A method of designing an acoustic waveguide in which acoustic waves travelling along the waveguide are treated as exhibiting single parameter behaviour, and in which the waveguide provides a boundary confining the acoustic waves as they travel along the wave propagation path and has two substantially parallel, primary surfaces spaced apart a distance less than a wavelength of a high frequency acoustic wave. The primary surfaces may be planar, curved, or a combination of planar portions and curved portions.

An audio device uses a multi-way speaker device, an ideal state being when the virtual sound source points of each unit group overlap and the spherical surface of the wavefront of the sound output from each speaker unit group overlaps one spherical surface. In order for the virtual sound source points of each unit group to be close to each other so that the wavefront of the sound output from each unit group is approximated to one spherical surface. A positioning a placement position of the speaker unit group having relatively small diameters rearward from a viewing position with respect to a placement position of the speaker unit group having relatively large diameters, and/or making the number of speaker units constituting the speaker unit group having relatively small diameters larger than the number of speaker units constituting the speaker unit group having relatively large diameters is adopted.

The present disclosure relates to a Sonar device (1) for detection of underwater objects. The sonar device (1) comprises a body element (2) comprising a piezo electric element (3). The sonar device further comprises a holder (4) adapted to hold the piezo electric element (3). The holder (4) is arranged to centre the piezo electric element (3) within said body element (2). The holder (4) is arranged such that the piezo electric element (3) is held firmly in place and also provide for that detection can be made omni-directionally. A method for manufacturing a holder (4) and a sonar device (1) is also disclosed.

A wave generator for an ultrasonic air data system can be configured to collect data derived from a flow of air in a downstream direction. The wave generator can include an ultrasonic wave source configured to output ultrasonic waves from a first end and a wave shaper connected to the first end of the ultrasonic wave source. The wave shaper can be configured to focus the ultrasonic waves into an area downstream from the ultrasonic wave source bounded by a first plane parallel to the downstream direction and a second plane orthogonal to the first plane.

A panel combination includes a panel, a directional speaker mounted to the panel, and a controller that receives a trigger signal and controls an output of the directional speaker according to the trigger signal.

An acoustic lens system comprises one or more speakers and a substrate. The speaker comprises a driver capable of receiving an audio signal and a wave forming member in communication with the driver and having a sloped surface. The speaker is adapted to abut the substrate. In use, the driver causes translation of the wave forming member in response to the audio signal. The translation of the wave forming member causes the sloped surface to generate an audio waveform that extends in a direction divergent to the direction of translation. The speaker also generates forces against the substrate so that a ripple wave is propagated along the substrate. The propagation of the ripple wave is projected perpendicularly at a location on the substrate to generate a sound wave from the substrate. The sound wave generated by the ripple wave and the divergently extending wave from the wave forming member intersect at a position away from the speaker thereby creating an immersive sound experience for the user.

An imaging system (300) includes a transducer array (308) with a transducer element (310) with at least two faces (402, 904). Each face faces a different direction. The transducer element includes at least two sub-elements (404, 902). Each sub-element is part of a different face. The at least two sub-elements transmit respective beams at each location along a scan path (806).

An imaging system (300) includes a transducer array (308) with a transducer element (310) with at least two faces (402, 904). Each face faces a different direction. The transducer element includes at least two sub-elements (404, 902). Each sub-element is part of a different face. The at least two sub-elements transmit respective beams at each location along a scan path (806).

An integrated antenna device comprises a protective casing of hydrodynamic shape delimiting an inner cavity and an upper fixing interface suitable for being fixed mechanically on a carrier structure, the device further comprises an antenna housed inside the inner cavity and fixed to the internal wall of the casing at the level of at least one fixing point, an assembly of cables comprising power supply and signals reception cables linked to the antenna. The protective casing is closed in a hermetic manner and traversed in a leaktight manner by the cables.

An integrated antenna device comprises a protective casing of hydrodynamic shape delimiting an inner cavity and an upper fixing interface suitable for being fixed mechanically on a carrier structure, the device further comprises an antenna housed inside the inner cavity and fixed to the internal wall of the casing at the level of at least one fixing point, an assembly of cables comprising power supply and signals reception cables linked to the antenna. The protective casing is closed in a hermetic manner and traversed in a leaktight manner by the cables.