Patent Application
20210142770
The present invention relates to the field of electrical musical instruments of the string type.
This invention relates broadly to electrical musical instruments of the string type. It is typically applicable to an electrical guitar or bass guitar or similar musical instrument having a plurality of stretched strings extending across a body and a neck, between the head of the instrument and a bridge assembly connected to the body, in which the strings are caused to vibrate by plucking or picking same.
In order to derive an output from such an electrical guitar, bass guitar or other similar electrical musical instrument, the instrument is conventionally provided with an electromagnetic pickup comprising a number of magnetic elements (pole pieces) having wound there around a conductive coil. Typically, one such magnetic element is disposed directly beneath each string of the instrument. The strings are constructed of a magnetizable substance, such as steel, and, therefore, become part of the conductive path for the magnetic lines of flux of the pole pieces. Accordingly, when any of the strings are caused to vibrate this causes a disturbance in the magnetic field of the associated pole piece. This has the effect of generating a voltage in the conductive coil which voltage may be suitably amplified and transmitted to a loudspeaker system.
Audio signal processing devices are used to modify an audio signal, for making the tone more interesting to the listener. These audio signal processing devices include, but are not limited to, analog and digital effect pedals, digital multi-effects processors, analog amplifiers, digital amp modelers, digital modelling amplifiers, filters, and equalizers. Each audio signal processing device typically has several control parameters used to shape the tone of the audio signal, as well as on/off switches. These control parameters appear as knobs, sliders, buttons and switches on the control panel of the audio signal processing devices, and may often be controlled by external devices by received analog (e.g. expression pedal) or digital (e.g. midi foot controller) communication signals. It is also well established that musicians desire the ability to manipulate these control parameters and engage/disengage certain effects during a performance. This type of manipulation during a performance is difficult, if the musician constantly moves around on the stage. As an example, when musicians are using stompbox effect pedals or midi foot controllers, they are limited in their movement on the stage, as the sound is controlled by their feet at a fixed location.
The objective of the present invention is to provide a system that solves some or all the above-mentioned problems.
The present invention allows the user of an electrical stringed instrument to control audio signal processing devices, connected to the instrument, by the use of knobs and/or sliders and/or buttons onboard the instrument. This advantage provides the user with freedom to move around the stage during a performance, while still being able to control the sound.
The present invention may allow the user to use existing holes on the electrical stringed instrument, that before installation where used for other onboard controls of the instrument (e.g. tone potentiometer), thereby avoiding the need to change the appearance or construction of the instrument.
Another advantage of the invention is that the communication signal travels along the same cable as the generated audio signal, but using a different conductor, thereby avoiding the need to use more than one cable, and also avoiding any change of the sound and/or impedance of the audio signal generated by the instrument.
A first aspect of the present invention relates to an electrical stringed instrument of the type including a body, a neck having a head, a bridge assembly connected to the body, a plurality of metal strings positioned between the head and the bridge assembly, and one or more pickups positioned on the body and beneath said metal strings; the electrical stringed instrument further comprising:
A second aspect relates to an electrical stringed instrument system comprising:
In the present context, the term “variable impedance unit” may be a variable resistor unit, a variable capacitor unit, or a variable inductor unit. Preferably, the variable impedance unit is a variable resistor unit.
For the most part, electric guitars or electric bass guitars have changed little over the past few decades. To produce sound, electrical guitars or electric bass guitars typically have two or three pickups, which are positioned beneath metal strings. The pickups include one or more electrical coils, which pick up the vibration of the metal strings, in a magnetic field. The electrical output of the coils is output through an audio output circuit electronically connected to the one or more pickups. Typically, electric guitars have an onboard switch for selecting which pickups to be connected. The electrical output of the coils is then amplified, and the amplified signal is reproduced by means of a loud speaker. Typically, each pickup is composed of a single coil of wire having two ends connectable to a guitar audio output circuit.
Electric guitars typically have additional circuitry for processing the electric signals produced by the pickups. The processing circuitry is used to alter different qualities of the tone. To allow the guitar user to adjust the processing of the electronic signal, a guitar typically includes various knobs and buttons for controlling the tone and volume. Hence, in one or more embodiments, the audio output circuit further comprises a processing circuitry.
The core of the invention is the first communication circuit positioned within the electrical stringed instrument. The first communication circuit allows the musician to instruct audio signal processing devices connected, directly or indirectly through a communication unit, to the electrical stringed instrument for processing of the audio signal in accordance with predefined rules. The first communication circuit comprises a variable impedance unit, and is electronically connected to a second channel of a multichannel output jack, i.e. a different channel than the output circuit is connected to. The variable impedance unit may e.g. be a potentiometer, which is a resistor with a movable element positioned by a manual knob or lever. The movable element, typically called a wiper, contacts a resistive strip of material (commonly called the slidewire if made of resistive metal wire) at any point selected by the manual control. The potentiometer's voltage division ratio is strictly a function of resistance and not of the magnitude of applied voltage. Typically, a potentiometer has three terminals. The wiper provides a division of the voltage at two of the terminals controlled by the voltage division ratio. If only two of the terminals are considered and one of them being the wiper terminal, the potentiometer functions as a variable resistor between those two terminals. Hence, a potentiometer functions as a variable resistor set by wiper position. By varying the resistance through the first communication circuit, each individual value or range of values may represent a code for a specific instruction for the audio signal processing device(s) connected. In one or more embodiments, the variable resistor is operably connected to a rotary or slidable knob mounted on the body of the electrical stringed instrument. As an example, the rotary switch or potentiometer may be replacing an existing tone potentiometer inside the electrical stringed instrument.
