Synchronous Tuning
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Staggered tuning is a technique used in the design of multi-stage tuned amplifiers whereby each stage is tuned to a slightly different frequency. In comparison to synchronous tuning (where each stage is tuned identically) it produces a wider bandwidth at the expense of reduced
gain Gain or GAIN may refer to: Science and technology * Gain (electronics), an electronics and signal processing term * Antenna gain * Gain (laser), the amplification involved in laser emission * Gain (projection screens) * Information gain in de ...
. It also produces a sharper transition from the passband to the
stopband A stopband is a band of frequencies, between specified limits, through which a circuit, such as a filter or telephone circuit, does not allow signals to pass, or the attenuation is above the required stopband attenuation level. Depending on applic ...
. Both staggered tuning and synchronous tuning circuits are easier to tune and manufacture than many other filter types. The function of stagger-tuned circuits can be expressed as a
rational function In mathematics, a rational function is any function that can be defined by a rational fraction, which is an algebraic fraction such that both the numerator and the denominator are polynomials. The coefficients of the polynomials need not be rat ...
and hence they can be designed to any of the major filter responses such as
Butterworth Butterworth may refer to: Places * Butterworth (ancient township), a former township centred on Milnrow, in the then Parish of Rochdale, England, United Kingdom * Butterworth, Eastern Cape, now also known as Gcuwa, a town located in South Africa ...
and
Chebyshev Pafnuty Lvovich Chebyshev ( rus, Пафну́тий Льво́вич Чебышёв, p=pɐfˈnutʲɪj ˈlʲvovʲɪtɕ tɕɪbɨˈʂof) ( – ) was a Russian mathematician and considered to be the founding father of Russian mathematics. Chebyshe ...
. The
poles Poles,, ; singular masculine: ''Polak'', singular feminine: ''Polka'' or Polish people, are a West Slavic nation and ethnic group, who share a common history, culture, the Polish language and are identified with the country of Poland in Ce ...
of the circuit are easy to manipulate to achieve the desired response because of the amplifier buffering between stages. Applications include television IF amplifiers (mostly 20th century receivers) and wireless LAN.


Rationale

Staggered tuning improves the bandwidth of a multi-stage tuned amplifier at the expense of the overall gain. Staggered tuning also increases the steepness of passband skirts and hence improves
selectivity Selectivity may refer to: Psychology and behaviour * Choice, making a selection among options * Discrimination, the ability to recognize differences * Socioemotional selectivity theory, in social psychology Engineering * Selectivity (radio), a ...
. The value of staggered tuning is best explained by first looking at the shortcomings of tuning every stage identically. This method is called synchronous tuning. Each stage of the amplifier will reduce the bandwidth. In an amplifier with multiple identical stages, the of the response after the first stage will become the points of the second stage. Each successive stage will add a further to what was the band edge of the first stage. Thus the bandwidth becomes progressively narrower with each additional stage. As an example, a four-stage amplifier will have its points at the points of an individual stage. The fractional bandwidth of an LC circuit is given by, : B = :where ''m'' is the power ratio of the power at resonance to that at the band edge frequency (equal to 2 for the point and 1.19 for the point) and ''Q'' is the
quality factor In physics and engineering, the quality factor or ''Q'' factor is a dimensionless parameter that describes how underdamped an oscillator or resonator is. It is defined as the ratio of the initial energy stored in the resonator to the energy los ...
. The bandwidth is thus reduced by a factor of \sqrt. In terms of the number of stages m = 2^. Thus, the four stage synchronously tuned amplifier will have a bandwidth of only 19% of a single stage. Even in a two-stage amplifier the bandwidth is reduced to 41% of the original. Staggered tuning allows the bandwidth to be widened at the expense of overall gain. The overall gain is reduced because when any one stage is at resonance (and thus maximum gain) the others are not, unlike synchronous tuning where all stages are at maximum gain at the same frequency. A two-stage stagger-tuned amplifier will have a gain less than a synchronously tuned amplifier. Even in a design that is intended to be synchronously tuned, some staggered tuning effect is inevitable because of the practical impossibility of keeping all tuned circuits perfectly in step and because of feedback effects. This can be a problem in very narrow band applications where essentially only one spot frequency is of interest, such as a local oscillator feed or a
wave trap In signal processing, a band-stop filter or band-rejection filter is a filter that passes most frequencies unaltered, but attenuates those in a specific range to very low levels. It is the opposite of a band-pass filter. A notch filter is a b ...
. The overall gain of a synchronously tuned amplifier will always be less than the theoretical maximum because of this. Both synchronously tuned and stagger-tuned schemes have a number of advantages over schemes that place all the tuning components in a single aggregated filter circuit separate from the amplifier such as ladder networks or coupled resonators. One advantage is that they are easy to tune. Each resonator is buffered from the others by the amplifier stages so have little effect on each other. The resonators in aggregated circuits, on the other hand, will all interact with each other, particularly their nearest neighbours. Another advantage is that the components need not be close to ideal. Every LC resonator is directly working into a resistor which lowers the ''Q'' anyway so any losses in the L and C components can be absorbed into this resistor in the design. Aggregated designs usually require high ''Q'' resonators. Also, stagger-tuned circuits have resonator components with values that are quite close to each other and in synchronously tuned circuits they can be identical. The spread of component values is thus less in stagger-tuned circuits than in aggregated circuits.


