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Another use of crossovers is ). OVERVIEW Butterworth and Linkwitz-Riley crossover filters. The summed output of the Butterworth filters has a +3dB peak at the crossover frequency.]] An ideal audio crossover would split the incoming audio signal into separate bands that do not overlap or interact and which, when added together, output the signal unchanged in both Frequency , relative levels, and Phase Response . This behavior cannot be achieved in practice, but can be approximated. Just which is the best approximation is a matter of lively debate. Many different crossover types are used, but they generally fall under one of the classifications provided below. CROSSOVER CLASSIFICATION Classification based on the number of filter sections In loudspeaker specifications, one often sees a speaker classified as an "N-way" speaker. N is a positive whole number greater than 1, and it indicates the number of filter sections. A 2-way crossover consists of a Low-pass and a High-pass filter. A 3-way crossover is constructed as a combination of Low-pass , Band-pass and High-pass filters (LPF, BPF and HPF respectively). The BPF section is in turn a combination of HPF and LPF sections. 4 (or more) way crossovers are not very common in speaker design, primarily due to the complexity involved, which is not generally justified by better acoustic performance. Recently, a number of manufacturers have developed what is often called "N.5-way" crossover techniques. This usually indicates the addition of an extra bass driver (commonly termed a Subwoofer when limited to only low frequencies below all other drivers) with a crossover designed such that it augments the bass response or compensates for cabinet Diffraction effects. ''Remark: Filter sections mentioned here is not to be confused with the individual 2-pole filter sections that a higher order filter consists of.'' Classification based on components Crossovers can also be classified based on the design approach (ie, more or less, the type of components used). Passive crossovers A passive crossover is made entirely of passive components, arranged most commonly in a Cauer topology to achieve a Butterworth Filter . Passive filters use both non reactive Resistor s, and reactive components such as Capacitor s and Inductor s. Very high performance passive crossovers may be more expensive than active crossovers. The use of non inductive resistors and special capacitor components adds significant cost, although they have some sonic benefits. Polypropylene and Metalizied Polyester foil, and paper- Electrolytic capacitors are common. Inductors may have air cores, powdered metal cores, Ferrite cores, or laminated Silicon steel cores, and most are wound with insulated Copper 'magnet wire'. Some passive networks include devices such as Fuses , PTC devices, bulbs or Circuit Breakers , to protect the loudspeaker drivers from accidental overpowering. Modern passive crossovers are increasingly also including equalization networks (similar to Zobel Network s) that compensate for the changes in impedance with frequency inherent in virtually all speakers. The issue is complex as part of the change in impedance is due to acoustic loading changes across a driver's passband. On the negative side,
Active crossovers An active crossover contains active components (ie, those with gain) in its filters. In recent years, the most commonly used active device is an Op-amp ; active crossovers are operated at levels suited to power amplifier inputs in contrast to passive crossovers which operate after the power amplifier's output, at high Voltage and Current levels. On the other hand, all circuits with Gain introduce noise, and in this case, unless carefully designed, the Noise will be amplified by the power amplifiers, perhaps unacceptably. Active crossovers always require the use of power amplifiers for each output band. Thus a 2-way active crossover needs two amplifiers — one each for the woofer and tweeter. This means that an active crossover based system will often cost more than a passive crossover based system, although none of the amplifiers needs to provide output as high as for an equivalent sound level full-frequency, power amplifier, which reduces cost. Generally, active crossovers require use of tweeter protection (typically a small capacitor) since the tweeter is now directly connected to an amplifier and may be damaged due to DC in that output, or a short thump produced when an amplifier turns on or off. The cost and complication disadvantages of active crossovers are offset by the following gains:
Mechanical crossovers See Also: Full-range This crossover type is mechanical and uses the properties of the materials in a driver diaphragm to achieve the necessary filtering. Such crossovers are commonly found in Full-range speakers which are designed to cover as much of the audio band as possible. One such is constructed by coupling the diaphragm of the speaker to the voice coil through a compliant section and directly attaching a small light-weight cone called ''whizzer'' to the voice coil. The compliant section is intended to ensure that the primary diaphragm responds only to lower frequencies while the whizzer, which is directly coupled to the voice coil, responds only to the rapid movements of the coil at higher frequencies. This combination results in the main diaphragm having an upper cut-off frequency while the characteristics of the