of the induction electromagnetic field type. In this case, the electronic pen 900 may not have a built-in battery. A power coil 600 in the form of a coil may be provided to surround at least a portion of the sensing area to emit an inductive electromagnetic field to the resonant circuit of the electronic pen 900. [ The specific operations of the power coil 600 and the electronic pen 900 are replaced with the above description.

On the other hand, the capacitive type control unit 100 and the induction electromagnetic type control unit 200 communicate with each other for the connection and disconnection described above. The capacitive type control unit 100 and the induction electromagnetic field type control unit 200 determine whether to connect or disconnect the plurality of first patterns 410 and the plurality of second patterns 420 while exchanging signals with each other , Whereby the current input mode can be set.

That is, in the first embodiment of the present invention, since the plurality of first patterns 410 and the plurality of second patterns 420 are commonly used in the capacitive touch input and the induction electromagnetic field type input, The capacitive type control unit 100 and the induction electromagnetic type control unit 200 are connected to each other to communicate with each other.

At least one of the sensing mode of the capacitive type and the sensing mode of the induction electromagnetic field type may be selected by mutual communication between the capacitive type control unit 100 and the induction electromagnetic type control unit 200.

Here, the selection of the mode may be such that two modes are repeatedly selected by adjusting the time interval, or may be provided such that priority is given to one mode, while other modes are selected and selected intermittently have.

On the other hand, the selection of the sensing mode of the capacitive type and the sensing mode of the induction electromagnetic type can be controlled by the capacitive type control unit 100 or the induction electromagnetic type type control unit 200, The control unit 100 is controlled to select the sensing mode of the capacitance type and the sensing mode of the induction electromagnetic field type.

1, the capacitance type control unit 100 transmits a mode selection signal 700 for indicating a selected mode of a capacitance sensing mode and an induction electromagnetic field sensing mode to an induction electromagnetic field type control unit 200, .

Here, the mode selection signal may be provided as a signal based on the capacitance-type sensing mode and the sensing mode of the induction electromagnetic-field-type sensing mode per unit time.

That is, as described above, the capacitive type sensing unit 400a and the induction electromagnetic type sensing unit 400b are provided to share at least a part of a plurality of patterns. In this case, in order to prevent interference with each other, I need to connect and disconnect.

To this end, the capacitive type control unit 100 and the induction electromagnetic type control unit 200 may be provided to enable connection and disconnection for switching input modes while communicating with each other.

Here, various methods may be considered for switching the input mode. However, in the first embodiment of the present invention, a method of dividing the unit time and allocating the divided time to each input mode may be used.

If the method of dividing the unit time and allocating the divided time to each input mode is used in order to switch the input mode, the mode selection signal is a pattern occupying the limit time that can occupy a plurality of patterns in the selected mode Time notification signal.

For example, when the unit time is 250 [ms: milliseconds], the induction electromagnetic field type control unit 200 is arranged to occupy a plurality of patterns for 240 [ms], and the remaining 10 [ms] The type control unit 100 may be arranged to occupy and use a plurality of patterns. While each of the control units 100 and 200 occupies a plurality of patterns, the control unit 100 may wait for sensing the input, detect the input, and transmit information such as required coordinates and pressure to the main control unit 300 .

In this case, when the capacitive touch input is sensed or the input of the induction electromagnetic field is detected, the time occupied by the plurality of patterns in the control units 100 and 200 per unit time may be changed.

For example, when a capacitive type touch input is detected, the unit time is changed to 105 [ms] and 5 [ms], the inductive electromagnetic field type control unit 200 occupies a plurality of patterns And for the remaining 100 [ms], the capacitance type control unit 100 may be provided to occupy and use a plurality of patterns.

That is, the mode selection signal is provided as a pattern occupancy time notification signal, so that a limit time to occupy a plurality of patterns in a selected mode is known. In this example, the limit time that the inductive electromagnetic type control unit 200 can occupy is 5 [ms], and the time limit that the capacitance type control unit 100 can occupy is 100 [ms].

On the other hand, as described above, the time for pattern occupation in the sensing mode of the capacitive type can be allocated, and the time for occupying the pattern in the sensing mode of the induction electromagnetic field type can be allocated. May be preset and stored as one piece of information.

