Described are methods and apparatuses pertaining to stacked integrated circuits having application in ultra-low-power and small form factor design, with fast prototyping and mass-production cycle time, including application for millimeter wave radio frequency circuits.

Described are methods and apparatuses pertaining to stacked integrated circuits having application in ultra-low-power and small form factor design, with fast prototyping and mass-production cycle time, including application for millimeter wave radio frequency circuits.

Described are methods and apparatuses pertaining to stacked integrated circuits having application in ultra-low-power and small form factor design, with fast prototyping and mass-production cycle time, including application for millimeter wave radio frequency circuits.

Described are methods and apparatuses pertaining to stacked integrated circuits having application in ultra-low-power and small form factor design, with fast prototyping and mass-production cycle time, including application for millimeter wave radio frequency circuits.

A method for evaluating a behaviour of a device comprises obtaining a first dataset representing a first set of values of at least two parameters relating to a first antenna pattern; and obtaining a second dataset representing a second set of values of the at least two parameters relating to a second antenna pattern being formed by the device. The method comprises relating the first dataset and the second dataset using a metric to obtain a relationship. Further, the method comprises evaluating at least a behaviour of the device using the relationship.

A method for evaluating a behaviour of a device comprises obtaining a first dataset representing a first set of values of at least two parameters relating to a first antenna pattern; and obtaining a second dataset representing a second set of values of the at least two parameters relating to a second antenna pattern being formed by the device. The method comprises relating the first dataset and the second dataset using a metric to obtain a relationship. Further, the method comprises evaluating at least a behaviour of the device using the relationship.

An electronic device is described. This electronic device may include a communication circuit (such as an integrated circuit) that combines an interrogator and a transponder. Notably, the communication circuit may dynamically and temporally interleave an interrogator or the transponder transmission with a transponder response to a second interrogator or the second transponder transmission associated with a second electronic device. Moreover, the electronic device may include or may be selectively electrically coupled to at least an omnidirectional antenna that is used for bidirectional communication, such as: transmitting the interrogator or the transponder transmission (or message), receiving the second interrogator or the second transponder transmission (or message), and/or transmitting the transponder response to the second interrogator or the second transponder transmission.

An electronic device is described. This electronic device may include a communication circuit (such as an integrated circuit) that combines an interrogator and a transponder. Notably, the communication circuit may dynamically and temporally interleave an interrogator or the transponder transmission with a transponder response to a second interrogator or the second transponder transmission associated with a second electronic device. Moreover, the electronic device may include or may be selectively electrically coupled to at least an omnidirectional antenna that is used for bidirectional communication, such as: transmitting the interrogator or the transponder transmission (or message), receiving the second interrogator or the second transponder transmission (or message), and/or transmitting the transponder response to the second interrogator or the second transponder transmission.

Aspects of the present disclosure relate to wireless communications, and more particularly, to techniques for detecting the possibility of damage to a receiver during a self-interference measurement procedure and taking action to avoid or mitigate such damage.

A switching system for sequential switching of radio frequency paths is provided. The switching system comprises a plurality of inputs and a plurality of outputs, a plurality of switching elements respectively connected between the plurality of inputs and the plurality of outputs and a trigger module. In this context, multiple signal paths are defined between the plurality of inputs and the plurality of outputs corresponding to specific switch positions of the plurality of switching elements. In addition, the trigger module is adapted to generate a trigger signal in order to switch between the multiple signal paths.