Systems and methods for use with a mobile electronic device comprising a housing having articulated structures on one or more of the housing side walls, the articulated structures including at least two segments forming an engagement which enables pivotal motion upon the application of a force on the housing thus enabling the housing to flex responsively.

Systems and methods for use with a mobile electronic device comprising a housing having articulated structures on one or more of the housing side walls, the articulated structures including at least two segments forming an engagement which enables pivotal motion upon the application of a force on the housing thus enabling the housing to flex responsively.

A semiconductor-based stress sensor can include a bipolar transistor device with first and second collector terminals. An excitation circuit can provide an excitation signal to an emitter terminal of the bipolar transistor device, and a physical stress indicator for the semiconductor can be provided based on a relationship between signals measured at the collector terminals in response to the excitation signal. The signals can indicate a charge carrier mobility characteristic of the semiconductor, which can be used to provide an indication of physical stress. In an example, the physical stress indicator is based on a current deflection characteristic of a base region of the transistor device.

A control method for a user interface system may include receiving an input signal, receiving a temperature signal indicative of a temperature, generating a baseline signal based on at least one among the input signal and the temperature signal, calculating an error signal based on a difference of the input signal and the baseline signal, and modifying the baseline signal based on the error signal.

A force transducer is disclosed, which is arranged in such a way that, when a force is applied to the force transducer, two output signals from the force transducer are generated, which output signals are representative of the force components in a first plane and in a second plane perpendicular to the first plane, respectively, whereas force components in a third plane perpendicular to the first plane and the second plane do not affect the output signals from the force transducer. Furthermore, a measuring device is disclosed, comprising a handle comprising such a force transducer and a base unit, to which the handle is attached. Even further, a system for measuring muscle stiffness is disclosed, comprising a measuring unit and a processing unit, the measuring unit comprising such a measuring device.

A force sensor apparatus is provided including a tube portion having a plurality of radial ribs and at least one fiber optic strain gauge positioned over each rib of the plurality of radial ribs. A proximal end of the tube portion is operably couplable to a shaft of a surgical instrument that is operably couplable to a manipulator arm of a robotic surgical system, and a distal end of the tube portion is proximally couplable to a wrist joint coupled to an end effector. A thermal shunt shell is over an outer surface of the tube portion.

A force sensor apparatus is provided including a tube portion having a plurality of radial ribs and at least one fiber optic strain gauge positioned over each rib of the plurality of radial ribs. A proximal end of the tube portion is operably couplable to a shaft of a surgical instrument that is operably couplable to a manipulator arm of a robotic surgical system, and a distal end of the tube portion is proximally couplable to a wrist joint coupled to an end effector. A thermal shunt shell is over an outer surface of the tube portion.

A micromechanical structure in accordance with various embodiments may include: a substrate; and a functional structure arranged at the substrate; wherein the functional structure includes a functional region which is deflectable with respect to the substrate responsive to a force acting on the functional region; and wherein at least a section of the functional region has an elastic modulus in the range from about 5 GPa to about 70 GPa.

A micromechanical structure in accordance with various embodiments may include: a substrate; and a functional structure arranged at the substrate; wherein the functional structure includes a functional region which is deflectable with respect to the substrate responsive to a force acting on the functional region; and wherein at least a section of the functional region has an elastic modulus in the range from about 5 GPa to about 70 GPa.

A mobile device including various components in communication with one another, the mobile device comprising a flexible housing, flexible display device mounted in the housing, a deformation sensor mounted in the housing and a device controller configured to operate the mobile device responsive to receipt of data input from the flexible display device, wherein the device controller automatically deactivates the processing of at least a portion of data input received of the plurality of data input received from the display device responsive to receiving communication from the deformation sensor detecting a threshold level of deformation of the housing.