When a predetermined input for each input mode is detected, a notification signal indicating a preset time is transmitted from the capacitance type control unit 100 to the induction electromagnetic type control unit 200.

In this respect, the pattern occupancy time notification signal may be provided as a pre-allocated allocation time notification signal that indicates the allocation time preset in the pattern occupation in the selected mode.

For example, if there is no input after initial booting, 240 [ms] is allocated to the induction electromagnetic field type control unit 200 for occupying a plurality of patterns, and the capacitance type control unit 100 10 [ms] can be assigned.

That is, the induction electromagnetic field type control unit 200 and the capacitance type control unit 100 alternately occupy a plurality of patterns and use them individually, with a unit time of 250 [ms: milliseconds] as one cycle.

When the capacitance input type touch input is sensed, the capacitance type control unit 100 sends the mode selection signal 700 to the induction electromagnetic type control unit 200. At this time, when the capacitive type touch input is sensed 5 [ms] is allocated to the inductive electromagnetic-type-type control unit 200 and 100 [ms] is allocated to the capacitive-type control unit 100, For 100 [ms], and then the induction electromagnetic field type control unit 200 connects the plurality of patterns for 5 [ms].

After the induction electromagnetic field type control unit 200 has used a plurality of patterns for 5 [ms], the capacitive type control unit 100 disconnects the capacitive type control unit 100 again.

That is, it is possible to connect and connect the plurality of patterns in the respective modes through communication between the capacitive type control unit 100 and the induction electromagnetic type control unit 200.

When the input of the electronic pen 900 is detected, that is, when the electronic pen input signal corresponding to the input of the induction electromagnetic field type is detected, the inductive electromagnetic field type control unit 200 transmits the electronic pen 900 to the electrostatic capacity type control unit 100 The pen input signal 800 is transmitted. In this case, too, the time required to occupy and use a plurality of patterns in each mode is different.

The mode selection signal 700 is sent from the capacitance type control unit 100 to the induction electromagnetic type control unit 200 and the electromagnetic induction type control unit 200 transmits the mode selection signal 700 from the induction electromagnetic type control unit 200 to the capacitance type control unit 100. [ The pen input signal 800 is sent, and a plurality of patterns can be used without interference, through mutual communication.

As a concrete example, when the sensing mode of the capacitance type is selected, the capacitance type control unit 100 controls the plurality of first patterns 410 and the plurality of second patterns 420, And so on.

In this case, the capacitive-type control unit 100 outputs the mode selection signal 700 (to the induction electromagnetic field type control unit 200) to the induction electromagnetic field type control unit 200 to inform the induction electromagnetic field type control unit 200 that the current capacitive- , See Fig. 1).

When the induction electromagnetic field type control unit 200 receives the mode selection signal 700 indicating that the pattern is occupied by the capacitive type mode, the induction electromagnetic field type control unit 200 detects the input of the electronic pen 900 The scanning may be interrupted temporarily, or may be arranged to intermittently scan after sleep for a predetermined time.

Here, if the induction electromagnetic field type control unit 200 is designed to intermittently scan after sleep for a predetermined time, if the input of the electronic pen 900 is not continuously detected, The control unit 100 sends a signal indicating that no induction electromagnetic type input is input, that is, a low-level electronic pen input signal 800 (see FIG. 1) to the capacitance type control unit 100.

In this case, since the input of the electronic pen 900 is not sensed, the capacitance type control unit 100 increases the scanning speed in the sensing mode of the capacitive type.

When the input of the electronic pen 900 is detected, the induction electromagnetic type control unit 200 transmits a signal indicating that an induction electromagnetic type input is being input, that is, a high-level electronic pen input signal 800 to the capacitance type control unit 100 ).

In this case, the capacitance type control unit 100 reduces the scanning speed in the sensing mode of the capacitive type or temporarily stops the scanning, and the capacitance type control unit 100 also controls the pattern in the mode of the induction electromagnetic field type And transmits the mode selection signal 700 to the induction electromagnetic field type control unit 200.

