Acoustic suspension

Last updated March 29, 2024

Acoustic suspension is a loudspeaker cabinet design that uses one or more loudspeaker drivers mounted in a sealed box. Acoustic suspension systems reduce bass distortion which can be caused by stiff suspensions required on drivers used for open cabinet designs.

A compact acoustic suspension loudspeaker was described in 1954 by Edgar Villchur,^[1] and it was brought to commercial production by Villchur and Henry Kloss with the founding of Acoustic Research in Cambridge, Massachusetts.^[2] In 1960, Villchur^[3] reiterated that: The first aim of the acoustic suspension design, over and above uniformity of frequency response, compactness, and extension of response into the low-bass range, is to reduce significantly the level of bass distortion that had previously been tolerated in loudspeakers. This is accomplished by substituting an air-spring for a mechanical one. Subsequently, the theory of closed-box loudspeakers was extensively described by Richard H. Small.^[4]^[5]

Speaker cabinets with acoustic suspension can provide well-controlled bass response, especially in comparison with an equivalently-sized speaker enclosure that has a bass reflex port or vent. The bass vent boosts low-frequency output, but with the tradeoff of introducing phase delay and accuracy problems in reproducing transient signals. Sealed boxes are generally less efficient than a bass-reflex cabinet for the same low-frequency cut-off and cabinet volume,^[6] so a sealed-box speaker cabinet will need more electrical power to deliver the same amount of acoustic low-frequency bass output.

Theory

The acoustic suspension woofer uses the elastic cushion of air within a sealed enclosure to provide the restoring force for the woofer diaphragm. The cushion of air acts like a compression spring. This is in contrast to the stiff physical suspension built into the driver of conventional speakers. Because the air in the cabinet serves to control the woofer's excursion, the physical stiffness of the driver can be reduced. The air suspension provides a more linear restoring force for the woofer's diaphragm, enabling it to oscillate a greater distance (excursion) in a linear fashion. This is a requirement for low distortion and loud reproduction of deep bass by drivers with relatively small cones.^[1]

Even though acoustic suspension cabinets are often called "sealed box" designs, they are not entirely airtight. A small amount of airflow must be allowed so that the speaker can adjust to changes in atmospheric pressure. A semi-porous cone surround allows enough air movement for this purpose. Most Acoustic Research designs used a PVA sealer on the foam surrounds to enable a longer component life and enhance performance. The venting was via the cloth spider and cloth dust caps, and not so much through the cone surround.

Acoustic suspension woofers remain popular in hi-fi systems due to their low distortion. They also have lower group delay at low frequencies compared to bass reflex designs, resulting in better transient response. However, the audibility of this benefit is somewhat contested. As noted by Small,^[6] an analysis performed by Thiele^[7] suggested that the differences among correctly adjusted systems of both types are likely to be inaudible.

In the 2000s, most subwoofers, bass amplifier cabinets and sound reinforcement system speaker cabinets use bass reflex ports, rather than a sealed-box design, in order to obtain more extended low-frequency response and to get higher sound pressure level (SPL). The speaker enclosure designers and their customers view the risk of increased distortion and phase delay as an acceptable price to pay for increased bass output and higher maximum SPL. That said, if one is designing a sound system for a style of music where very accurate, precise bass rhythms are an important part of the genre, one may wish to consider the merits of sealed box woofers and subwoofers.

Acoustic performance

The two most common types of speaker enclosure are acoustic suspension (sometimes called pneumatic suspension) and bass reflex, so they are worth comparing. In both cases, the tuning affects the lower end of the driver's response, but above a certain frequency, the driver itself becomes the dominant factor and the size of the enclosure and ports (if any) become irrelevant.

In general, acoustic suspension systems (driver plus enclosure) have a second-order acoustic (12 dB/octave) roll-off below the −3 dB point. Bass reflex designs have a fourth-order acoustic roll-off (24 dB/octave). Given a driver that is suitable for either type of enclosure, the ideal bass reflex cabinet will be larger, have a lower −3 dB point, but both systems will have equal voltage sensitivity in the passband.

