Abstract: The present invention relates to a modular architecture for transmitting and/or receiving radio frequency (RF) signals using a phased antenna array. A first portion of the RF signal is transmitted/received by a master IC (21) and a second portion of the RF signal is transmitted/received by a plurality of satellite ICs (22). RF distribution between the master IC (21) and the satellite ICs (22) occur over a low-RF-loss interposer (51). The master IC (21) performs upconversion/downconversion between RF signal and a baseband or intermediate frequency signal.

Abstract: A frequency reference device comprising a waveguide with a first end and a second end, a signal transmitter module for generating a high-frequency electromagnetic wave in the waveguide, and a signal receiver module for receiving the high-frequency electromagnetic wave in the waveguide. The component comprises a sealed enclosure, and said sealed enclosure is filled with a gas. The waveguide, first and second radiation coupling probes and the signal transmitter module and the signal receiver module are all located within said scaled enclosure.

Abstract: The present invention relates to a millimeter wave RF antenna array apparatus. The apparatus comprises a single-chip MMIC comprising active circuit elements of the antenna array apparatus. The active circuit elements comprise at least antenna feed circuitry configured to feed antenna elements of the antenna array. The apparatus comprises an interposer fabricated of low-loss RF material, such as glass, low-temperature co-fired ceramic, LTCC, or printed circuit board, PCB. The interposer comprises transmission lines of a RF distribution network and a plurality of antenna elements of the antenna array. The transmission lines of the interposer are coupled to the MMIC for providing RF connections for distributing RF signals to and from the antenna feed circuitry. Area of the interposer that comprises the transmission lines of the RF distribution network and the plurality of antenna elements is collocated with the area of the MMIC that comprises said antenna feed circuitry.

Abstract: According to an example aspect of the present invention, there is provided a wafer-level package (1), comprising a top substrate (10) and a bottom substrate (30), wherein the top substrate (10) comprises a recess (12) on a side of the top substrate (10) which is towards the bottom substrate (30) and the bottom substrate (30) comprises a recess (32) on a side of the bottom substrate (30) which is towards the top substrate (10), wherein the recess (12) of the top substrate (10) and the recess (32) of the bottom substrate (30) are arranged to form a waveguide (5) within the wafer-level package (1) and a middle substrate (20) arranged to couple an integrated circuit (24) of the wafer-level package (1) to the waveguide (5), wherein the middle substrate (20) is in between the top substrate (10) and the bottom substrate (30) and the middle substrate (20) comprises a probe (21), wherein the probe (21) extends to the waveguide (5) and the probe (21) is arranged to couple a signal coming from the integrated circuit (24

Abstract: A probe apparatus of a millimeter or submillimeter radio frequency band comprises transition layers having outermost layers on opposite surfaces of the probe apparatus. An internal transition cavity extends through the transition layers for guiding electromagnetic radiation within the probe apparatus. A probe layer disposed between the transition layers, the probe layer having a lateral transmission line for interacting with the electromagnetic radiation guided by the internal transmission cavity.

Abstract: A probe apparatus of a millimeter or submillimeter radio frequency band comprises transition layers having outermost layers on opposite surfaces of the probe apparatus. An internal transition cavity extends through the transition layers for guiding electromagnetic radiation within the probe apparatus. A probe layer disposed between the transition layers, the probe layer having a lateral transmission line for interacting with the electromagnetic radiation guided by the internal transmission cavity.

Abstract: Apparatus including one or more carbon nanotubes; one or more fullerenes directly covalently bonded to the one or more carbon nanotubes; and one or more photoactive molecules bonded to the one or more fullerenes.

Abstract: According to an example aspect of the present invention, there is provided a MEMS capacitive pressure sensor (1), comprising a first electrode (17), a deformable second electrode (18) being electrically insulated from the first electrode (17) by means of a chamber (4) between the first electrode (17) and the second electrode (18), and wherein at least one of the first electrode (17) and the second electrode (18) includes at least one pedestal (5) protruding into the chamber (4). According to another example aspect of the present invention, there is also provided a method for manufacturing a MEMS capacitive pressure sensor (1).

Abstract: A printed wiring board including a conductive layer, the conductive layer including a network of nanotubes with respective longitudinal axes, the nanotubes arranged such that their longitudinal axes are aligned substantially parallel to one another in a configuration such that electrical current passing through the conductive layer along a first axis substantially parallel to the longitudinal axes of the nanotubes experiences one degree of dissipation, and electrical current passing through the conductive layer along a second axis experiences a higher degree of dissipation.

