A method for setup a touch sensitive area of an electronic paper touch panel is provided. The method comprising: having an electronic paper display of the electronic paper touch panel marking an existing first touch sensitive area in a first display format; detecting an event via touch electrodes of the electronic paper touch panel; setting up a second touch sensitive area according to the detected event; and having the electronic paper display marking the second touch sensitive area in a second display format.

The technology disclosed relates to manipulating a virtual object. In particular, it relates to detecting a hand in a three-dimensional (3D) sensory space and generating a predictive model of the hand, and using the predictive model to track motion of the hand. The predictive model includes positions of calculation points of fingers, thumb and palm of the hand. The technology disclosed relates to dynamically selecting at least one manipulation point proximate to a virtual object based on the motion tracked by the predictive model and positions of one or more of the calculation points, and manipulating the virtual object by interaction between at least some of the calculation points of the predictive model and the dynamically selected manipulation point.

An optical IR touch sensing apparatus configured to determine, based on output signals of light detectors, a light energy value for each light path across a touch surface, and generate a transmission value for each light path based on the light energy value. A processor is then configured to operate an image reconstruction algorithm on at least part of the thus-generated transmission values and determine a position of a touching object on the touch surface, and an attenuation value corresponding to the attenuation of the light resulting from the object touching the touch surface. Using these values, the processor is configured to identify the type of object.

An optical IR touch sensing apparatus configured to determine, based on output signals of light detectors, a light energy value for each light path across a touch surface, and generate a transmission value for each light path based on the light energy value. A processor is then configured to operate an image reconstruction algorithm on at least part of the thus-generated transmission values and determine a position of a touching object on the touch surface, and an attenuation value corresponding to the attenuation of the light resulting from the object touching the touch surface. Using these values, the processor is configured to identify the type of object.

An input device comprises a plurality of optical vibration sensors mounted in a common housing. Each optical vibration sensor comprises a diffractive optical element; a light source arranged to illuminate the diffractive optical element such that a first portion of light passes through the diffractive optical element and a second portion of light is reflected from the diffractive optical element; and a photo detector arranged to detect an interference pattern generated by said first and second portions of light. The optical vibration sensor is configured so that in use, after the first portion of light passes through the diffractive optical element, the first portion of light is reflected from a reflective surface onto the photo detector. The input device is placed in contact with a surface of a solid body, and an object is brought into physical contact with the surface of the solid body, thereby causing vibrations in the solid body. The vibrations are detected using two or more of the optical vibration sensors. The relative phase(s) of the vibrations are used to determine information regarding the point of contact of the object on the surface of the solid body.

An input device comprises a plurality of optical vibration sensors mounted in a common housing. Each optical vibration sensor comprises a diffractive optical element; a light source arranged to illuminate the diffractive optical element such that a first portion of light passes through the diffractive optical element and a second portion of light is reflected from the diffractive optical element; and a photo detector arranged to detect an interference pattern generated by said first and second portions of light. The optical vibration sensor is configured so that in use, after the first portion of light passes through the diffractive optical element, the first portion of light is reflected from a reflective surface onto the photo detector. The input device is placed in contact with a surface of a solid body, and an object is brought into physical contact with the surface of the solid body, thereby causing vibrations in the solid body. The vibrations are detected using two or more of the optical vibration sensors. The relative phase(s) of the vibrations are used to determine information regarding the point of contact of the object on the surface of the solid body.

The present disclosure concerns a system that includes a multi-touch-sensitive display unit and sensing modules that are associated with the display unit for sensing force applied onto the display unit. The display unit is configured to display the sensed signal that is indicative of the force that is applied onto the display unit, in association with the position of the application of force. One realization of the system is for weighing objects on the touch-sensitive display unit. A user may place an object on the display unit and trigger weighing process by an interface of the multi-touch-sensitive display unit. The weighing process is carried out by the sensing modules and the weight of the object is displayed on the display unit in association with the object, e.g. in the vicinity to where the object is placed on the display unit.

The present disclosure concerns a system that includes a multi-touch-sensitive display unit and sensing modules that are associated with the display unit for sensing force applied onto the display unit. The display unit is configured to display the sensed signal that is indicative of the force that is applied onto the display unit, in association with the position of the application of force. One realization of the system is for weighing objects on the touch-sensitive display unit. A user may place an object on the display unit and trigger weighing process by an interface of the multi-touch-sensitive display unit. The weighing process is carried out by the sensing modules and the weight of the object is displayed on the display unit in association with the object, e.g. in the vicinity to where the object is placed on the display unit.

There is provided an information processing system, an information processing method, and a program capable of changing a process to be executed in response to a recognition result of an inclination of a hand with respect to an object. The information processing system includes: an acquisition unit configured to acquire a recognition result of an inclination of a hand with respect to an object when it is recognized that the hand is touching the object; and a change unit configured to change a value of a parameter related to a process to be executed on the basis of the recognition result.

There is provided an information processing system, an information processing method, and a program capable of changing a process to be executed in response to a recognition result of an inclination of a hand with respect to an object. The information processing system includes: an acquisition unit configured to acquire a recognition result of an inclination of a hand with respect to an object when it is recognized that the hand is touching the object; and a change unit configured to change a value of a parameter related to a process to be executed on the basis of the recognition result.