On the right is a simulation of the low-frequency response of a typical 5" mid-woofer, the FaitalPRO 5FE120^[8] mid-woofer generated, obtained using WinISD,^[9] for ideal sealed (yellow) and ported (cyan) enclosure configurations. The ported version adds about an octave of bass extension, dropping the −3 dB point from 100 Hz to 50 Hz, but the tradeoff is that the cabinet size is more than twice as large, 8 litres of interior space versus 3.8 litres. It is also worth noting that: a) above 200 Hz the simulations converge and there is no difference in output, and b) below 32 Hz the sealed enclosure produces more low-frequency output. Thus, a ported cabinet does not provide improved bass output over the entire low-frequency range.

Small^[4] presented the physical efficiency-bandwidth-volume limitation of closed-box system design. By considering the variation in the reference efficiency of the driver operating in the system enclosure, the relationship of maximum reference efficiency to cut-off frequency and enclosure volume for closed-box loudspeaker systems was determined. Subsequently, Small^[10] derived a similar relationship for vented-box loudspeaker systems. When Small^[6] compared these two sets of results, they revealed that the closed-box system has a maximum theoretical value of reference efficiency that is 2.9 dB lower than that of the vented-box system. This suggests that an acoustic suspension loudspeaker with the same enclosure volume and low-frequency −3 dB cut-off as a vented-box system will be up to 2.9 dB less sensitive than its counterpart. Alternatively, if the reference efficiency and cut-off frequency of the two systems is the same, then the enclosure volume of the acoustic suspension loudspeaker will be approximately twice as large as that of the vented system.

The acoustic roll-off of acoustic suspension designs makes them easier to integrate with other drivers with a crossover (passive or active). This makes it an ideal choice for midrange enclosures as well as for satellite speaker and subwoofer systems ^{[ citation needed ]}.

In multi-way speakers

While boxed hi-fi speakers are often described as being acoustic suspension or ported (bass reflex), depending on the absence or presence of a port tube/vent, it is also true that, in typical box speakers with more than two drivers, the midrange drivers between the woofer and tweeter are usually designed as acoustic suspension, with a separate, sealed air-space, even if the woofer itself is not. However, one notable exception to this was the Sonus Faber Stradivari Homage, which used a ported enclosure for the midrange.^[11]

Related Research Articles

A subwoofer is a loudspeaker designed to reproduce low-pitched audio frequencies, known as bass and sub-bass, that are lower in frequency than those which can be (optimally) generated by a woofer. The typical frequency range that is covered by a subwoofer is about 20–200 Hz for consumer products, below 100 Hz for professional live sound, and below 80 Hz in THX-certified systems. Thus, one or more subwoofers are important for high-quality sound reproduction as they are responsible for the lowest two to three octaves of the ten octaves that are audible. This very low-frequency (VLF) range reproduces the natural fundamental tones of the bass drum, electric bass, double bass, grand piano, contrabassoon, tuba, in addition to thunder, gunshots, explosions, etc.

<span class="mw-page-title-main">Loudspeaker</span> Converts an electrical audio signal into a corresponding sound

A loudspeaker is an electroacoustic transducer that converts an electrical audio signal into a corresponding sound. A speaker system, also often simply referred to as a speaker or loudspeaker, comprises one or more such speaker drivers, an enclosure, and electrical connections possibly including a crossover network. The speaker driver can be viewed as a linear motor attached to a diaphragm which couples that motor's movement to motion of air, that is, sound. An audio signal, typically from a microphone, recording, or radio broadcast, is amplified electronically to a power level capable of driving that motor in order to reproduce the sound corresponding to the original unamplified electronic signal. This is thus the opposite function to the microphone; indeed the dynamic speaker driver, by far the most common type, is a linear motor in the same basic configuration as the dynamic microphone which uses such a motor in reverse, as a generator.