Abstract: A voltage-tunable phase shifter comprising a conducting line and a ground electrode separated by a layer of dielectric material, the phase shifter configured to generate an electric field when a potential difference is applied between the conducting line and ground electrode, the electric field configured to change the phase of an electromagnetic signal propagating along the conducting line, wherein the ground electrode comprises graphene, and wherein the change in phase is dependent upon the strength of electric field and can be controlled by varying the potential difference between the conducting line and the ground electrode.

Abstract: In one or more embodiments described herein, there is provided an apparatus comprising input and output waveguides, and a carbon nanotube array. The array is positioned to electromagnetically couple the waveguides. The array has a slow-wave factor associated therewith, the speed of propagation of waves through the array being determined by this slow-wave factor. The array also has a first interface region. The apparatus further comprises a tuning element positioned to oppose the first interface region of the array to define a tuning distance. The slow-wave factor is affected by this tuning distance, and the tuning element is configured to be movable with respect to the first interface region so as to vary this tuning distance and thereby control the speed of propagation of waves through the array.

Abstract: An apparatus including a spin torque oscillator configured to receive an input electric current and to produce a radio frequency output signal; and a tunable current source for providing an input electric current to the spin torque oscillator.

Abstract: An apparatus (200) comprising: a first electrode (204), wherein the first electrode comprises at least one layer of graphene; a second electrode (208); and a layer of piezoelectric material (206) disposed between the first electrode (204) and the second electrode (208), wherein the piezoelectric material (206) is able to resonate at a resonant frequency in response to application of an oscillating electrical signal to the first or second electrode (204, 208).

Abstract: A printed wiring board including a conductive layer, the conductive layer including a network of nanotubes with respective longitudinal axes, the nanotubes arranged such that their longitudinal axes are aligned substantially parallel to one another in a configuration such that electrical current passing through the conductive layer along a first axis substantially parallel to the longitudinal axes of the nanotubes experiences one degree of dissipation, and electrical current passing through the conductive layer along a second axis experiences a higher degree of dissipation.

Abstract: A voltage-tunable phase shifter comprising a conducting line and a ground electrode separated by a layer of dielectric material, the phase shifter configured to generate an electric field when a potential difference is applied between the conducting line and ground electrode, the electric field configured to change the phase of an electromagnetic signal propagating along the conducting line, wherein the ground electrode comprises graphene, and wherein the change in phase is dependent upon the strength of electric field and can be controlled by varying the potential difference between the conducting line and the ground electrode.

Abstract: A data storage medium stories data in the form of marks, said marks being written and/or read by an array of probes. The storage medium further includes a plurality of data fields, each field including an area of the storage medium which, in use, is scanned for reading and/or writing by an associated one of the array of probes. The data fields include operational data fields having operational data for operating said scanning stored dierein, wherein the operational data fields are arranged in a plurality of clusters, each cluster including a plurality of adjacent operational data fields. The invention also provides a method of scanning the data storage medium with the probe array, in which a target data field is determined and an operational data cluster closest to the target data field is selected and the operational data stored therein is used to control parameters of the scanning.

Abstract: In one or more embodiments described herein, there is provided an apparatus comprising input and output waveguides, and a carbon nanotube array. The array is positioned to electromagnetically couple the waveguides. The array has a slow-wave factor associated therewith, the speed of propagation of waves through the array being determined by this slow-wave factor. The array also has a first interface region. The apparatus further comprises a tuning element positioned to oppose the first interface region of the array to define a tuning distance. The slow-wave factor is affected by this tuning distance, and the tuning element is configured to be movable with respect to the first interface region so as to vary this tuning distance and thereby control the speed of propagation of waves through the array.

Abstract: An apparatus including a spin torque oscillator configured to receive an input electric current and to produce a radio frequency output signal; and a tunable current source for providing an input electric current to the spin torque oscillator.

Abstract: Apparatus including one or more carbon nanotubes; one or more fullerenes directly covalently bonded to the one or more carbon nanotubes; and one or more photoactive molecules bonded to the one or more fullerenes.

Abstract: The invention relates to a method of determining wear of a data storage medium actively by performing a read operation on the data storage medium and detecting a read signal, comparing the read signal to at least one wear threshold; and determining a wear level of an area of the data storage medium based on the comparison. The wear threshold is lower than a detection threshold, wherein the detection of the read signal above the detection threshold indicates the presence of stored data.