whizzer and voice coil set the lower limit to the whizzer's response, thereby implementing a crossover action. The choice/weight of materials used for the diaphragm, whizzer and the speaker's suspension determine the crossover frequency and the effectiveness of the crossover. This sort of crossover is much more complex to design, especially if the highest degree of performance is desired. Extensive trial and error is required. Over several years, the compliance of the joint can change, negatively effecting the response of the speaker. An alternative is to use the dust cap as a high frequency radiating device, also crossed over by mechanical compliance from the primary Diaphragm . High frequency Dispersion is somewhat different for this approach than for whizzer cones. Another possibility is to build the primary cone with such profile, and of such materials, that the neck area remains rigid, radiating all frquencies, while the outer areas of the cone are selectively decoupled, radiating only at lower freqencies. Speakers which use these mechanical crossovers have some advantages in sound quality despite the difficulties of designing and manufacturing them, and despite the inevitable output limitations. Full-range drivers have a single acoustic center, and can have relatively modest phase change across the audio spectrum. For best performance at low frequencies, these drivers require careful enclosure design. Their small size (typically 165 to 200mm) requires considerable cone excursion to reproduce bass, but have short voice coils, demanded for reasonable high frequency performance, incapable of the large cone motions required for bass. But wihtin these constraints, cost and complications are reduced, as no crossovers are required. Those who do not prefer the sound of fullrange drivers (eg, a lack of powerful bass and usually strong highs) sometimes argue that a single diaphragm that must produce both low and high frequencies does neither justice. ''See Full-range Speaker for construction details''. Digital Crossovers Active crossovers can be implemented digitally using a DSP chip or a Microprocessor . They either use the Digital approximations of traditional Analog IIR filters ( Bessel , Butterworth , Linkwitz-Riley etc.), having similar character to the analog versions, or they use Finite Impulse Response (FIR) filters. FIR filters can be constructed easily using DSP chips or Microprocessors . They usually have a higher order, but their behaviour is different. They can be designed and built so that they have a Linear phase response, which is desirable in sound reproduction. As a result, they are often used as crossovers in digital signal processing. Classification based on filter order or slope Just as filters have different orders, so do crossovers, depending on the filter slope they implement. The final acoustic slope may be completely determined by the electrical filter or may be achieved by combining the electrical filter's slope with the natural characteristics of the driver. In the former case, the only requirement is that each driver has a flat response at least to the point where its signal is approximately -10dB down from the passband. In the latter case, the final acoustic slope is usually steeper than of the electrical filters used. A third or fourth order acoustic crossover often has just a 2nd order electrical filter. This requires that speaker drivers be well behaved a considerable way from the nominal crossover frequency, and further that the high frequency driver be able to survive a considerable input in a frequency range below its crossover point. This is difficult in actual practice. In the discussion below, the characteristics of the electrical filter order is discussed, followed by a discussion of crossovers having that acoustic slope and their advantages or disadvantages. Most audio crossovers use first to fourth order electrical filters. Higher orders are not generally implemented in passive crossovers for loudspeakers, but are sometimes found in electronic equipment under circumstances for which their considerable cost and complexity can be justified. First order crossovers 1st order filters have a 20 dB/ Decade (or 6 dB/ Octave ) slope. All 1st order filters have a Butterworth Filter characteristic. 1st order filters are considered by many Audiophile s to be ideal for crossovers. This is because this filter type is 'transient perfect', meaning it passes both amplitude and phase unchanged across the range of interest. It also uses the fewest parts and has the lowest insertion loss (if passive). A 1st order crossover allows signal at unwanted frequencies to get through in the LPF and HPF sections than other configurations. While woofers can easily take this (aside from generating distortion at frequencies above those they can properly handle), smaller high frequency drivers (especially tweeters) are more likely to be damaged since they are not capable of handling large power inputs at lower frequencies than their crossovers. In practice, speaker systems with true first order acoustic slopes are difficult to design because they require large overlapping driver bandwidth, and the shallow slopes mean that non-coincident drivers interfere over a wide frequency range and cause large response shifts off-axis. Second order crossovers 2nd order filters have a 40 dB/decade (or 12 dB/octave) slope. 