Audio crossovers are a type of electronic filter circuitry that splits an audio signal into two or more frequency ranges, so that the signals can be sent to loudspeaker drivers that are designed to operate within different frequency ranges. The crossover filters can be either active or passive. They are often described as two-way or three-way, which indicate, respectively, that the crossover splits a given signal into two frequency ranges or three frequency ranges. Crossovers are used in loudspeaker cabinets, power amplifiers in consumer electronics and pro audio and musical instrument amplifier products. For the latter two markets, crossovers are used in bass amplifiers, keyboard amplifiers, bass and keyboard speaker enclosures and sound reinforcement system equipment.

<span class="mw-page-title-main">Tweeter</span> Type of loudspeaker

A tweeter or treble speaker is a special type of loudspeaker that is designed to produce high audio frequencies, typically deliver high frequencies up to 100 kHz. The name is derived from the high pitched sounds made by some birds (tweets), especially in contrast to the low woofs made by many dogs, after which low-frequency drivers are named (woofers).

<span class="mw-page-title-main">Mid-range speaker</span> Loudspeaker driver

A mid-range speaker is a loudspeaker driver that reproduces sound in the frequency range from 250 to 2000 Hz.

A woofer or bass speaker is a technical term for a loudspeaker driver designed to produce low frequency sounds, typically from 20 Hz up to a few hundred Hz. A subwoofer can take the lower part of this range, normally up to 80 Hz. The name is from the onomatopoeic English word for a dog's deep bark, "woof". The most common design for a woofer is the electrodynamic driver, which typically uses a stiff paper cone, driven by a voice coil surrounded by a magnetic field.

<span class="mw-page-title-main">Electrostatic loudspeaker</span> Sound playback device

An electrostatic loudspeaker (ESL) is a loudspeaker design in which sound is generated by the force exerted on a membrane suspended in an electrostatic field.

Klipsch Audio Technologies is an American loudspeaker company based in Indianapolis, Indiana. Founded in Hope, Arkansas, in 1946 as 'Klipsch and Associates' by Paul W. Klipsch, the company produces loudspeaker drivers and enclosures, as well as complete loudspeakers for high-end, high-fidelity sound systems, public address applications, and personal computers.

<span class="mw-page-title-main">Bass reflex</span> Type of loudspeaker enclosure with improved bass performance

A bass reflex system is a type of loudspeaker enclosure that uses a port (hole) or vent cut into the cabinet and a section of tubing or pipe affixed to the port. This port enables the sound from the rear side of the diaphragm to increase the efficiency of the system at low frequencies as compared to a typical sealed- or closed-box loudspeaker or an infinite baffle mounting.

<span class="mw-page-title-main">Full-range speaker</span> Type of loudspeaker

A full-range loudspeaker drive unit is defined as a driver which reproduces as much of the audible frequency range as possible, within the limitations imposed by the physical constraints of a specific design. The frequency range of these drivers is maximized through the use of a whizzer cone and other means. Most single driver systems, such as those in radios, or small computer speaker designs, cannot reproduce all of the audible frequencies or the entire audible audio range.

<span class="mw-page-title-main">Acoustic Research</span>

Acoustic Research was a Cambridge, Massachusetts-based company that manufactured high-end audio equipment. The brand is now owned by VOXX. Acoustic Research was known for the AR-3 series of speaker systems, which used the 12 in (300 mm) acoustic suspension woofer of the AR-1 with newly designed dome mid-range speaker and high-frequency drivers. AR's line of acoustic suspension speakers were the first loudspeakers with relatively flat response, extended bass, wide dispersion, small size, and reasonable cost. The AR Turntable remains a highly sought vinyl record player.

<span class="mw-page-title-main">Loudspeaker enclosure</span> Acoustical component

A loudspeaker enclosure or loudspeaker cabinet is an enclosure in which speaker drivers and associated electronic hardware, such as crossover circuits and, in some cases, power amplifiers, are mounted. Enclosures may range in design from simple, homemade DIY rectangular particleboard boxes to very complex, expensive computer-designed hi-fi cabinets that incorporate composite materials, internal baffles, horns, bass reflex ports and acoustic insulation. Loudspeaker enclosures range in size from small "bookshelf" speaker cabinets with 4-inch (10 cm) woofers and small tweeters designed for listening to music with a hi-fi system in a private home to huge, heavy subwoofer enclosures with multiple 18-inch (46 cm) or even 21-inch (53 cm) speakers in huge enclosures which are designed for use in stadium concert sound reinforcement systems for rock music concerts.

