Apparatus for driving of a touch panel having a dummy electrode and haptic mode

What is claimed is: 1. An apparatus comprising: a touch panel including a plurality of touch driving electrodes, an elastic dielectric member provided on the plurality of touch driving electrodes, and a plurality of touch sensing electrode groups provided on the elastic dielectric member and respectively intersected and overlapped with the plurality of touch driving electrodes, wherein each of the touch sensing electrode groups includes a touch sensing electrode and a first dummy electrode being in parallel to each other on the elastic dielectric member; and a touch driving circuit configured to: in a touch point sensing mode, electrically float the first dummy electrode in a unit of a touch sensing electrode group and sense a change of capacitance through the touch sensing electrode of the touch sensing electrode group, and in a haptic mode, apply a voltage to a touch driving electrode and apply a reference voltage to the touch sensing electrode group, wherein the first dummy electrode of the touch sensing electrode group is electrically connected with the touch sensing electrode in the unit of the touch sensing electrode group in the haptic mode, and wherein the touch driving circuit generates touch force sensing data by electrically connecting the first dummy electrode to the touch sensing electrode in the unit of the touch sensing electrode group and sensing another change of capacitance through the touch sensing electrode while supplying a touch driving pulse to the touch driving electrode in accordance with a touch force sensing mode. 2. The apparatus according to claim 1 , wherein the voltage applied to the touch driving electrode is an AC voltage at a predetermined frequency. 3. The apparatus according to claim 2 , wherein the elastic dielectric member varies according to an amplitude of the AC voltage. 4. The apparatus according to claim 1 , wherein the elastic dielectric member is comprised of PDMS (polydimethylsiloxane), acrylic or poly-urethane material. 5. The apparatus according to claim 1 , wherein the touch driving circuit generates touch point sensing data by electrically floating the first dummy electrode in a unit of the touch sensing electrode group and sensing the change of capacitance through the touch sensing electrode while supplying the touch driving pulse to the touch driving electrode in accordance with the touch point sensing mode. 6. The apparatus according to claim 5 , wherein each of the touch sensing electrode groups includes a second dummy electrode being in parallel to the first dummy electrode with the touch sensing electrode interposed therebetween, wherein the touch driving circuit electrically floats the first dummy electrode and the second dummy electrode in the unit of the touch sensing electrode group in accordance with the touch point sensing mode, and electrically connects the first dummy electrode and the second dummy electrode with the touch sensing electrode in the unit of the touch sensing electrode group in accordance with the touch force sensing mode. 7. The apparatus according to claim 6 , further comprising a haptic control circuit for determining a haptic area and haptic intensity based on at least one of the touch point sensing data and the touch force sensing data, and generating a haptic mode signal corresponding to the determined haptic area and the haptic intensity in accordance with the haptic mode. 8. The apparatus according to claim 7 , wherein the touch driving circuit applies the voltage to the touch driving electrode in the haptic area and applies the reference voltage to the first dummy electrode, the second dummy electrode, and the touch sensing electrode for the touch sensing electrode group included in the haptic area based on the haptic mode signal. 9. The apparatus according to claim 8 , wherein the touch driving circuit includes: a driving signal supplying part for supplying the touch driving pulse to the touch driving electrode in accordance with the touch point sensing mode and the touch force sensing mode, and generating the voltage corresponding to the haptic mode signal in accordance with the haptic mode and supplying the generated voltage corresponding to the haptic mode signal to the touch driving electrode; an electrode connecting part for electrically floating the first dummy electrode and the second dummy electrode in the unit of the touch sensing electrode group in accordance with the touch point sensing mode, electrically connecting the first dummy electrode and the second dummy electrode to the touch sensing electrode in the unit of the touch sensing electrode group in accordance with the touch force sensing mode, and applying the reference voltage to the first dummy electrode, the second dummy electrode, and the touch sensing electrode for the touch sensing electrode group included in the haptic area in accordance with the haptic mode; a sensing part for generating the touch point sensing data and the touch force sensing data, wherein the sensing part is connected with the touch sensing electrode through the electrode connecting part in accordance with the touch point sensing mode and the touch force sensing mode so as to sense the change of capacitance through the touch sensing electrode; and a sensing data processing part for storing the touch point sensing data and the touch force sensing data provided from the sensing part in a memory, and transmitting the touch point sensing data and the touch force sensing data stored in the memory to a host system. 10. The apparatus according to claim 9 , wherein the electrode connecting part includes: a first switching device for electrically floating the first dummy electrode by each of the touch sensing electrode groups in accordance with the touch point sensing mode, and electrically connecting the first dummy electrode to the touch sensing electrode by each of the touch sensing electrode groups in accordance with the touch force sensing mode or the haptic mode; a second switching device for electrically floating the second dummy electrode by each of the touch sensing electrode groups in accordance with the touch point sensing mode, and electrically connecting the second dummy electrode to the touch sensing electrode by each of the touch sensing electrode groups in accordance with the touch force sensing mode or the haptic mode; and a multiplexer for connecting the touch sensing electrode to the sensing part by each of the touch sensing electrode groups in accordance with the touch point sensing mode or the touch force sensing mode, and supplying the reference voltage to the touch sensing electrode by each of the touch sensing electrode groups in accordance with the haptic mode. 11. The apparatus according to claim 6 , wherein each of the touch sensing electrode groups includes a dummy bridge electrode for electrically connecting one side of the first dummy electrode with one side of the second dummy electrode. 12. The apparatus according to claim 11 , further comprising a haptic control circuit for determining a haptic area and a haptic intensity based on at least one of the touch point sensing data and the touch force sensing data, and generating a haptic mode signal corresponding to the determined haptic area and the haptic intensity in accordance with the haptic mode. 13. The apparatus according to claim 12 , wherein the touch driving circuit applies the voltage to the touch driving electrode in the haptic area and applies the reference voltage to the first dummy electrode, the second dummy electrode, and the touch sensing electrode for the touch sensing electrode group included in the haptic area based on the haptic mode s