Alternatively, the variable impedance unit may be a multi-position switch, e.g. rotary switch or slide switch, which switches between multiple circuits with different impedances. The first communication circuit may in one or more embodiments comprise a switch adapted to switch between a primary circuit and a secondary circuit, and wherein the secondary circuit has a relatively higher impedance than the primary circuit. This configuration allows for doubling the number of possible codes. In one or more embodiments, the switch is operably connected to a push button mounted on the body of the electrical stringed instrument, preferably embedded into the variable impedance unit, e.g. a potentiometer with push/push or push/pull switch.
In one or more embodiments, the output circuit and the communication circuit share the same ground wire.
A second communication circuit may be present in a wireless transmitter unit that is configured for wireless communication with an audio signal processing device. Alternatively, the second communication circuit may be present in a communication unit either built separately or built into the chassis of an audio signal processing device. The second communication circuit is configured to measure and convert the impedance of the first communication circuit to a digital representation. The digital representation is forwarded to a processor, such as a microcontroller, configured for communicating with an audio signal processing device by using digital or analog signals. The processor may in one or more embodiments communicate wirelessly with the audio signal processing device. Preferably, the processor is positioned together with the second communication unit in in a wireless transmitter unit that is configured for communicating with an audio signal processing device.
A third aspect relates to an electrical stringed instrument system comprising:
In one or more embodiments, the second communication circuit comprises an operational amplifier.
In one or more embodiments, the second communication circuit comprises an analog-to-digital converter.
In one or more embodiments, the second communication circuit comprises a processor configured for communicating with an audio signal processing device.
The term “analog” as used with respect to electrical signals has its usual meaning in electrical engineering.
The term “digital” has its usual meaning in electrical and computer engineering.
The term “analog-to-digital converter” (ADC) has its usual and ordinary meaning in the field of electrical engineering.
As used in the specification and the appended claims, the singular forms “a”, “an”, and “the” include plural referents unless the context clearly dictates otherwise. Ranges may be expressed herein as from “about” or “approximately” one particular value and/or to “about” or “approximately” another particular value. When such a range is expressed, another embodiment includes from the one particular value and/or to the other particular value. Similarly, when values are expressed as approximations, by use of the antecedent “about”, it will be understood that the particular value forms another embodiment.
It should be noted that embodiments and features described in the context of one of the aspects of the present invention also apply to the other aspects of the invention.
The invention is described in more detail in the following detailed description of a preferred embodiment, with reference to the figures.
The first communication circuit 100 comprises a variable impedance (here shown as a potentiometer) unit 110, and is electronically connected to a second channel 220 of a multichannel output jack 200, i.e. a different channel than the audio output circuit 300 is connected to, which is the first channel 210. The audio output circuit 300 and the communication circuit 100 is shown sharing the same ground wire 230. The potentiometer 110 is here shown with a maximum resistance of 50 kOhm. By varying the resistance through the first communication circuit 100, each individual value or range of values may represent a code for a specific instruction for the audio signal processing device(s) connected thereto. The first communication circuit is also shown comprising a switch 120 adapted to switch between a primary circuit 130 and a secondary circuit 140. The primary circuit 130 is shown comprising a resistor of 6.2 kOhm, while the secondary circuit 140 is shown comprising a resistor of 62 kOhm. This configuration allows for doubling the number of possible codes. The first communication circuit 100 further comprises a capacitor 150 in parallel with the electrical load. The capacitor is here shown with 10 nF. This configuration avoids a noticeable “click or pop” (electrical transient signal) into the common ground terminal each time the switch 120 is activated.
The audio output circuit 300 is here shown with a pickup 310, a tone potentiometer 320, a tone capacitor 330, and a volume potentiometer 340.
In order to receive the instructions via the first communication circuitry 100, a second communication circuit 400 (
The second communication circuit 400 is configured to amplify, measure, and convert the voltage from the first communication circuit 100 to a digital representation that is forwarded to a microcontroller configured for communicating with an audio signal processing device.
In
The communication unit 500 further comprises a multichannel input jack 600 and an audio mono/single-channel output jack 700 electronically connected to one another. The multichannel input jack 600 is electronically connected to the multichannel output jack 200 through a stereo (TRS) cable. This configuration allows for the audio signal to be directly transmitted to the audio mono/single-channel output jack 700, while the communication signal is passed to the second communication circuit 400.
| Number | Date | Country | Kind |
|---|---|---|---|
| PA 2018 00166 | Apr 2018 | DK | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/EP2019/058620 | 4/5/2019 | WO | 00 |
