The present application claims priority to European Patent Application 18164264.6 filed by the European Patent Office on Mar. 27, 2018, the entire contents of which being incorporated herein by reference.
The present disclosure generally pertains to the field of acoustics, in particular to the design of loudspeakers and to an acoustic waveguide.
A loudspeaker cabinet (or speaker box) is an enclosure in which speaker drivers (e.g., loudspeakers and tweeters) and associated electronic hardware are mounted. Depending on the design, the loudspeaker cabinet significantly influences the reproduction characteristics of the sound transducers used. Especially in the low frequency range, the loudspeaker cabinet is used to avoid an acoustic short circuit.
In loudspeaker design, waveguides are used to control the directivity of a speaker. Acoustic waveguides are used to create a certain radiation pattern of a speaker box. Such guides are designed to provide a specific directivity pattern.
Although loudspeaker with acoustic waveguides do exist, it is generally desirable to improve the design of loudspeakers and speaker boxes.
According to a first aspect the disclosure provides a loudspeaker comprising an acoustic waveguide, the acoustic waveguide being configured to change its shape in order to change the directivity of sound emitted by the loudspeaker.
According to a further aspect the disclosure provides a method comprising changing the shape of an acoustic waveguide in order to change the directivity of sound emitted by a loudspeaker.
According to a further aspect the disclosure provides an acoustic waveguide, the acoustic waveguide being configured to change its shape in order to change the directivity of sound received from a sound source.
According to a further aspect the disclosure provides a method comprising changing the shape of an acoustic waveguide in order to change the directivity of sound emitted by a sound source.
Further aspects are set forth in the dependent claims, the following description and the drawings.
Embodiments are explained by way of example with respect to the accompanying drawings, in which:
The embodiments described below in more detail provide a loudspeaker comprising an acoustic waveguide, the acoustic waveguide being configured to change its shape in order to change the directivity of sound emitted by the loudspeaker.
The flexible acoustic waveguide may guide the acoustic sound produced by the loudspeaker according to multiple alternative directivity patterns. The flexible acoustic waveguide may comprise walls or other media. The flexible acoustic waveguide may for example comprise elements with different rigidities so that the acoustic waveguide may be able to alter a shape mechanically or electromagnetically.
The loudspeaker may be an electroacoustic transducer which converts an electrical audio signal into corresponding sound. In particular, the loudspeaker may be a woofer, i.e. a speaker that is sized and constructed so that it can reproduce low or low and mid-range frequencies well.
The flexible acoustic waveguide may change its shape to adjust the directivity of the loudspeaker depending on a desired pattern, e.g. depending on an environment or a listening position.
Changing the shape of the acoustic waveguide and thus the directivity of sound emitted by the loudspeaker may for example allow a flexible adaptation of the loudspeaker to different rooms or listening positions. For example, the sound emitted by the loudspeaker may be focused at the position of a listener that has been previously captured by a sensor, e.g. one or more cameras or other sensors. Alternatively, by changing the shape of the acoustic waveguide, the sound emitted by the loudspeaker may be focused at a position that is defined by a user input. Still alternatively, the shape of the acoustic waveguide may be changed based on information of an external device, which can scan the room and/or environment.
The shape of acoustic waveguide may for example determine the sweet spot of the loudspeaker. When the directivity of the acoustic waveguide is low, an acoustic wave having a smaller directivity is produced. When the directivity of the acoustic waveguide of the acoustic waveguide is strong, an acoustic wave having a stronger directivity is generated.
The acoustic waveguide may comprise a speaker plate that is configured to support a speaker driver. The speaker driver may be a device that converts electrical signals into sound as the result of an electro-mechanical process. The speaker driver may for example be a dynamic speaker, a tweeter, or the like.
The acoustic waveguide may for example be configured to dynamically change its opening angle. A waveguide with smaller opening angle may result in a small sweet spot, but excellent spatial reproduction, where as a waveguide with wider opening may have a big sweet spot, but a more flat spatial reproduction.
The acoustic waveguide may comprise adjustable elements. An acoustic waveguide may for example consist of adjustable elements that are connected by some flexible parts.
The loudspeaker may further comprise an adjustment device that is configured to dynamically change the shape of the acoustic waveguide. The adjustment device may for example be configured to control the position of a speaker plate and/or speaker driver within a loudspeaker box.
The adjustment device may be configured to change the shape of the acoustic waveguide mechanically. A motor, such as a stepper motor may be as adjustment device. The motor may for example be connected with a pin to the speaker plate.
Alternatively, the adjustment device may be configured to change the shape of the acoustic waveguide electromagnetically. In order to change the shape of the acoustic waveguide electromagnetically, the speaker plate or a solid ring to which the speaker plate is attached may be made of a conductor (metal), for example iron. When a magnetic field is applied to the solid ring, the solid ring may be pulled toward the magnetic field. In addition or alternatively, iron threads or wires may be disposed in the flexible parts and/or the rigid parts of the acoustic waveguide. When a magnetic field is applied, the shape of the acoustic waveguide is changed depending on the electrical current through the iron threads or wires. The amount and the direction of the current may give the moving force for modifying the shape of the acoustic waveguide.