Here, the induction electromagnetic field type control unit 200 switches from the sensing mode of the capacitive type to the sensing mode of the induction electromagnetic field type, and the induction electromagnetic field type control unit 200 increases the speed of scanning in the induction electromagnetic field sensing mode .

6, a mode selection signal is generated when a touch input of a capacitance type or an input of an induction electromagnetic field type is detected, May be set so that the occupancy rate per unit time is set higher.

6A, the state where the touch input by the finger and the input by the electronic pen 900 are not both generated, the electronic pen input signal 800 is in a low level, and at this time, The time is allocated 240 [ms], and the time required for scanning for sensing the capacitance type is allocated to 10 [ms].

Here, the master control unit does not send any report to the main control unit 300.

6, the electronic pen input signal 800 is still in a low state when no input by the electronic pen 900 is generated but a finger input by the finger is generated, but the scanning for the detection of the induction electromagnetic field type The time required for scanning is reduced to 5 [ms: milliseconds], and the time required for scanning for sensing the capacitance type is increased to 100 [ms].

6 is different from the state a in FIG. 6, the overall cycle is different and the occupancy rate and the occupation time are different. That is, not only the occupation time but also the whole cycle and the unit time can be changed according to each state.

Where the master control unit sends a report of the capacitive type sensing at a rate of 95 pps [Point Per Second] to the main control unit 300. That is, when the inductive electromagnetic field type control unit 200 is set as the master control unit and the capacitive type control unit 100 is set as the slave control unit, the detection of the capacitance type detected from the capacitive type control unit 100 The result is sent to the master control unit, the inductive electromagnetic field type control unit 200, and then transmitted to the main control unit 300 at a rate of 95 pps [Point Per Second].

6, the electronic pen input signal 800 is switched to the high level when both the input by the electronic pen 900 and the input by the finger are generated, and it is necessary to perform the scanning for the detection of the induction electromagnetic field type The time and the time required for scanning for sensing the capacitive type are equally assigned to 10 [ms].

Here, the master control unit sends a report to the main control unit 300, which is transmitted at a speed of 100 pps [Point Per Second] for the detection result of the induction electromagnetic field type, and 50 pps [ Point Per Second].

As described above, the detection result in the sensing mode of the capacitive type and the detection result in the sensing mode of the induction electromagnetic field type are transmitted to the main control unit 300 through the master control unit.

6, the electronic pen input signal 800 is a high level when an input by the electronic pen 900 is generated but no touch input by the finger is generated, and it is necessary to perform the scanning for the detection of the induction electromagnetic field type The time is increased to 240 [ms: milliseconds], and the time required for the scanning for sensing of the capacitance type is reduced to 10 [ms].

Here, the master control unit sends a report to the main control unit 300, which is transmitted at a speed of 200 pps [Point Per Second] for the detection result of the induction field type, and in the case of the result for the detection of the capacitance type It is not transmitted.

In the first embodiment of the present invention, only one of the capacitive type control unit 100 and the induction electromagnetic type control unit 200 is connected to the main control unit 300 to communicate with the main control unit 300, So that the performance and the effect of improving the performance of the main control unit 300 by increasing the communication speed will be described.

In the first embodiment of the present invention, sensing of a capacitive type and detection of an induction electromagnetic field type are all possible. In this case, a plurality of patterns used for sensing a capacitive type and a plurality of patterns used for sensing an induced electromagnetic field type are commonly used The cost can be reduced and the transparency can be increased.

In this case, it is determined whether a plurality of patterns are to be used in the sensing mode of the capacitive type and the sensing mode of the induction electromagnetic field type. Therefore, the capacitive type control unit 100 and the induction electromagnetic type control unit 200 can communicate with each other .

Upon the first boot, the mode selection signal 700 and the electronic pen input signal 800 are initialized. Here, a waiting time is required for the capacitive type control unit 100 and the induction electromagnetic type control unit 200 to operate properly.

Then, scanning is performed to detect the capacitive type. When the sensing by the capacitance type after the scanning is not performed for one period, the sensing of the capacitance type is interrupted or intermittently performed.

If the electronic pen input signal 800 is still at a low level, the scanning for sensing of the capacitance type and the scanning for sensing of the induction electromagnetic field are slipped or intermittently performed.

