Transducer for sensing body sounds

Electrical audio signal processing systems and devices – Stethoscopes – electrical

Reexamination Certificate

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C600S528000, C600S529000

Reexamination Certificate

active

06661897

ABSTRACT:

FIELD OF THE INVENTION
The present invention relates to sensing body sounds, and more specifically, to acoustic-to-electrical transducers used for sensing body sounds, especially in stethoscopes.
BACKGROUND OF THE INVENTION
Stethoscopes are widely used by health professionals to aid in the detection of body sounds. The procedures for listening to and analyzing body sounds, called auscultation, is often difficult to learn due to the typically low sound volume produced by an acoustic stethoscope. Electronic stethoscopes have been developed which amplify the faint sounds from the body. However, such devices suffer from distortion and ambient noise pickup. The distortion and noise are largely due to the performance of the acoustic-to-electrical transducers, which differ in operation from the mechanical diaphragms used in acoustic stethoscopes.
Acoustic stethoscopes have been the reference by which stethoscope sound quality has been measured. Acoustic stethoscopes convert the movement of the stethoscope diaphragm into air pressure, which is directly transferred via tubing to the listener's ears. The listener therefore hears the direct vibration of the diaphragm via air tubes.
Existing electrical stethoscope transducers are typically one of three types: (1) microphones mounted behind the stethoscope diaphragm, or (2) piezoelectric sensors mounted on, or physically connected to, the diaphragm, or (3) other sensors which operate on the basis of electro-mechanical sensing of vibration via a sensing mechanism in mechanical contact with the diaphragm placed against the body
Microphones mounted behind the stethoscope diaphragm pick up the sound pressure created by the stethoscope diaphragm, and convert it to electrical signals. The microphone itself has a diaphragm, and thus the acoustic transmission path comprises stethoscope diaphragm, air inside the stethoscope housing, and finally microphone diaphragm. The existence of two diaphragms, and the intervening air path, result in excess ambient noise pickup by the microphone, as well as inefficient acoustic energy transfer. Various inventions have been disclosed to counteract this fundamentally inferior sensing technique, such as adaptive noise canceling, and various mechanical isolation mountings for the microphone. However, these methods are often just compensations for the fundamental inadequacies of the acoustic-to-electrical transducers.
The piezo-electric sensors operate on a somewhat different principle than merely sensing diaphragm sound pressure. Piezo-electric sensors produce electrical energy by deformation of a crystal substance. In one case, the diaphragm motion deforms a piezoelectric sensor crystal which is mechanically coupled to the stethoscope diaphragm, and an electrical signal results. The problem with this sensor is that the conversion mechanism produces signal distortion compared with sensing the pure motion of the diaphragm. The resulting sound is thus somewhat different in tone, and distorted compared with an acoustic stethoscope.
Other sensors are designed to transfer mechanical movement of the diaphragm, or other surface in contact with the body, via some fluid or physical coupling to an electromechanical sensing element. The problem with such sensors is that they restrict the mechanical movement of the diaphragm by imposing a mechanical load on the diaphragm. Acoustic stethoscopes have diaphragms that are constrained at the edges or circumference, but do not have any constraints within their surface area, other than the inherent elasticity imposed by the diaphragm material itself. Thus placing sensors in contact with the diaphragm restrict its movement and change its acoustic properties and hence the sounds quality capacitive acoustic sensors have been disclosed and are in common use in high performance microphones and hydrophones. A capacitive microphone utilizes the variable capacitance produced by a vibrating capacitive plate to perform acoustic-to-electrical conversion. Dynamic microphones that operate on the principle of a changing magnetic field are well-known. These devices typically operate by having a coil move through a static magnetic field, thereby inducing a current in the coil. Optical microphones have been disclosed, which operate on the principle that a reflected light beam is modified by the movement of a diaphragm.
A capacitive, magnetic or optical microphone placed behind a stethoscope diaphragm would suffer from the same ambient noise and energy transfer problems that occur with any other microphone mounted behind a stethoscope diaphragm. A unique aspect of the present invention is that the stethoscope diaphragm is the only diaphragm in the structure, whereas existing microphone-based solutions comprise a stethoscope diaphragm plus a microphone diaphragm, resulting in the inefficient noise-prone methods described previously.
The present invention provides both direct sensing of the diaphragm movement, with the diaphragm making direct contact with the body, while at the same time avoids any change in acoustic characteristics of the diaphragm compared with that of an acoustic stethoscope, since the sensing means does not mechanically load the diaphragm. This results in efficient energy transfer, and hence reduced noise, with acoustic characteristics that are faithful to that of an acoustic stethoscope diaphragm. The present invention discloses three basic embodiments: (a) A capacitive sensor, (b) a magnetic sensor, and (c) an optical sensor.
SUMMARY OF THE INVENTION
According to one aspect of the invention, there is provided a acoustic-to-electrical transducer for detecting body sounds, the transducer comprising (a) a capacitive to electrical conversion means, or (b) a magnetic to electrical conversion means, or (c) an optical (light) to electrical conversion means.
The capacitive to electrical conversion means comprises: a diaphragm having an electrically conductive surface, the diaphragm being mounted in a housing such that the diaphragm can contact a body for body sound detection; a conductive plate substantially parallel to the diaphragm, mounted within the housing, the conductive plate being positioned behind and spaced from the diaphragm to allow diaphragm motion, the diaphragm and conductive plate being connected in the form of an electrical capacitance to electrical circuitry; and a capacitance-to-electrical signal conversion means to convert capacitance changes to electrical signals.
The magnetic to electrical conversion means comprises a diaphragm that is placed against the body, the diaphragm having magnetic elements such as a permanent magnetic surface or electrically-induced magnetic field due to a wire or printed-circuit coil, so that a magnetic field is set up that is subject to change by motion of the diaphragm. The conversion means additionally comprises a magnetic field sensing means to convert the magnetic field changes to an electrical signal. Thus diaphragm motion affects the magnetic field, the magnetic field changes an electrical signal, and acoustic to electrical conversion is achieved.
The optical to electrical conversion means comprises a diaphragm placed against the body, with a light path that can be modified by motion of the diaphragm. A light source transmits visible or infrared light to the diaphragm. The diaphragm reflects the light, which is then detected by an optical detector, and changes in the reflected light signal due to diaphragm motion are then converted to an electrical signal. Another embodiment of the optical method is transmissive, with the light beam passing through an optical element that moves with the diaphragm, the motion of the optical element causing changes in the light beam received by the optical detector.
The present invention provides an acoustic-to-electrical transducer means for the detection of body sounds, such as for use in a stethoscope. The term “body” in this specification may include living or inanimate bodies. Living bodies may include humans and animals, while inanimate bodies may include, by example only, buildings, machin

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