Patent Application
20090304193
The present invention generally relates to devices for testing audio equipment and, more specifically, to devices for testing the operability of vehicle audio speakers.
Vehicles typically include a plurality of factory-installed audio speakers positioned throughout the passenger compartment. The audio speakers are generally connected to an audio head unit by wires and connectors concealed between the interior finished surfaces of the vehicle and the body of the vehicle. During assembly of the vehicle these wires may become damaged, pinched or disconnected from the audio speaker or the audio head unit thereby rendering the audio speaker inoperable. Vehicle manufacturers incur significant warranty costs when a new vehicle is delivered with inoperable audio speakers. To reduce these warranty costs it is necessary to test the operability of the audio speakers prior to the vehicle leaving the assembly plant.
However, testing the operability of audio speakers while the vehicle is being assembled presents a unique set of challenges. Specifically, the vehicle assembly plant has a significant amount of background and environmental noise at a particularly high volume. This background and environmental noise makes it difficult to isolate and/or detect the audible noise produced by the audio speaker with conventional audio detectors or detection equipment.
Accordingly, a need exists for an alternative testing devices for testing the operability of audio speakers during the assembly of a vehicle.
In one embodiment, a device for testing the operability of an audio speaker includes a housing, a unidirectional microphone and a display. The underside of the housing may include a recessed area. The unidirectional microphone is positioned and oriented in the recessed area such that the unidirectional microphone is recessed from the underside of the housing. The display is positioned on the housing such that the display is visible when the testing device is placed proximate an audio speaker with the underside of the housing facing the audio speaker. The display may include at least one visual indicator operatively coupled to the unidirectional microphone such that, when the unidirectional microphone is receiving an acoustic signal, the at least one visual indicator is activated.
In another embodiment, a method for testing the operability of an audio speaker located in a vehicle during the assembly of the vehicle includes positioning a testing device comprising a housing, a unidirectional microphone and a plurality of LEDs directly against a speaker cover oriented over the audio speaker. The housing may include a top and an underside. The underside of the housing may include a recessed area. The unidirectional microphone may be located on the underside of the housing and positioned and oriented in the recessed area such that, when the testing device is placed proximate the audio speaker with the underside of the testing device facing the audio speaker, the unidirectional microphone is recessed from the underside of the housing and oriented towards the audio speaker. The plurality of LEDs may be operatively coupled to the unidirectional microphone such that, when the unidirectional microphone is receiving an acoustic signal, at least one LED is illuminated. The housing may be enclosed in a rubber case, the rubber case having an opening proximate the recessed area. The testing device may be positioned against the speaker cover such that the underside of the housing is facing the speaker cover, the rubber case is in direct contact with the speaker cover thereby preventing the testing device from damaging the speaker cover and the unidirectional microphone is directed towards the audio speaker such that any acoustic signal received by the unidirectional microphone is substantially from the audio speaker. An audio head unit operatively associated with the audio speaker may then be turned on such that, if the audio speaker and the audio head unit are properly connected and operable, an acoustic signal will emanate from the audio speaker. The LEDs on the testing device are observed to determine if an acoustic signal is emanating from the audio speaker.
In yet another embodiment, a testing device for testing the operability of an audio speaker, includes a housing, a microphone and a display. The housing may include a top and an underside, wherein the underside of the housing has a recessed area and a raised rib extending around the recessed area. The microphone may be located on the underside of the housing and positioned in the recessed area such that, when the testing device is placed proximate the audio speaker with the underside of the testing device facing the audio speaker, the microphone is recessed from the underside of the housing and oriented towards the audio speaker. The display may be positioned on the housing such that the display is visible when the testing device is placed proximate the audio speaker with the underside of the housing facing the audio speaker. The display may include at least one LED and is operatively coupled to the microphone such that, when the unidirectional microphone is receiving an acoustic signal, the at least one LED is illuminated.
The embodiments set forth in the drawings are illustrative and exemplary in nature and not intended to limit the inventions defined by the claims. The following detailed description of the illustrative embodiments can be understood when read in conjunction with the following drawings, where like structure is indicated with like reference numerals and in which:
Referring to
The housing 101 may be constructed from any suitable material including, without limitation, polymers, composites, metals and the like. In one embodiment, the housing 101 may comprise a coating, such as a no-scratch coating, such that, when the testing device 100 comes in contact with the interior finishes of a vehicle, the testing device 100 does not scratch or otherwise damage the interior finishes. For example, the coating may comprise a polymer or rubber coating. Alternatively, the coating may comprises a rubber case or sheath in which the housing 101 is inserted. The case or sheath may have various openings through which the microphone 116, display panel 118 and various other testing device controls extend.
The microphone 116 may be positioned on the underside 104 of the housing 101. In one embodiment, as shown in
It should be understood that, while the recessed area 114 is generally depicted in
The microphone 116 may comprise a unidirectional microphone which may be positioned and oriented in the housing 101 to receive an acoustic signal from a specific, pre-determined direction. More specifically, the unidirectional microphone may be positioned and oriented in the housing 101 such that, when the testing device is positioned over an audio speaker, the an acoustic signal received from the microphone is substantially from the audio speaker and not from the surrounding environment. By positioning the unidirectional microphone in this manner ambient or background sound (e.g., any acoustic signal not emanating from the audio speaker) may be reduced and/or eliminated thereby providing a more accurate determination of the operability of the audio speaker.