Then, when the detection result input of the capacitance type is detected, the capacitance type control unit 100 increases the scanning speed of the capacitance sensing mode. When the input of the next electronic pen 900 is detected, the induction electromagnetic type control unit 200 sends a high-level electronic pen input signal 800 to the capacitive type control unit 100. In this case, The unit 100 decreases the scanning speed or stops scanning in the sensing mode of the capacitive type and the induction electromagnetic field type control unit 200 switches from the sensing mode of the capacitive type to the sensing mode of the induction electromagnetic type .

FIG. 7 is a schematic structural diagram of a multiple input pad capable of sensing both a capacitance type touch input and an induction electromagnetic type input according to a second embodiment of the present invention.

In the second embodiment of the present invention, only one of the capacitive type control unit 100 and the induction electromagnetic type control unit 200 is connected to and communicated with the main control unit 300, The operation and effect of improving the performance of the main control unit 300 by increasing the communication speed will be described. In the substrate processing according to the first embodiment of the present invention, The description common to those described in the apparatus is to be replaced with the above description.

The second embodiment of the present invention differs from the first embodiment in the structure of the multiple input pad for sensing the capacitance type touch input and sensing the induction electromagnetic type input. In other words, referring to FIG. 7, in the second embodiment of the present invention, the first pattern 410 is commonly used in the touch input of the capacitive type and the induction electromagnetic field type in comparison with the first embodiment, 420 is different from the first embodiment in that it is used for a touch input of a capacitive type and a third pattern 430 for inputting an induction electromagnetic field type is separately provided.

7, the capacitance type sensing unit 400a and the induction electromagnetic field sensing unit 400b may include a plurality of first patterns 410, a plurality of second patterns 420, (430), and a ground loop (500).

Referring to FIG. 7, a plurality of first patterns 410 are formed in a first direction within a predetermined sensing region, where the first pattern 410 is a signal input pattern Tx or a signal sensing pattern Rx For convenience of explanation, a description will be made below of a case where a plurality of first patterns 410 are signal input patterns Tx.

The first direction in which the plurality of first patterns 410 are formed may be the X axis direction or the Y axis direction with reference to FIG. 7. For the sake of convenience of explanation, the first direction is referred to as X Axis direction will be described.

The plurality of second patterns 420 may be formed to cross the plurality of first patterns 410 and may be formed in a second direction within a predetermined sensing area. The second pattern 420 may be a signal input pattern Tx or a signal sensing pattern Rx. If the first pattern 410 is provided as the signal input pattern Tx, The second pattern 420 may be provided with the sensing pattern Rx and the second pattern 420 may be provided with the signal input pattern Tx when the first pattern 410 is provided with the signal sensing pattern Rx.

As described above, the case where the plurality of first patterns 410 are the signal input patterns Tx will be described below, so that the plurality of second patterns 420 will be described as the signal sensing patterns Rx do.

A description will be given of a case where a plurality of first patterns 410 are provided as a signal input pattern Tx and a plurality of second patterns 420 is a signal sensing pattern Rx.

The second direction in which the plurality of second patterns 420 are formed may be the X-axis direction or the Y-axis direction with reference to FIG. 7, but for simplicity of explanation, The case of the Y-axis direction will be described with reference to Fig.

The plurality of third patterns 430 may be disposed in a proximity to the plurality of second patterns 420 to cross the plurality of first patterns 410 and may be formed in a second direction within a predetermined sensing area. have. Herein, a plurality of third patterns 430 may be disposed between the plurality of first patterns 410, but a plurality of third patterns 430 may be disposed between the plurality of second patterns 420 And arranged parallel to the second pattern 420 will be described. Accordingly, a plurality of third patterns 430 are provided in the Y-axis direction with reference to FIG.

Referring to FIG. 7, the ground loop 500 is provided to surround at least a part of the sensing area. Here, the ground loop 500 can be understood as a grounding concept as described above. The ground may be set to 0 [V] corresponding to the reference point of the voltage, or the specific voltage may be set to an open or open state, The specific voltage and the open state voltage may be set to be the reference voltage.

