An apparatus may include an inner module, an outer module that substantially surrounds a perimeter of the inner module, a plurality of light emitters, and a light distribution medium. The plurality of light emitters may be positioned under the inner module and project light radially outward. The light distribution medium may transport the light projected from the plurality of light emitters to an edge of the light distribution medium. The edge may include a diffusive surface and traverse a substantial portion of a boundary between the inner module and the outer module.

A moving magnet motor comprising: a stationary voice coil coupled to a frame; a moving magnet assembly movably coupled to the frame and operable to move relative to the stationary coil, the moving magnet assembly comprising a magnet and a flux concentrating member that define a gap within which the stationary coil is positioned; and an actuating surface coupled to the moving magnet assembly, and wherein a movement of the moving magnet assembly drives a movement of the actuating surface along an axis of translation.

A sound emission and collection device includes a speaker, a filter processing a sound emission signal, microphones, echo cancellers cancelling regression sound signals of the sound emitted by the speaker from the sound collection signals of the corresponding microphones, a first integration section integrating adaptive filter coefficients taken out from the plurality of echo cancellers, a reverberation time estimation section estimating the reverberation time for each frequency band in the space in which the speaker and the plurality of microphones are present on the basis of the integrated adaptive filter coefficient, and an arithmetic operation section specifying a frequency band having a long reverberation time from the sound emission signal based on the estimated reverberation time, calculating a filter coefficient for suppressing power of the specified frequency band, and setting the filter coefficient to the filter.

A sound emission and collection device includes a speaker, a filter processing a sound emission signal, microphones, echo cancellers cancelling regression sound signals of the sound emitted by the speaker from the sound collection signals of the corresponding microphones, a first integration section integrating adaptive filter coefficients taken out from the plurality of echo cancellers, a reverberation time estimation section estimating the reverberation time for each frequency band in the space in which the speaker and the plurality of microphones are present on the basis of the integrated adaptive filter coefficient, and an arithmetic operation section specifying a frequency band having a long reverberation time from the sound emission signal based on the estimated reverberation time, calculating a filter coefficient for suppressing power of the specified frequency band, and setting the filter coefficient to the filter.

An electrical power unit with wireless communications capability includes a wireless communications module supported in a housing that is configured to be mounted at or along a work surface. The wireless communications module includes an audio speaker, a microphone, a wireless audio signal receiver, and a wireless audio signal transmitter. The wireless signal receiver is operable to receive first electronic audio signals from a first mobile communication device, and the audio speaker is operable to emit amplified sound in response to the wireless signal receiver receiving the first electronic audio signals. The wireless audio signal transmitter is operable to receive second electronic audio signals from the microphone, and to transmit the second electronic audio signals to the mobile communication device for further transmission from the first mobile communication device to a second communication device located remotely from the electrical power unit and the first mobile communication device.

An electrical power unit with wireless communications capability includes a wireless communications module supported in a housing that is configured to be mounted at or along a work surface. The wireless communications module includes an audio speaker, a microphone, a wireless audio signal receiver, and a wireless audio signal transmitter. The wireless signal receiver is operable to receive first electronic audio signals from a first mobile communication device, and the audio speaker is operable to emit amplified sound in response to the wireless signal receiver receiving the first electronic audio signals. The wireless audio signal transmitter is operable to receive second electronic audio signals from the microphone, and to transmit the second electronic audio signals to the mobile communication device for further transmission from the first mobile communication device to a second communication device located remotely from the electrical power unit and the first mobile communication device.

Aspects of the present disclosure relate to a speakerphone configuration for audio and/or video conferencing that includes a cavity underneath the speakerphone where cable ports are arranged. The arrangement of the cable ports are such that when a power plug is installed in the speakerphone, a telecommunication port is blocked, and vice versa. In addition, the port arrangement allows cables to attach to opposite walls in the cavity such that cables run parallel to each other within the cavity. The disclosed speakerphone may be daisy-chained together and function as a single unit. Therefore a speakerphone according to the disclosure may function as either a master unit, a mid unit, or an end unit in a string of speakerphones depending on how the speakerphone is wired. The port arrangement in the cavity increases ease for setup and daisy-chaining of multiple speakerphone units.

Aspects of the present disclosure relate to a speakerphone configuration for audio and/or video conferencing that includes a cavity underneath the speakerphone where cable ports are arranged. The arrangement of the cable ports are such that when a power plug is installed in the speakerphone, a telecommunication port is blocked, and vice versa. In addition, the port arrangement allows cables to attach to opposite walls in the cavity such that cables run parallel to each other within the cavity. The disclosed speakerphone may be daisy-chained together and function as a single unit. Therefore a speakerphone according to the disclosure may function as either a master unit, a mid unit, or an end unit in a string of speakerphones depending on how the speakerphone is wired. The port arrangement in the cavity increases ease for setup and daisy-chaining of multiple speakerphone units.

The present invention relates to a desktop speakerphone constructed to make the desktop speakerphone less space-consuming while having improved audio qualities. The desktop speakerphone preferably has two microphone clusters 6, 7 mounted at the upper side of the housing 2 closer towards respective longitudinal ends 8 of the latter, so that each microphone cluster 6, 7 can receive voice sound A.sub.v from one or more of the users. Each microphone cluster 6, 7 preferably comprises three pressure microphones 10, 11, 12. Furthermore, within each microphone cluster 6, 7, the second and third sound inlets 14, 15 are preferably arranged symmetrically on opposite sides of the respective median plane 18. Within each microphone cluster 6, 7, the relative arrangement of the three sound inlets 13, 14, 15 defines a respective microphone axis 9, 19 for each of the microphone pairs 10, 11, 10, 12. The microphone axis 9 of the first microphone pair 10, 11 extends through the first and the second sound inlet 13, 14, while the microphone axis 19 of the second microphone pair 10, 12 extends through the first and the third sound inlet 13, 15. The microphones are connected to multiple array processors, each configured to provide an array signal in dependence on two or more of the multiple microphone signals. First and second array processor configured to provide array signals in dependence on microphone signals.

The present invention relates to a desktop speakerphone constructed to make the desktop speakerphone less space-consuming while having improved audio qualities. The desktop speakerphone preferably has two microphone clusters 6, 7 mounted at the upper side of the housing 2 closer towards respective longitudinal ends 8 of the latter, so that each microphone cluster 6, 7 can receive voice sound A.sub.v from one or more of the users. Each microphone cluster 6, 7 preferably comprises three pressure microphones 10, 11, 12. Furthermore, within each microphone cluster 6, 7, the second and third sound inlets 14, 15 are preferably arranged symmetrically on opposite sides of the respective median plane 18. Within each microphone cluster 6, 7, the relative arrangement of the three sound inlets 13, 14, 15 defines a respective microphone axis 9, 19 for each of the microphone pairs 10, 11, 10, 12. The microphone axis 9 of the first microphone pair 10, 11 extends through the first and the second sound inlet 13, 14, while the microphone axis 19 of the second microphone pair 10, 12 extends through the first and the third sound inlet 13, 15. The microphones are connected to multiple array processors, each configured to provide an array signal in dependence on two or more of the multiple microphone signals. First and second array processor configured to provide array signals in dependence on microphone signals.