The isobaric loudspeaker configuration was first introduced by Harry F. Olson in the early 1950s, and refers to systems in which two or more identical woofers operate simultaneously, with a common body of enclosed air adjoining one side of each diaphragm. In practical applications, they are most often used to improve low-end frequency response without increasing cabinet size, though at the expense of cost and weight.

A speaker enclosure using a passive radiator (PR) usually contains an "active loudspeaker", and a passive radiator. The active loudspeaker is a normal driver, and the passive radiator is of similar construction, but without a voice coil and magnet assembly. It is not attached to a voice coil or wired to an electrical circuit or power amplifier. Small and Hurlburt have published the results of research into the analysis and design of passive-radiator loudspeaker systems. The passive-radiator principle was identified as being particularly useful in compact systems where vent realization is difficult or impossible, but it can also be applied satisfactorily to larger systems.

A guitar speaker is a loudspeaker – specifically the driver (transducer) part – designed for use in a combination guitar amplifier of an electric guitar, or for use in a guitar speaker cabinet. Typically these drivers produce only the frequency range relevant to electric guitars, which is similar to a regular woofer type driver, which is approximately 75 Hz — 5 kHz, or for electric bass speakers, down to 41 Hz for regular four-string basses or down to about 30 Hz for five-string instruments.

An acoustic transmission line is the use of a long duct, which acts as an acoustic waveguide and is used to produce or transmit sound in an undistorted manner. Technically it is the acoustic analog of the electrical transmission line, typically conceived as a rigid-walled duct or tube, that is long and thin relative to the wavelength of sound present in it.

A bookshelf loudspeaker is a compact loudspeaker, generally sold for consumer-grade home audio applications as part of a shelf stereo pair or home theater package, that is compact in size and intended to be placed on a raised surface, e.g. a bookshelf.

<span class="mw-page-title-main">Electrodynamic speaker driver</span> Individual transducer that converts an electrical audio signal to sound waves

An electrodynamic speaker driver, often called simply a speaker driver when the type is implicit, is an individual transducer that converts an electrical audio signal to sound waves. While the term is sometimes used interchangeably with the term speaker (loudspeaker), it is usually applied to specialized transducers which reproduce only a portion of the audible frequency range. For high fidelity reproduction of sound, multiple loudspeakers are often mounted in the same enclosure, each reproducing a different part of the audible frequency range. In this case the individual speakers are referred to as drivers and the entire unit is called a loudspeaker. Drivers made for reproducing high audio frequencies are called tweeters, those for middle frequencies are called mid-range drivers, and those for low frequencies are called woofers, while those for very low bass range are subwoofers. Less common types of drivers are supertweeters and rotary woofers.

A transmission line loudspeaker is a loudspeaker enclosure design which uses the topology of an acoustic transmission line within the cabinet, compared to the simpler enclosures used by sealed (closed) or ported designs. Instead of reverberating in a fairly simple damped enclosure, sound from the back of the bass speaker is directed into a long damped pathway within the speaker enclosure, which allows far greater control and use of speaker energy and the resulting sound.

Thomas J. Danley is an American audio engineer, electrical engineer and inventor, the holder of multiple patents for audio transducers, especially high-linearity, high-output professional horn loudspeaker systems. Danley first gained notice in the 1980s with his novel servomotor-driven subwoofer systems used to reproduce very low frequencies in concert tours and theme parks. In 2000 he advanced the implementation of multiple-entry horns in 2000 with several designs led by the SPL-td1, a seven-driver loudspeaker. In 2005, he started a new company, Danley Sound Labs, through which he patented further technologies and produced a wide variety of loudspeaker models based on these technologies.