That is, the ground loop 500 may be set to a state where it is connected to ground, a specific voltage is applied, or is open.

7, a plurality of first patterns 410, that is, a signal input pattern Tx may be switchably connected to the capacitive type control unit 100 and the induction electromagnetic type control unit 200, respectively. The switch 10 is connected to one end of the plurality of first patterns 410 so as to switch between the open and the ground.

Here, the switch 10 may be disposed between the signal input pattern Tx and the capacitive type control unit 100 and the inductive electromagnetic type type control unit 200, or may be connected to each of the capacitive type control unit 100 and the capacitive type control unit 100, And the switch 10 may be provided in the induction electromagnetic field type control unit 200. The switching function may be implemented by a multiplexer (MUX) having various channels. do.

The plurality of first patterns 410, that is, the signal input patterns Tx may be commonly used for inputting capacitive touch inputs and induction electromagnetic field types.

That is, the signal input pattern Tx may be connected to the capacitive type control unit 100 and the induction electromagnetic type control unit 200, respectively, so as to be connected or disconnected when necessary, whereby the number of films Can be reduced.

However, the plurality of second patterns 420, that is, the signal sensing patterns Rx, are connected such that one side is switchable only to the capacitance type control unit 100, and the other side is kept open.

First, a description will be given of the case of the capacitive sensing mode in which capacitive type touch input is detected. Here, a single routing method and a double routing method can be considered as a method of inputting the pulse signal 50 by the AC voltage through the signal input pattern Tx. The input method of the pulse signal 50 is similar to that of the first embodiment They are replaced by the description of the first embodiment.

The capacitance type control unit 100 or the induction electromagnetic field type control unit 200 includes a plurality of first patterns 410, that is, a connection between one side of the signal input pattern Tx and the induction electromagnetic field type control unit 200 Lt; / RTI >

7, the right side of the signal input pattern Tx is opened by the switch 10 and the left side of the signal input pattern Tx is disconnected from the induction electromagnetic field type control unit 200. [ The disconnection of the left side of the signal input pattern Tx from the inductive electromagnetic field type control unit 200 can be made possible by the internal switch 10 of the induction electromagnetic type control unit 200, for example, a multiplexer (MUX) have.

In the second embodiment, the lower side of the signal sensing pattern Rx is already opened.

Referring to FIG. 7, when the right side of the signal input pattern Tx is opened by switching, the input of the induction electromagnetic field type becomes a sleep mode, and in this case, the capacitive type touch input can be detected

That is, from the signal input pattern Tx to the signal input pattern Tx which is opened by the switch 10 and the lower side of the signal sensing pattern Rx which is already open, Charges in a predetermined range are accumulated in the plurality of second patterns 420, that is, the signal sensing patterns Rx by the input AC voltage. When charges are accumulated in the signal sensing patterns Rx by the touch of a finger or the like, The touch position of the capacitive type can be determined by detecting the change in the voltage due to the change in the amount of charge.

Here, the plurality of third patterns 430 are connected to the ground loop 500 and the other end is switchably connected to the induction electromagnetic type control unit 200. In the capacitive sensing mode, the third pattern 430 ) Is disconnected.

Next, the case of an inductive electromagnetic field sensing mode for detecting the input of the induction electromagnetic field type will be described.

First, the capacitance type control unit 100 or the induction electromagnetic field type control unit 200 connects one side of the plurality of first patterns 410 to the ground. In this case, the capacitive type control unit 100 releases the connection between the capacitance type control unit 100 and the other side of the plurality of first patterns 410 by the switch 10 incorporated therein.

7, the right side of the plurality of first patterns 410 is connected to the ground, and the left side of the plurality of first patterns 410 is connected to a switch 10 (see FIG. 7) incorporated in the capacitance type control unit 100. In other words, The connection with the capacitance type control unit 100 is released.

In this case, the left side of the plurality of first patterns 410 is connected only to the induction electromagnetic field type control unit 200, and the right side of the plurality of first patterns 410 is connected to the ground.

One end of the third pattern 430 is connected to the ground loop 500, and the other end of the third pattern 430 is connected to the induction electromagnetic field type control unit 200.

