Rotation operation detection mechanism and rotation operation detection method

The invention claimed is: 1. A rotation operation detection mechanism comprising: a housing; an operation surface disposed on a first main surface of the housing; an operation unit formed integrally and continuously with the housing and protruding from the operation surface, with the operation unit configured to rotate about a rotational axis that is orthogonal to the operation surface; and a sensor disposed directly on a back surface of the operation unit, wherein the sensor is planar shaped and is configured to detect a stress generated on the housing when the operation unit is rotated. 2. The rotation operation detection mechanism according to claim 1 , wherein the sensor is disposed on a back surface of the operation surface. 3. The rotation operation detection mechanism according to claim 1 , wherein the operation unit has one of a columnar or polygonal column shape. 4. The rotation operation detection mechanism according to claim 3 , wherein the operation unit has a hollow shape. 5. The rotation operation detection mechanism according to claim 4 , wherein the sensor is disposed along a circumferential direction of the operation unit. 6. The rotation operation detection mechanism according to claim 5 , wherein the sensor is disposed along a side surface of the operation unit. 7. The rotation operation detection mechanism according to claim 1 , wherein a portion of the operation unit protrudes on a back side of the operation surface. 8. The rotation operation detection mechanism according to claim 1 , wherein the sensor is configured to detect a rotation direction that matches a shear stress applied to the operation surface when the operation unit is rotated. 9. The rotation operation detection mechanism according to claim 1 , wherein the sensor is disposed on a location other than the operation unit on the operation surface, such that the sensor is disposed along a direction parallel or orthogonal to a tangential direction in a circumferential direction of the operation unit. 10. The rotation operation detection mechanism according to claim 1 , further comprising a plurality of the sensors configured to detect the stress generated on the housing when the operation unit is rotated, with the plurality of sensors being disposed annularly around the operation unit. 11. The rotation operation detection mechanism according to claim 1 , wherein the sensor extends across a boundary between the operation unit and the housing other than the operation unit. 12. The rotation operation detection mechanism according to claim 1 , wherein the sensor includes a piezoelectric film including a chiral polymer stretched in a predetermined direction, and wherein the piezoelectric film comprises a rectangular shape and a stretching direction that extends along a short side direction or a long side direction of the piezoelectric film. 13. The rotation operation detection mechanism according to claim 1 , further comprising a holding portion disposed on a back side of the operation surface in the operation unit, with the sensor being disposed on the holding portion, and wherein the holding portion has a flat plate or columnar shape. 14. A rotation operation detection mechanism comprising; a housing; an operation surface disposed on a first main surface of the housing; an operation unit formed integrally with the housing and protruding from the operation surface, with the operation unit configured to rotate about a rotational axis that is orthogonal to the operation surface; and a plurality of sensors disposed in the operation unit divided into three or more sections and that are directly coupled on a back side of the operation surface on a side surface thereof. 15. The rotation operation detection mechanism according to claim 14 , further comprising: a signal detection unit configured to detect a signal output by each sensor of the plurality of sensors; and a signal processing unit configured to receive an input signal from the respective signals detected by the signal detection unit. 16. The rotation operation detection mechanism according to claim 14 , wherein the side surface extends in a direction parallel to the rotational axis of the operation unit. 17. A rotation operation detection mechanism comprising: a housing; an operation surface disposed on a first main surface of the housing; an operation unit formed integrally with the housing and protruding from the operation surface; a plurality of sensors in the operation unit divided into three or more sections on a back side of the operation surface on a side surface thereof; a signal detection unit configured to detect a signal output by each sensor of the plurality of sensors; and a signal processing unit is configured to: receive an input signal from the respective signals detected by the signal detection unit; determine that one sensor of the plurality of sensors outputs a signal with a peak having an intensity equal to or more than a predetermined threshold for a predetermined first time; store a time at which the respective signal is determined to become a reference value as a first time; and handle a signal detected by the signal detection unit after the first time for determining a detection of rotation operation. 18. The rotation operation detection mechanism according to claim 17 , wherein the signal processing unit is configured to: store, as a second time, a time at which one sensor of the plurality of sensors outputs a signal with a peak having an intensity equal to or more than the predetermined threshold for a subsequent time after the first time; store, as a third time, a time at which one sensor of the plurality of sensors outputs a signal with a peak having an intensity equal to or more than the predetermined threshold and of a same polarity as a peak output at the second time for a subsequent time after the second time; and determine that the operation unit receives a rotation operation when signals of all sensors of the plurality of sensors are determined to exceed the predetermined threshold during a period from the first time to the third time. 19. The rotation operation detection mechanism according to claim 18 , wherein the signal processing unit is configured to determine a rotation direction of the operation unit based on a detection order of peaks of one sensor of the plurality of sensors that outputs a signal with a peak at the second time and one sensor of the plurality of sensors that outputs a signal with a peak at the third time. 20. The rotation operation detection mechanism according to claim 17 , wherein the signal processing unit is configured to: store, as a second time, a time at which one of the plurality of sensors outputs a signal with a peak having an intensity equal to or more than the predetermined threshold for subsequent time after the first time; store, as a third time, a time at which one sensor of the plurality of sensors outputs a signal with a peak having an intensity equal to or more than the predetermined threshold and of same polarity as a peak output at the second time for subsequent time after the second time; and determine that the operation unit receives only a gripping operation when signals of all of the plurality of sensors do not exceed the predetermined threshold during a period from the first time to the third time.