Electrical audio signal processing systems and devices – Electro-acoustic audio transducer – Having acoustic wave modifying structure
Reexamination Certificate
2002-04-05
2004-04-27
Kuntz, Curtis (Department: 2643)
Electrical audio signal processing systems and devices
Electro-acoustic audio transducer
Having acoustic wave modifying structure
C455S090300
Reexamination Certificate
active
06728386
ABSTRACT:
The invention relates to an electro-acoustic communications unit such as a mobile telephone and a telephone handset or headset to be held in engagement with a user's ear, but also a headphone.
Particularly in the field of mobile telephones there has been a development toward units, which both weigh less and less and are smaller in size. This makes great demands on designers and manufacturers of electronic and electro-acoustic components, which here comprise microphone and sound generator or receiver transducers. These transducers, too, are available today in smaller dimensions than before.
The preferred electro-acoustic receiver transducers used here are of the electro-dynamic type with a diaphragm for generating acoustic signals in the form of sound with frequencies in the audible range. Traditionally, the transducer is secured to the inner side of the housing wall of the telephone, e.g. by means of an adhesive or a soft rubber fitting, which establishes a sealing. Acoustic connections in the form of apertures in the housing wall transmit sound generated by the transducer to the user's ear and have a carefully designed shape to give the desired acoustic impedance and frequency characteristic, when the telephone is in engagement with the user's ear. Traditionally, the transducer is secured to the inner side of the housing wall in the immediate vicinity of the acoustic connections.
A coil of electrically conductive wire secured to the diaphragm of the transducer drives the diaphragm in response to electric currents in the coil. Sound is thereby emitted from both sides of the diaphragm, whereby the transducer can be considered as a dipole. The preferred transducers are low acoustic impedance sound pressure generators where either side of the diaphragm can be used to generate sound to be transmitted to the user's ear. The principal difference between the sound signals from the two sides of the diaphragm is a phase shift of 180 degrees.
When the diaphragm moves, it emits sound to the user's ear from one side, traditionally referred to as the front side, and for the transducer to operate satisfactorily, it is necessary that an air volume of a certain size is available to the opposite side, traditionally referred to as the rear side, of the diaphragm, since the diaphragm will otherwise be blocked and prevented from moving. If a too small air volume is available to the rear side of the diaphragm, the sensitivity and thereby also the output of the transducer will be reduced at low frequencies. In addition, any leak in the assembly of the housing will, in combination with the small air volume at the rear side of the diaphragm, result in a frequency characteristic having an unfortunate course in the form of a notch. In other words, the diaphragm of the transducer must have a certain working volume of air on both sides of the diaphragm. With the traditional mounting of the speaker transducer closely to the inner side of the housing wall the front side of the diaphragm will have access, through openings in the housing wall, to the air volume in the user's outer ear, and the rear of the diaphragm will have access to an air volume within the housing, or, via openings in the housing, to the ambient air.
Mobile telephones and telephone handsets are tested for their acoustic quality using an ear simulator. The International Telecommunication Union (ITU) recommendation ITU-T P.57 and international standards such as IEC 318 and IEC 711 define ear simulators, all of which are based on the situation of use, where a user holds the telephone or the handset against his or her ear. To ensure reproducible measurements, these standards and recommendations provide guidelines for the mechanical and physical structure of the ear simulator and its acoustic function with a view to simulating a human ear as best as possible, and it is laid down how to carry out a test, including how to engage the telephone with the ear simulator, and in particular the accurate position and orientation of the telephone relative to the ear simulator.
This means that, for any given telephone, and on the basis of the standards, it is possible to define the engagement face of the telephone with the ear simulator in the standardized or recommended test, which, according to the standard or recommendation, will correspond to engagement with a user's ear. In the following, the expression “face for engagement with a user's ear” will therefore be used as a synonym for the engagement of the communications unit with a standardized ear simulator, as these faces are identical according to the foregoing.
Such standardized ear simulators are commercially available e.g. from Brüel & Kjær as type 4157, type 4185, type 4195 and type 4128. The engagement face is typically a circular area with a diameter of 25 mm, the ear simulator having a ring-shaped engagement face with a 25 mm diameter. Inwardly of the ring-shaped engagement face of the ear simulator there is an air volume corresponding to the volume of the human outer ear. This volume is the sound entrance opening of the ear simulator to a microphone by means of which the sound from the telephone may be registered.
The size of the air volume in the sound entrance of the ear simulator, or of the human ear, substantially influences the acoustic loading of the receiver transducer of the communications unit. Any leak to the surroundings may cause a considerable increase in this volume, which gives a significant change in the acoustic loading. Changes in the acoustic loading may cause measurement results, which do not correspond correctly to the acoustic properties of the communications unit, which it is desired to measure. To achieve correct and reproducible test measurements, which are characteristic of the communications unit, the communications unit must therefore, in accordance with the standards, be in a tight fitting relationship with the ring-shaped engagement face of the ear simulator.
In normal use, there will be considerable variations in the degree of the tightness of the engagement of the communications unit with individual users' ears, which gives greater or smaller acoustic leaks to the surroundings. Such variations influence the acoustic loading of the receiver transducer, which in turn, depending on the unit's sensitivity to the acoustic loading impedance, may change the acoustic properties of the communications unit. The user perceives such changes as variations in the sound quality of the communications unit. This is undesirable.
Accordingly, there is a need for communications units which are leak-tolerant, that is units which give a perceived sound quality for the user as well as measurement results on an ear simulator all of which, to the greatest extent possible, are independent of leaks both in the engagement of the unit with the user's ear and with the ear simulator.
WO 98/24214 and WO 00/21330 each disclose such a known mobile telephone using a leak-tolerant construction of the earpiece.
FIG. 1
shows a simplified acoustic equivalent diagram of the acoustic impedances involved in connection with the speaker transducers in one such known telephone. The speaker transducer is shown as a sound pressure generator P with a complex acoustic output impedance Z
1
. L
1
and R
1
represent the acoustic impedances in the path from the “front side” of the speaker transducer through the sound outlet opening to the user's ear, which is represented by the loading acoustic impedance Zear. L
2
and R
2
represent the acoustic impedances in the sound path from the “rear side” of the speaker transducer to an opening to the user's ear, whereby the telephone is made leak-tolerant. L
3
and R
3
represent the acoustic impedance in the leakages of the telephone housing shells, and C
1
represent the inner air volume in the telephone.
In
FIG. 1
, C
1
in parallel with L
1
constitute a parallel resonator on the rear side of the speaker transducer. This parallel resonator has a resonance frequency with a very high impedance. At th
Ensey Brian
Kirk Acoustics A/S
Kuntz Curtis
Oliff & Berridg,e PLC
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