Here, when the electronic pen 900 is approached, an induced voltage is generated. By the difference between the voltage output from the plurality of first patterns 410 and the voltage of the ground loop 500 by the induction electromagnetic field, And the originating position of the induction electromagnetic field in the X direction is determined through the difference between the voltage output from the plurality of third patterns 430 and the voltage of the ground loop 500. [

Meanwhile, a detailed description of a method of detecting the input of the induction electromagnetic field type will be replaced with the description of FIG. 3 and FIG. 4 described above.

The electromagnetic pen 900 used in the method of detecting the input of the induction electromagnetic field type uses the electromagnetic pen 900 of the induction electromagnetic field type. In this case, the electronic pen 900 may not have a built-in battery. A power coil 600 in the form of a coil may be provided to surround at least a portion of the sensing area to emit an inductive electromagnetic field to the resonant circuit of the electronic pen 900. [ The specific operations of the power coil 600 and the electronic pen 900 are replaced with the above description.

Meanwhile, the capacitive type control unit 100 and the induction electromagnetic type control unit 200 communicate with each other for the above-described connection and disconnection. The detailed description related to this is common to the first embodiment , It will be replaced by the description of the first embodiment.

FIG. 8 is a schematic structural diagram of a multi-input device for sensing a capacitance type touch input and an induction electromagnetic type input according to a third embodiment of the present invention.

Hereinafter, the functions and effects of the third embodiment of the present invention will be described, but the description common to those described in the first and second embodiments of the present invention will be replaced with the above description.

In the case of the third embodiment of the present invention, one of the capacitive type control unit 100 and the inductive electromagnetic type type control unit 200 is set as a master control unit and the main control unit 300 is connected to only the master control unit Which is different from the first embodiment and the second embodiment.

8, the main control unit 300 is connected to and communicates with one of the capacitive type control unit 100 and the induction electromagnetic type control unit 200. The main control unit 300 includes a capacitive type touch input or an induction electromagnetic type type input To perform the control of the process of FIG.

Here, one of the capacitive type control unit 100 and the inductive electromagnetic type type control unit 200 can be set as a master control unit and the other as a slave control unit. The present embodiment in which the unit 200 is set as a master control unit and the capacitance type control unit 100 is set as a slave control unit will be described.

However, the scope of the present invention is not limited thereto, and the capacitive type control unit 100 may be set as a master control unit and the induction electromagnetic type control unit 200 as a slave control unit.

8, the master control unit is connected to and communicated with the main control unit 300, and the slave control unit performs at least one of transmission and reception with respect to the main control unit 300 via the master control unit .

That is, as described above, the capacitive type control unit 100 is configured to control the capacitive type touch input and the induction electromagnetic type control unit 200 is configured to control the input of the induction electromagnetic type type, When the main control unit 200 is set as the master control unit, the information about the touch input of the capacitive type, for example, the position information of the finger, is also set to the master control unit via the induction electromagnetic type control unit 200 300 and may be processed in the main control unit 300.

The information about the input of the induction electromagnetic field type, for example, the position information of the electronic pen 900, is transmitted from the induction electromagnetic type control unit 200, which is set as the master control unit, directly to the main control unit 300, Lt; RTI ID = 0.0 > 300 < / RTI >

That is, in the third embodiment of the present invention, the capacitive type control unit 100 and the induction electromagnetic type control unit 200 communicate with each other, and the main control unit 300 is provided with the capacitive type control unit 100 and the induction electromagnetic type Since only one of the control units 200 set as the master control unit is connected, it is possible to prevent the main control unit 300 from being overloaded, thereby improving the performance of the main control unit by increasing the communication speed There is an effect that can be.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Accordingly, such modifications or variations are intended to fall within the scope of the appended claims.