In one embodiment, the underside 104 of the housing 101 may also contain an isolation member 112 which generally surrounds the recessed area 114 and the microphone 116. The isolation member may generally comprise a raised rib extending circumferentially around the microphone 116. When the testing device is placed proximate an audio speaker, such as when the underside of the testing apparatus is placed in direct contact with the speaker cover of an audio speaker, the isolation member forms a barrier extending circumferentially around the microphone which substantially blocks ambient or background sound (e.g., any acoustic signal not emanating from the audio speaker) from being received by the microphone thereby providing a more accurate determination as to the operability of the audio speaker. Further, the isolation member 112 may also protect the microphone 116 from damage by increasing the distance between the microphone 116 and any surface on which the testing device 100 is positioned.
While
In one embodiment, the isolation member 112 may be integrally formed with the housing 101. In another embodiment, the isolation member 112 may comprise a sound dampening material affixed to the underside 104 of the housing 101 with an epoxy, glue or other adhesive. The sound dampening material may comprise felt, foam rubber, rubber or any suitable sound dampening material. In yet another embodiment, when the housing 101 is enclosed in a rubber or polymer case or sheath as described hereinabove, the isolation member 112 may be integrally formed with the case or sheath. In one embodiment, the material from which the isolation member 112 is formed may be selected such that, when the testing unit 100 is positioned on a sloped or inclined surface, the testing unit 100 does not slide with respect to the surface.
The testing unit 100 may also include a display 118 as shown in
The display 118 may be operatively connected to the microphone 116 (as will be discussed further herein) such that, when an acoustic signal is received by the microphone 116, the display 118 visually indicates that the microphone 116 is receiving an acoustic signal. Accordingly, the display 118 may comprise one or more visual indicators including, without limitation, LED indicators and the like. In the embodiment shown in
In another embodiment, when the display 118 comprises a plurality of visual indicators, the number of visual indicators which are illuminated when an acoustic signal is received by the microphone 116 is proportional to the level or intensity of the acoustic signal received by the microphone 116. For example, when the display 118 comprises an LED display bar as depicted in
Referring now to the circuit diagram shown in
In operation, the microphone 116 receives an acoustic signal (e.g., sound) and converts the acoustic signal to an electrical signal which is passed to the microphone operational amplifier 212. The microphone operational amplifier 212 amplifies the electrical signal from the microphone 216 and relays the signal to the display driver 210. In one embodiment, when the display driver 210 receives an amplified signal from the microphone operational amplifier 212, the display driver 210 illuminates all the LEDs associated with the display 118. In another embodiment, when the display driver 210 receives an amplified signal from the microphone operational amplifier 212, the number of LEDs in the display 118 illuminated by the display driver 210 is in proportion to the voltage of the signal received by the display driver 210 from the microphone operational amplifier 212. In this embodiment, the voltage of the signal output from the microphone operational amplifier 212 may be proportional to the acoustic signal received by the microphone 116. Accordingly, the number of LEDs illuminated in the display 118 will be proportional to the acoustic signal received by the microphone 116.
While the circuit diagram shown in
Referring now to
While the testing device 100 may be shown in
With the testing device 100 in place on the speaker cover 300, the audio head unit of the vehicle may be turned on such that an acoustic signal emanates from the audio speaker. When the testing device 100 receives an acoustic signal emanating from the audio speaker, the display 118 of the testing device 100 is illuminated thereby indicating that the audio speaker located beneath the speaker cover 300 is operating properly. If no acoustic signal emanates from the audio speaker, the display 118 of the testing device 100 does not illuminate thereby indicating that the audio speaker is not functioning properly and that the audio speaker, the audio head unit, and/or the connection between the audio speaker and the audio head unit is/are in need of repair and or replacement.
In another embodiment, in addition to checking the basic operability of the audio speaker and/or the audio head unit, the testing device 100 may also be used to assess the strength of the signal received by the audio speaker from the audio head unit. In this embodiment, the testing device 100 is calibrated to illuminate a specified number of LEDs for an acoustic signal of a given level or intensity by adjusting the sensitivity of the device. The testing device 100 is then placed proximate the audio speaker, as described above, and the audio head unit is set to send a signal to the audio head unit corresponding to the given acoustic signal intensity. If the specified number of LEDs are illuminated on the display 118 of the testing device 100, then the audio head unit is functioning properly. If the number of LEDs is more or less than the specified number of LEDs, then the audio head unit may need to be adjusted and/or repaired.
It should now be understood that the testing device described herein may be used to verify the operability of an audio speaker and, more particularly, audio speakers and related components installed in a vehicle during assembly of the vehicle. The use of a directional microphone and/or isolation member assists in blocking or mitigating the ambient or background noise commonly found in a vehicle assembly plant and which may otherwise adversely effect the performance of the testing device.
Further, the testing device described herein is compact and easy for a user to carry and operate and the display of the testing device provides an instantaneous indication of the operability of the audio speaker thus improving the overall efficiency of the audio speaker testing process.
While reference is made herein to using the testing device to test audio speakers located in a vehicle during assembly of the vehicle, it should be understood that the testing device described herein may also be used to test any audio speaker under conditions where it is necessary to isolate the testing device from ambient or background noise and thereby improve the results obtained by the testing device.
While particular embodiments and aspects of the present invention have been illustrated and described herein, various other changes and modifications can be made without departing from the spirit and scope of the invention. Moreover, although various inventive aspects have been described herein, such aspects need not be utilized in combination. It is therefore intended that the appended claims cover all such changes and modifications that are within the scope of this invention.
