Over the past 10 years, more and more high-end manufacturers have begun using Integrated Circuits (ICs) in their analog electronics. While ICs offer advantages in terms of cost and size compared to discrete circuits, even the best ICs fall short when it comes to all-out sonic performance. This is why Ayre only uses discrete FET circuitry for all analog stages (and associated power supply regulators), and mechanical switching elements for level controls and input selectors. 

Four Design Elements

Today, there are four different gain elements available to the audio designer: vacuum tubes, bipolar transistors, integrated circuits, and field-effect transistors (FETs).    Let us briefly examine each of these choices.

Vacuum Tubes

The oldest type of electronic gain element still offers many strengths for audio design, including excellent  linearity, extended high-frequency performance, and tolerance to short-term overload. However, these characteristics must be balanced against their inevitable sonic degradation over time, the need for high-voltages and filament supplies (with attendant reliability issues), and the difficulty of interfacing with low impedance loads.

Nonetheless, allowing for their limitations, excellent performance is available from tube designs. In fact, the characteristics of tubes are such that it is difficult to design a poor sounding product when using tubes exclusively in the audio circuitry and power supply.

Bipolar Transistors

These solid-state device offer virtually the opposite benefits and drawback of tubes.  They offer virtually  no degradation over time,  operate with low voltages and without filaments, and are naturally suited to low-impedance loads.

Regrettably, they are not the perfect substitute for vacuum tubes. Their exponential transfer function yields higher-order distortion products, while high-frequency performance is constrained due to minority-carrier effects, and short-term overload results in catastrophic failure.

Notwithstanding these limitations, a skilled designer can extract excellent performance from bipolar transistors, as attested to by the many successful designs utilizing this technology.

Integrated Circuits

Modern photo lithographic techniques allow for a complete circuit to be fabricated with nearly the same ease and cost as a single transistor. Representative ICs used for audio applications are op-amps, voltage regulators, and digitally- controlled level attenuators.  These devices typicallyinclude several dozen bipolar transistors, although FETs are sometimes utilized in the input stages.

The chief advantages of ICs are low costs, potential for improved thermal tracking, and the possibility of miniaturized products.  Note however, that these benefits are not generally applicable to high-performance audio designs. The disadvantages of ICs include those associated with bipolar transistors in general, along with other constraints that result from the prepackaging of complex circuitry.

One limitation with ICs is the fact that virtually all of the resistors are fabricated from the same silicon substrate as the transistors.  Silicon resistors inherently cannot achieve the same linearity and performance that is available from high-quality discrete resistors, due to the limitations of the resistive material. In addition, a nonlinear parasitic capacitance exists between the silicon resistor and the substrate, which varies with the applied voltage.

Another difficulty arises due to the need for massive amounts of negative feedback with IC op-amps and voltage regulators.  Critical listening tests by many observers have shown a preference for little or no negative feedback. However, this is not an option for circuits using ICs.

Perhaps the most pervasive shortcoming of ICs is the cookie-cutter approach to circuit design that they engender. Although their easy application allows the inexperienced designer to achieve reasonably good results from today's high performance ICs, gone is the opportunity for an experienced designer to extract the ultimate performance level from any given circuit.

Obviously, the overall circuit topology of an IC is determined by the manufacturer and cannot be altered. Perhaps what is not so obvious is the loss of ability to fine-tune any given circuit.  The crucial details that separate a good sounding design from the truly excellent are not available for optimization.  Bias current levels, open-loop gain, ultrasonic response characteristics, and other important parameters that affect the sonic result remain inflexibly predetermined.

Field-Effect Transistors

The concept of the FET predates the bipolar transistor by several decades, although manufacturing constraints gave them a late start in commercial electronics.  This is unfortunate,as the FET combines the strengths of vacuum tubes and bipolar transistors, bypassing their respective weaknesses.

As solid-state devices, they exhibit no gradual deterioration. Their transfer function obeys the square-order law, dramatically lowering high-order distortion products.  Only majority carriers are present, allowing for improved high-frequency performance. FETs are also free from secondary breakdown effects that can destroy bipolar devices during overload conditions.

Disadvantages of FETs include higher cost, device-to-device performance spread that necessitates matching for optimal results, and a lack of readily available design information.

Conclusion

Among the four basic building blocks of audio circuits, ICs offer the fewest advantages for high-performance audio.  Excellent results are achievable from both vacuum tubes and bipolar transistors when a skilled designer optimizes the circuit to the application. However at Ayre, we have chosen to use FETs and mechanical switching elements exclusively as the best avenue to attaining the ultimate sonic performance combined with decades of reliable operation.

Information originally from http://www.ayre.com with permission

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