100: Capacitive type control unit 200: Inductive electromagnetic type control unit
300: Main control unit 400a: Capacitive type sensing unit
400b: induction electromagnetic field type sensing unit 410: first pattern
420: second pattern 430: third pattern
500: Ground loop 600: Power coil
700: mode selection signal 800: electronic pen input signal
900: Electronic pen

Claims (21)

A capacitance type sensing unit having a plurality of patterns for sensing capacitive type touch inputs;
An inductive electromagnetic field type sensing unit that shares at least a portion of the plurality of patterns and senses an input of an induction electromagnetic field type;
A capacitive type control unit for controlling a capacitive type touch input by the capacitive type sensing unit;
An induction electromagnetic field type control unit for controlling an induction electromagnetic field type input by the induction electromagnetic field type sensing unit; And
A main control unit connected to at least one of the capacitive type control unit and the induction electromagnetic field type control unit and performing control on processing of the capacitive type touch input or the induction electromagnetic type input,
Wherein the capacitive type control unit and the induction electromagnetic field type control unit are connected to one of a capacitive sensing mode for sensing the capacitive touch input and an inductive electromagnetic sensing mode for sensing the input of the induction electromagnetic field type Lt; RTI ID = 0.0 > mode, < / RTI &
At least one of the capacitance type control unit and the induction electromagnetic field type control unit transmits a mode selection signal for informing a selected mode of the capacitance type sensing mode and the induction electromagnetic field type sensing mode, Type sensing mode and a selection of the sensing mode of the induction electromagnetic field type,
The time allocated for pattern occupation in the sensing mode of the capacitance type and the time allocated for occupying the pattern in the sensing mode of the induction electromagnetic field type are preset in accordance with the unit time changed according to the selected sensing mode ,
The mode selection signal is a signal based on the capacitance-type sensing mode and the sensing mode of the induction electromagnetic field-type sensing unit, and is a pattern occupancy time notification signal indicating a time limit for occupying the pattern in the selected mode Lt; / RTI &
The pattern occupancy time notification signal is provided as a pre-allocated allocation time notification signal indicating the time allocated to occupation of the pattern in the selected mode,
Wherein the mode selection signal is set such that when one of the input of the capacitive type and the input of the induction electromagnetic field type is detected, the occupancy rate per unit time of the detected mode of the detected input is set higher,
Characterized in that one of the capacitance type control unit and the induction electromagnetic field type control unit is set as a master control unit and the other is set as a slave control unit so that the master control unit is connected to the main control unit A capacitive type multi-input device for sensing touch input and induction electromagnetic type inputs. delete The method according to claim 1,
Wherein the capacitance type control unit controls the selection of the sensing mode of the capacitance type and the sensing mode of the induction electromagnetic field type by transmitting the mode selection signal to the induction electromagnetic field type control unit,
Wherein the induction electromagnetic field type control unit transmits a signal indicating that the electronic pen input is detected to the capacitance type control unit when the electronic pen input signal corresponding to the input of the induction electromagnetic field type is detected. Multiple input devices that sense inputs and induction field type inputs. delete delete delete delete delete delete The method according to claim 1,
The electrostatic capacity type sensing unit and the induction electromagnetic field sensing unit may comprise:
A plurality of first patterns formed in a first direction within a predetermined sensing area;
A plurality of second patterns formed to intersect the plurality of first patterns and formed in a second direction in the predetermined sensing area; And
And a ground loop surrounding at least a portion of the sensing area,
Wherein the plurality of first patterns and the plurality of second patterns are switchably connected to the capacitive type control unit and the induction electromagnetic field type control unit, respectively, and the capacitive type touch input and the induction electromagnetic type input Wherein the plurality of first patterns and the plurality of second patterns are commonly used in a plurality of input devices for sensing a capacitive type touch input and an induction electromagnetic type input. 11. The method of claim 10,
Characterized in that the input of the induction electromagnetic field further comprises a coil in the form of a coil using an electronic pen and surrounding at least a part of the sensing area to emit an inductive electromagnetic field with respect to the resonant circuit of the electronic pen Multi-input device that detects type touch input and induction electromagnetic type input. 11. The method of claim 10,
In the sensing mode of the capacitive type for sensing touch of the capacitive type,
Wherein either the capacitance type control unit or the induction electromagnetic field type control unit opens one side of the plurality of first patterns or connects one side of the plurality of first patterns to the other side of each of the plurality of first patterns, A voltage is applied through the plurality of first patterns and a change in voltage appearing in the plurality of second patterns is sensed by a voltage applied through the plurality of first patterns Wherein the touch position of the capacitive type is determined based on the touch position of the capacitive touch input. 11. The method of claim 10,
