Bridge (instrument)
A bridge is a device that supports the
Explanation
Most stringed instruments produce sound through the application of energy to the strings, which sets them into vibratory motion, creating musical sounds. The strings alone, however, produce only a faint sound because they displace only a small volume of air as they vibrate. Consequently, the sound of the strings alone requires impedance matching to the surrounding air by transmitting their vibrations to a larger surface area that displaces a larger volume of air (and thus produces louder sounds). This calls for an arrangement that lets the strings vibrate freely, but also conducts those vibrations efficiently to the larger surface. A bridge is the customary means for accomplishing this. The bridge conducts the vibrations of the strings to a hollowed out chamber in a number of instruments (e.g., violin family, acoustic guitar, balalaika).
On
Positioning
Typically, the bridge is perpendicular to the strings and larger surface (which are roughly parallel to one another) with the
- Wood, as the top "plate" piece of wood of a guitar or violin
- Calfskin or plastic under tension, as with a drum, as on the head of a banjo
- Metal, as on certain types of resophonic fretted instruments
- Virtually any material that can vibrate sympathetically with the strings. Some upright basses are made of aluminium. Some violin familyinstruments are made of carbon fibre.
Construction
Bridges may consist of a single piece of material, most commonly wood for violins and acoustic guitars, that fits between the strings and the resonant surface. Alternatively, a bridge may consist of multiple parts. One common form is a bridge with a separate bearing surface, called a saddle, that supports the strings. This is often of a material harder than the bridge itself, such as bone, ivory, high-density plastic, or metal. Some acoustic guitar bridges have multiple materials, such as a bridge support and "feet" made of wood and a plastic or bone "ridge" where the strings are positioned against.
A classical guitar saddle sits loosely in the hardwood bridge, held in place by string tension. Strings pass through shallow grooves in the saddle, at least for the treble strings, which prevents them moving around during hard playing.
Yet another type of multi-part bridge is common on instruments with a curved sound plate, such as an arch-top
Bridge pin
Bridge pins or string pegs are used on some musical instruments to locate the
In pianos the pins are set precisely in line with the edges of the notches of the bridge. The precise and firm setting of the pins is a critical element of the piano's quality. Loose or inaccurate pinning commonly produces false beats and tonal irregularities.
In harpsichords there tends to be a significant distance instead. This enables control of sustain and tone in harpsichord design (as per external link).
For the larger, deeper violin family instruments, the bridge pin may have an extendable "endpin" which raises the instrument up.
Tie block
The bridge of the classical guitar does not use bridge pins. In this instrument the strings are tied to the part of the bridge called the tie block. Strings run over the bridge saddle, through drilled holes in the base of the tie block, loop over the top of the tie block, loop under the strings and are tied on. A variation called the 18 hole bridge[1] uses three holes per string and eliminates the need to tie the string down.
Operation
The bridge must transfer vibration of the strings to the sound board or other amplifying surface. As the strings are set in motion (whether by picking or strumming, as with guitars, by bowing, with violin family instruments, or by striking them, as with pianos), the bridge bends to and fro along the string direction at twice the rate of the string vibration. This causes the sounding board to vibrate at the same frequency as the string producing a wave-like motion and an audible sound. Instruments typically use a hollow, resonant chamber (violin bodies, guitar bodies) or a pickup and an amplifier/speaker to make this sound loud enough for the performers and audience to hear.
Bridges are designed to hold the strings at a suitable height above the fingerboard of the instrument. The ideal bridge height creates sufficient angularity in the string to create enough down force to drive the top, but places the strings sufficiently close to the fingerboard to make noting the strings easy. Bridge height may be fixed or alterable. Most violin-family bridges are carved by a luthier; as such, the height can be changed, but only by taking the violin into the repair shop. Many acoustic guitars have fixed bridges that a regular player cannot adjust. Some jazz guitars have a "floating bridge" which the player can reposition themself for different sounds and tones.
In addition to supporting the strings and transmitting their vibrations, the bridge also controls the spacing between strings with shallow grooves cut in the bridge or its saddle. The strings sit in those grooves, thus are held in their proper lateral position. The nut, at the opposite end of the instrument from the bridge or tailpiece (typically where the head holding the tuning pegs joins the fingerboard), serves a similar string-spacing function. As well, like the bridge, the nut's height determines how high the strings are from the fingerboard.
Electric guitar bridges
Bridges for electric guitars can be divided into two main groups, "
Non-vibrato bridges supply an anchoring point for the strings but provide no active control over string tension or pitch. That is, there is no "whammy bar" or lever. A small group of vibrato bridges have an extended tail (also called "longtail"). These guitars have more reverb and sustain in their sound, because of the string resonance behind the bridge. The Fender Jaguar is an example of such a guitar.
All bridges have advantages, and disadvantages, depending on the playing style, but, in general, a non-vibrato bridge is thought to provide better tuning stability and a solid contact between the guitar body and the strings. A whammy bar bridge is important in some heavy metal music styles, such as shred guitar.
Vibrato bridges
Generally, the more contact the bridge has with the body (i.e., the lower the position), the better the sound transfer is into the body. A "warmer" sound with increased sustain is the result. Vibrato bridges usually must be suspended in some way, which reduces contact. Most vibrato system designs use a group of springs in the guitar body, which oppose the tension of the strings. Some players feel that the vibration of the springs affects resonance in a way that makes the guitar sound better, but others disagree. Many electric guitar playing styles require a vibrato system, either "locking" or "non-locking".
Non-locking tremolo/vibrato systems
Non-locking (or vintage) tremolos are the bridges found on guitars manufactured prior to the advent of the
Also, keeping a guitar with a non-locking tremolo in tune can be difficult. The most common types of non-locking tremolos are the "Synchronized Tremolo" type and an almost endless stream of copies. The Bigsby vibrato tailpiece is another option.
Locking tremolo/vibrato systems
A locking tremolo uses a bridge that has a small clamp in each saddle to hold the strings in place (usually adjusted with an
Non-Tremolo/vibrato bridges
It is generally thought[by whom?] that non-tremolo bridges offer better transfer of string vibration into the body. This is due to direct contact of the bridge to the guitar's body. These bridges bolt directly to the guitar body. Assuming the bridge is of good quality[clarification needed], it limits longitudinal string movement, providing tuning stability. The improved transfer of string vibration into the body has an effect on the sound, so guitars with this type of bridge have different characteristics than those with tremolos, even when removed. There are no springs in the body or a cavity to accommodate them, which also affects resonance.
See also
- Fingerboard
- Electronic tuner Some tuners attach to the bridge of an instrument.
- Nut (string instrument)
References
- ISBN 978-1-7341256-0-3.
- ^ Owens, Jeff (2016-11-01). "Pitch or Volume? The Difference Between Tremolo and Vibrato". www.fender.com. Retrieved 2019-03-10.
- A.B.Wood (Admiralty Research Laboratory), A Textbook of Sound, Publ Bell, 3rd ed. 1955. No ISBN found.