2nd order filters can have a Bessel , Linkwitz-Riley or Butterworth characteristic depending on design choices and the components used. This order is commonly used in passive crossovers as it offers a reasonable balance between complexity, response, and higher frequency driver protection. When designed with time aligned physical placement, these crossovers have a symmetrical Polar response, as do all even order crossovers. It is commonly thought that there will always be a Phase difference of 180° between the outputs of a (second order) low-pass filter and a high-pass filter having the same crossover frequency. And so, in a 2-way system, the high-pass sections output is usually connected to the high frequency driver 'inverted', to correct for this phase problem. For passive systems, the tweeter is wired with opposite Polarity to the woofer; for active crossovers the high-pass filter's output is inverted. In 3-way systems the mid-range driver or filter is inverted. However, this is generally only true when the speakers have a wide response overlap and the acoustic centers are physically aligned. Third order crossovers 3rd order filters have a 60 dB/decade (or 18 dB/octave) slope. These crossovers usually have Butterworth filter characteristics; Phase Response is very good, the level sum being flat and in phase Quadrature , similar to a first order crossover. The polar response is Asymmetric . In the original D'Appolito MTM arrangement, a symmetrical arrangement of drivers is used to create a symmetrical off axis response when using 3rd order crossovers. Third order acoustic crossovers are often built from first or second order filter circuits. Fourth order crossovers 4th order filters have an 80 dB/decade (or 24 dB/octave) slope. These filters are complex to design in passive form. A 4th order crossover with −6 dB crossover point and flat summing is also known as a Linkwitz-Riley crossover (named after its inventors). It can be constructed in active form by cascading two 2nd order Butterworth filter sections. The output signals of this crossover order are in phase, thus avoiding phase inversion in driver connections unless the driver acoustic centers are not aligned. Higher order crossovers Passive crossovers giving acoustic slopes higher than 4th order are not common, because of cost and complexity. They are sometimes used in active crossover modules. Mixed order crossovers Crossovers can also be constructed with mixed order filters. For example, a second order lowpass combined with a third order highpass. These are generally passive and are used for several reasons, often when the component values are found by computer program optimization. A higher order tweeter crossover can sometimes help compensate for the time offset between the woofer and tweeter, caused by non aligned acoustic centers. Classification based on circuit topology Parallel crossovers These are by far the most common. Electrically the filters are in parallel and thus the various filter sections do not interact. This makes them easier to design because the sections can be considered separately, and because component tolerance variations will be isolated. Series crossovers Crossovers using this topology are almost always passive because it is easiest to construct in passive form. In this topology, the individual filters are connected in series, with a driver or driver combination connected in parallel to each filter. As can be seen in the image, a low-pass filter in Shunt with the tweeter results in a high-pass response for the tweeter, since the lower frequencies are shunted by the LPF via the woofer. Similarly, the HPF in parallel with the woofer shunts away the higher frequencies via the tweeter - a low-pass response for the woofer. One advantage (or disadvantage, depending on how one looks at it) of this crossover, is that the crossover sections interact with each other. Changes in any one component affects both highpass and lowpass sections. To some extent, this makes the crossover somewhat self-balancing - the crossover frequency changes, but the system still sums substantially flat. This characteristic makes them appealing to designers not using using sophisticated measuring equipment or simulation software. These crossovers are also more sensitive to component tolerance variations. Derived Crossovers These are active crossovers in which one of the crossover responses is derived from the other through the use of a differential amplifier. For example, the difference between the input signal and the output of the high pass section is a low pass response. Bohn, D. (Ed.), ''Audio Handbook'' (National Semiconductor Corporation, Santa Clara, CA 1976) § 5.2.4 Thus, when a differential amplifier is used to extract this difference, its output constitutes the low pass filter section. The main advantage of derived filters are that it produces no phase difference between the high pass and low pass sections at any frequency. The disadvantages are either
or both. In case (a), above, the usual situation is that the derived low pass response attenuates at a much slower rate than the fixed response. This requires the speaker to which it is directed to continue to respond to signals deep into the stopband where it's physical characteristics may not be ideal. In the case of (b), above, the both speakers are required to operate at higher volume levels as the signal nears the crossover points. This uses more amplifier power and may drive the speaker cones into non-linearity. NOTES REFERENCES
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