In the case of the inductive electromagnetic field sensing mode for sensing the input of the induction electromagnetic field type,
And a ground fault detection circuit for detecting a difference between a voltage output from the plurality of first patterns and a voltage of the ground loop by an induction electromagnetic field and inducing a difference between a voltage output from the plurality of first patterns and a voltage of the ground loop by coupling one side of the plurality of first patterns and one side of the plurality of second patterns to the ground loop And a transmission position of the induction electromagnetic field is determined based on a difference between a voltage output from the plurality of second patterns and a voltage of the ground loop by an electromagnetic field. The electrostatic capacity type touch input and the induction electromagnetic type input Multiple input device. The method according to claim 1,
The electrostatic capacity type sensing unit and the induction electromagnetic field sensing unit may comprise:
A plurality of first patterns formed in a first direction within a predetermined sensing area;
A plurality of second patterns formed to intersect the plurality of first patterns and formed in a second direction in the predetermined sensing area;
A plurality of third patterns arranged in a second direction in the predetermined sensing area, the third patterns being arranged in proximity to the plurality of second patterns to cross the plurality of first patterns; And
And a ground loop surrounding at least a portion of the sensing area,
Wherein the plurality of first patterns are switchably connected to the capacitive type control unit and the induction electromagnetic field type control unit, respectively,
Wherein the plurality of second patterns are switchably connected to the capacitance type control unit,
Wherein the plurality of third patterns are connected to the ground loop on one side and are switchably connected to the induction electromagnetic field type control unit on the other side. Device. The method according to claim 1,
The electrostatic capacity type sensing unit and the induction electromagnetic field sensing unit may comprise:
A plurality of first patterns formed in a first direction within a predetermined sensing area;
A plurality of second patterns formed to intersect the plurality of first patterns and formed in a second direction in the predetermined sensing area;
A plurality of third patterns arranged in a second direction in the predetermined sensing area, the third patterns being arranged in proximity to the plurality of second patterns to cross the plurality of first patterns; And
And a ground loop surrounding at least a portion of the sensing area,
Wherein the plurality of first patterns are switchably connected to the capacitance type control unit,
Wherein the plurality of second patterns are switchably connected to the capacitive type control unit and the induction electromagnetic field type control unit, respectively,
Wherein the plurality of third patterns are connected to the ground loop on one side and are switchably connected to the induction electromagnetic field type control unit on the other side. Device. 16. The method according to claim 14 or 15,
Characterized in that the input of the induction electromagnetic field further comprises a coil in the form of a coil using an electronic pen and surrounding at least a part of the sensing area to emit an inductive electromagnetic field with respect to the resonant circuit of the electronic pen Multi-input device that detects type touch input and induction electromagnetic type input. 15. The method of claim 14,
In the capacitive sensing mode, which senses capacitive touch inputs,
Wherein the capacitance type control unit or the induction electromagnetic field type control unit is configured to open one side of the plurality of first patterns or to connect one side of the plurality of first patterns to the other side of each of the plurality of first patterns, Wherein a voltage is applied through the first pattern and a change in voltage appearing in the plurality of second patterns is sensed by a voltage applied through the plurality of first patterns to determine a touch position of the capacitance type Capacitive type Multiple input device for sensing touch input and induction electromagnetic type input. 15. The method of claim 14,
In the case of an inductive electromagnetic field sensing mode for sensing the input of an induction electromagnetic field type,
And a second ground pattern connected to the other end of the plurality of first patterns, wherein the first pattern is connected to the ground, the difference between the voltage output from the plurality of first patterns and the ground loop by the induction electromagnetic field, Wherein the source position of the inductive electromagnetic field is determined based on a difference between a voltage of the ground loop and a voltage of the induction electromagnetic field. delete The method according to claim 1,
Wherein the slave control unit is configured to perform at least one of transmission and reception to and from the main control unit via the master control unit. 21. The method of claim 20,
Wherein the detection result in the sensing mode of the capacitive type and the sensing result in the sensing mode of the induction electromagnetic field type are transmitted to the main control unit through the master control unit. Multiple input devices that sense input.

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