References

1 2 Villchur, Edgar M. (1954). "Revolutionary Loudspeaker and Enclosure" (PDF). Audio (October): 25–27, 100. Retrieved 2022-05-14.
↑ Schoenherr, Steven E. (2008). "Edgar Villchur and the Acoustic Suspension Loudspeaker". Audio Engineering Society. Retrieved 2022-05-14.
↑ Villchur, Edgar M. (1960). "Another Look at Acoustic Suspension" (PDF). Audio (January): 24–25, 75. Retrieved 2022-05-14.
1 2 Small, R. H. (1972). "Closed-Box Loudspeaker Systems–Part 1: Analysis". Journal of the Audio Engineering Society. 20 (June): 363–372.
↑ Small, R. H. (1973). "Closed-Box Loudspeaker Systems–Part 2: Synthesis". Journal of the Audio Engineering Society. 21 (February): 11–18.
1 2 3 Small, R. H. (1973). "Vented-Box Loudspeaker Systems–Part 2: Large-Signal Analysis". Journal of the Audio Engineering Society. 21 (July/August): 438–444.
↑ Thiele, A. N. (1971). "Loudspeakers in Vented Boxes: Part 2". Journal of the Audio Engineering Society. 19 (June): 471–483.
↑ "FaitalPRO 5FE120 (8Ω)" . Retrieved 2022-05-14.
↑ "WinISD Loudspeaker Simulation Software". Linearteam. Retrieved 2022-05-14.
↑ Small, R. H. (1973). "Vented-Box Loudspeaker Systems–Part 1: Small-Signal Analysis". Journal of the Audio Engineering Society. 21 (June): 363–372.
↑ Atkinson, John (2005). "Sonus Faber Stradivari Homage Loudspeaker Measurements". Stereophile (January). Retrieved 2022-05-14.

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.

[Villchur1954-1] 1 2 Villchur, Edgar M. (1954). "Revolutionary Loudspeaker and Enclosure" (PDF). Audio (October): 25–27, 100. Retrieved 2022-05-14.

[Schoenherr2008-2] Schoenherr, Steven E. (2008). "Edgar Villchur and the Acoustic Suspension Loudspeaker". Audio Engineering Society. Retrieved 2022-05-14.

[Villchur1960-3] Villchur, Edgar M. (1960). "Another Look at Acoustic Suspension" (PDF). Audio (January): 24–25, 75. Retrieved 2022-05-14.

[Small_CBPt1-4] 1 2 Small, R. H. (1972). "Closed-Box Loudspeaker Systems–Part 1: Analysis". Journal of the Audio Engineering Society. 20 (June): 363–372.

[Small_CBPt2-5] Small, R. H. (1973). "Closed-Box Loudspeaker Systems–Part 2: Synthesis". Journal of the Audio Engineering Society. 21 (February): 11–18.

[Small_VBPt2-6] 1 2 3 Small, R. H. (1973). "Vented-Box Loudspeaker Systems–Part 2: Large-Signal Analysis". Journal of the Audio Engineering Society. 21 (July/August): 438–444.

[Thiele_VBPt2-7] Thiele, A. N. (1971). "Loudspeakers in Vented Boxes: Part 2". Journal of the Audio Engineering Society. 19 (June): 471–483.

[FaitalPRO-8] "FaitalPRO 5FE120 (8Ω)" . Retrieved 2022-05-14.

[WinISD-9] "WinISD Loudspeaker Simulation Software". Linearteam. Retrieved 2022-05-14.

[Small_VBPt1-10] Small, R. H. (1973). "Vented-Box Loudspeaker Systems–Part 1: Small-Signal Analysis". Journal of the Audio Engineering Society. 21 (June): 363–372.

[SonusFaber2005-11] Atkinson, John (2005). "Sonus Faber Stradivari Homage Loudspeaker Measurements". Stereophile (January). Retrieved 2022-05-14.

[1]

[2]

[3]

[4]

[5]

[6]

[7]

[8]

[9]

[10]

[11]