An optical head assembly for sue with a stringed musical instrument, the vibrations of the strings causing a light beam to be modulated in accordance with the frequency of the vibrating strings. The modulated light output, produced by the relative motion between two adjacent grates, is coupled to a device with converts the modulated light beam to a corresponding modulated electrical signal which, in turn, is coupled to an amplifier associated with the instrument.

A saddle for a stringed musical instrument comprising a body having at least one member with a first and second section. The first section, in cross section has opposite ends, and a geometry conforming to the geometry of a slot in a bridge plate and a width approximately equal in dimension to the width of the slot so the opposite ends of the first section tightly fit into the slot when the first section is inserted therein. The second section having a width substantially wider than the width of the first section and having two lateral sides, in cross section, extending from the opposite ends of the first section to form, in combination with the first section, a right-side up T fitting such that the saddle possesses a substantially higher resistance to bending forces from tension in the strings in the musical instrument as compared conventional saddle structures.

An optical head assembly for use with a stringed musical instrument, the vibrations of the strings causing a light beam to be modulated in accordance with the frequency of the vibrating strings. The modulated light output, produced by the relative motion between two adjacent grates, is coupled to a device with converts the modulated light beam to a corresponding modulated electrical signal which, in turn, is coupled to an amplifier associated with the instrument.

A sound post assembly for a musical instrument, comprising two or more mechanically movable parts that allow for a length adjustment of the sound post assembly and one or more electrical components. In an example embodiment, the electrical components are configured to electrically measure the force exerted by the sound post on the upper and lower walls of the instrument's sound box. In some embodiments, the electrical components may operate to mechanically change the length of the sound post assembly through an electrical actuator, such as a piezo-electric actuator or an electro-magnetic motor. Also disclosed are example safety mechanisms and methods of wiring and interfacing said sound post assembly with a control unit.

An accessory for modifying sound output of a musical instrument. The body of the instrument has a soundboard. The accessory includes a sound sensor, an actuator, a fastener, and a controller. The sound sensor engages the body and senses vibration of the body representing the sound output of the musical instrument. The actuator engages the soundboard and deforms the soundboard of the musical instrument so as to modify the sound output of the musical instrument. The sound sensor is preferably arranged distally to the actuator. The fastener engages the accessory to the musical instrument, to locate the actuator against the soundboard of the musical instrument. The controller is connected to the actuator and the sound sensor for receiving and analysing the sound output sensed by the sound sensor, and controlling the actuator in dependence on the sound output sensed by the sound sensor.

This invention eliminates most mechanical switching in vibrational pickup circuits by using variable gains to combine signals of sensors in differential amplifiers as J1 humbucking pairs for J>1 number of sensors, with the sensors matched to produce the same level and phase of unwanted hum from external sources. It can also combine J>1 number of matched sensors with K>1 number of dissimilar sensors which are matched only to each other in the same manner. This produces not only all the possible mechanically switched humbucking signals, but all the continuously-varying combinations of humbucking signals in between.

In several embodiments of the invention, a pickup saddle for a stringed instrument includes a U-shaped top cap having two legs, each leg including a receiving portion configured to mate with a mating portion of a base, a base fitted to the interior of the top cap, where two surfaces of the base include a mating portion matching with and affixed to a receiving portion of the top cap, a piezoelectric transducer placed between the top cap and the base and electrically connected to the base, a positive wire connected to the piezoelectric transducer, and a ground wire connected to the base.

An electric musical instrument includes a body and a resonant stack. The resonant stack includes a bridge having a bridge mass and at least a first spring having a first spring constant, in which the first spring is positioned between the bridge and the body. The resonant stack has at least one resonant frequency that is dependent on the bridge mass and the first spring constant. The electric musical instrument includes a plurality of strings that extend across at least a portion of the body, in which each string has a vibrating length defined at least in part by the bridge. The electric musical instrument includes at least a first pickup device to detect vibrations of the strings and generate a first pickup signal, and at least a second pickup device to detect movements of the bridge and generate a second pickup signal.

An electronic sensor device for detecting the vibration related to an amplification system within stringed musical instruments. The described structure is detachably mounted below the saddle. It comprises several central piezoelectric elements, several metal capped poles, and each metal capped pole consists of an integrally formed pole and cap, from top to bottom. The top end of the pole extends through a matching positioning hole into the saddle slot and touches the bottom of the saddle. The bottom end of the cap accurately captures the top of the central piezoelectric element, and the top ring of the cap is closely pressed up to the bridge plate. The invention provides an electronic sensor device for detecting the vibration related to an amplification system within stringed musical instruments, which is easy to install and is easily uninstalled. By applying mass on the non-sensing side of piezoelectric element assembly, the electro-acoustic amplification performance of the instruments is greatly enhanced, as it is firmly coupled to the stringed instruments, therefore improving the sensing efficiency, in providing better output and tone that is closer to the original acoustic.

A musical instrument having a hollow or semi-hollow body and a sound board, representing either the anatomical front surface or the anatomical rear surface of the hollow body, or with the front surface and the rear surface both functioning as a sound board for the musical instrument and having at least one tuned sound port located in either the front and/or rear sound board of the musical instrument through which sound can exist with the tuned sound port comprising a hollow member adapted to be inserted through a hole formed in one or both of the sound boards and having a central opening of predetermined geometry and a length extending a fixed distance from the sound board into the interior of the musical instrument of between 5% and 95% of the distance between the front rear sound surfaces of the musical instrument. The musical instrument is preferably a stringed musical instrument which may include a plurality of panels extending between the front and rear sound boards for enhancing the structural support of the musical instrument and for funneling sound through the tuned sound ports or alternatively the musical instrument may include a plurality of panels extending between the front and rear surfaces without a tuned sound port.