The acoustic waveguide may comprise one or more flexible parts. The flexible part may be able to extend or shrink (compress) so that the shape of the acoustic waveguide may be changed. The flexible parts may for example be made of an elastic material such as rubber, an elastomer, etc.
In addition or alternatively, the acoustic waveguide may comprise one or more rigid parts. The rigid parts may for example be solid rings or the like. The rigid parts may be made out wood, metal, or the like. The flexibility of the acoustic waveguide may maintain by the parts with lower rigidity, whereas the needed stiffness may be provided by the rigid elements.
The embodiments also disclose a method comprising changing the shape of an acoustic waveguide in order to change the directivity of sound emitted by a loudspeaker. The method further comprising obtaining a desired directivity and changing the directivity of sound emitted by the loudspeaker to the desired directivity.
According to an embodiment, an acoustic waveguide may be configured to change its shape in order to change the directivity of sound received from a sound source, wherein the sound source is an external sound source.
The external sound sources may be an exhaust pipe of a car, in such cases the chassis of the car is constructed to guide the sound into the room of the driver. Alternatively, the external sound source may be a siren of an emergency car being located behind the acoustic waveguide. The acoustic waveguide may be located at the rear window, and thus allows to focus the siren to the driver's seat.
The embodiments also disclose a method changing the shape of an acoustic waveguide in order to change the directivity of sound emitted by a sound source.
The embodiment described above shows only one possible implementation of the variable waveguide. Other variable waveguides may be used. In general, the flexible acoustic waveguide may consist of elements with different rigidities so that the acoustic waveguide may be able to alter a shape mechanically or electromagnetically. For example, an iris-like lamellar structure is also suitable to dynamically shape the sound emitted by a loudspeaker. Still further, the variable waveguide may be an acoustic lens, the surface of which is made of rubber including some iron threads or wires. When the lens is placed in a magnetic field, the shape of the lens may be deformed depending on the flow of electric current on the threads or wires. The amount of current will give the force moving the shape into the desired form.
In the embodiments described above, the acoustic waveguide is part of a loudspeaker. As an alternative embodiment, an acoustic waveguide is provided which is not part of a loudspeaker, but which is separate device which can be positioned at any place to change the directivity of sound. For example, the acoustic waveguide may be placed close to a loudspeaker, or it may be positioned on a loudspeaker (without being fixed to the loudspeaker). That is, there may be a speaker creating the sound and the acoustic waveguide may focus the sound into any direction.
Still further, the acoustic waveguide may be used to change the directive of sound produced by other external sound sources than a loudspeaker. The external sound sources may for example be an exhaust pipe of a car. In such cases the chassis of the car may be constructed to guide the sound into the room of the driver. Alternatively, the external sound source may be a siren of an emergency vehicle being located behind the acoustic waveguide. The acoustic waveguide may be located at the rear window of a car and may be configured to focus the siren to the driver's seat. The directivity pattern may be based on the type of sound source, for example, if an emergency vehicle located behind the vehicle generates a siren, the acoustic waveguide may be used in a shallow position (see
Note that the present technology can also be configured as described below.
[1] A loudspeaker comprising an acoustic waveguide (210), the acoustic waveguide (210) being configured to change its shape in order to change the directivity of sound emitted by the loudspeaker.
[2] The loudspeaker of [1], wherein the acoustic waveguide consists of adjustable elements.
[3] The loudspeaker of [1] or [2], wherein the acoustic waveguide is configured to change its opening angle.
[4] The loudspeaker of anyone of [1] to [3], wherein the shape of the acoustic waveguide is changed depending on an environment condition or on a listening position.
[5] The loudspeaker of [4], wherein the listening position is obtained by a sensor.
[6] The loudspeaker of anyone of [1] to [5], wherein the acoustic waveguide (210) is configured to change its shape depending on a desired directivity pattern.
[7] The loudspeaker of anyone of [1] to [6], wherein the acoustic waveguide comprises a speaker plate that is configured to support a speaker driver.
[8] The loudspeaker of anyone of [1] to [7], further comprising an adjustment device that is configured to change the shape of the acoustic waveguide.
[9] The loudspeaker of [8], wherein the adjustment device is configured to control the position of a speaker plate (205) and/or speaker driver within a loudspeaker box (201).
[10] The loudspeaker of [8], wherein the adjustment device is configured to change the shape of the acoustic waveguide (210) mechanically.
[11] The loudspeaker of [8], wherein the adjustment device is configured to change the shape of the acoustic waveguide (210) electromagnetically.
[12] The loudspeaker of anyone of [1] to [11], wherein the acoustic waveguide (210) comprises one or more flexible parts (202, 207).
[13] The loudspeaker of anyone of [1] to [12], wherein the acoustic waveguide (210) comprises one or more rigid parts (203, 204).
[14] A method comprising changing the shape of an acoustic waveguide (210) in order to change the directivity of sound emitted by a loudspeaker.
[15] The method of [14], further comprising obtaining a desired directivity and changing the directivity of sound emitted by the loudspeaker to the desired directivity.
[16] An acoustic waveguide (210), the acoustic waveguide (210) being configured to change its shape in order to change the directivity of sound received from a sound source.
[17] The acoustic waveguide of [16], wherein the sound source is an external sound source.
[18] A method comprising changing the shape of an acoustic waveguide (210) in order to change the directivity of sound emitted by a sound source.
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