Design

Tuned amplifiers such as the one illustrated at the beginning of this article can be more generically depicted as a chain of transconductance amplifiers each loaded with a tuned circuit. :where for each stage (omitting the suffixes) :''g''m is the amplifier transconductance :''C'' is the tuned circuit capacitance :''L'' is the tuned circuit inductance :''G'' is the sum of the amplifier output conductance and the input conductance of the next amplifier.


Stage gain

The gain ''A''(''s''), of one stage of this amplifier is given by; : A(s) = \frac :where ''s'' is the complex frequency operator. This can be written in a more generic form, that is, not assuming that the resonators are the LC type, with the following substitutions, : \omega_0 = (the resonant frequency) : A_0 := A(\omega_0) = \frac (the gain at resonance) : Q = (the stage quality factor) Resulting in, : A(s) = A_0 \frac


Stage bandwidth

The gain expression can be given as a function of (angular) frequency by making the substitution where ''i'' is the imaginary unit and ''ω'' is the angular frequency : A(\omega) = A_0 \frac The frequency at the band edges, ''ω''c, can be found from this expression by equating the value of the gain at the band edge to the magnitude of the expression, : , A(\omega_c), = \frac :where ''m'' is defined as above and equal to two if the points are desired. Solving this for ''ω''c and taking the difference between the two positive solutions finds the bandwidth Δ''ω'', : \Delta \omega_\mathrm c = \omega_ - \omega_ = \frac and the fractional bandwidth ''B'', : B := \frac = \frac


Overall response

The overall response of the amplifier is given by the product of the individual stages, : A_\mathrm T = A_1 A_2 A_3 \cdots It is desirable to be able to design the filter from a standard low-pass prototype filter of the required specification. Frequently, a smooth
Butterworth response The Butterworth filter is a type of signal processing filter designed to have a frequency response that is as flat as possible in the passband. It is also referred to as a maximally flat magnitude filter. It was first described in 1930 by the Br ...
will be chosen but other polynomial functions can be used that allow ripple in the response. A popular choice for a polynomial with ripple is the Chebyshev response for its steep skirt. For the purpose of transformation, the stage gain expression can be rewritten in the more suggestive form, : A(s) = \frac This can be transformed into a low-pass prototype filter with the transform : Q \left ( \frac + \frac \right ) \to \frac :where ''ωc is the cutoff frequency of the low-pass prototype. This can be done straightforwardly for the complete filter in the case of synchronously tuned amplifiers where every stage has the same ''ω''0 but for a stagger-tuned amplifier there is no simple analytical solution to the transform. Stagger-tuned designs can be approached instead by calculating the
poles Poles,, ; singular masculine: ''Polak'', singular feminine: ''Polka'' or Polish people, are a West Slavic nation and ethnic group, who share a common history, culture, the Polish language and are identified with the country of Poland in Ce ...
of a low-pass prototype of the desired form (e.g. Butterworth) and then transforming those poles to a band-pass response. The poles so calculated can then be used to define the tuned circuits of the individual stages.


Poles

The stage gain can be rewritten in terms of the poles by factorising the denominator; : A(s) = \frac \frac :where ''p'', ''p*'' are a complex conjugate pair of poles and the overall response is, : A_\mathrm T = \frac \cdot \frac \cdot \frac \cdot \cdots :where the ''a''k = ''A''0k''ω''0k/''Q''0k From the band-pass to low-pass transform given above, an expression can be found for the poles in terms of the poles of the low-pass prototype, ''qk'', : p_k, p^*_k = \left ( \frac \pm \sqrt \right ) :where ''ω''0B is the desired band-pass centre frequency and ''Q''eff is the effective ''Q'' of the overall circuit. Each pole in the prototype transforms to a complex conjugate pair of poles in the band-pass and corresponds to one stage of the amplifier. This expression is greatly simplified if the cutoff frequency of the prototype, ''ωc, is set to the final filter bandwidth ''ω''0B/''Q''eff. : p_k, p^*_k = \left ( q_k \pm \sqrt \right ) In the case of a narrowband design which can be used to make a further simplification with the approximation, : p_k, p^*_k \approx \pm i \omega_ These poles can be inserted into the stage gain expression in terms of poles. By comparing with the stage gain expression in terms of component values, those component values can then be calculated.


Applications

Staggered tuning is of most benefit in wideband applications. It was formerly commonly used in television receiver
IF amplifier Intermediate-frequency (IF) amplifiers are amplifier stages used to raise signal levels in radio and television receivers, at frequencies intermediate to the higher radio-frequency (RF) signal from the antenna and the lower (baseband) audio or v ...
s. However,
SAW filter A saw is a tool consisting of a tough blade, wire, or chain with a hard toothed edge. It is used to cut through material, very often wood, though sometimes metal or stone. The cut is made by placing the toothed edge against the material and mo ...
s are more likely to be used in that role nowadays. Staggered tuning has advantages in VLSI for radio applications such as wireless LAN. The low spread of component values make it much easier to implement in
integrated circuit An integrated circuit or monolithic integrated circuit (also referred to as an IC, a chip, or a microchip) is a set of electronic circuits on one small flat piece (or "chip") of semiconductor material, usually silicon. Large numbers of tiny ...
s than traditional ladder networks.Iniewski, p. 200


See also

*
Double-tuned amplifier A double-tuned amplifier is a tuned amplifier with transformer coupling between the amplifier stages in which the inductances of both the primary and secondary windings are tuned separately with a capacitor across each. The scheme results in a w ...


References


Bibliography

* Chattopadhyay, D., ''Electronics: Fundamentals and Applications'', New Age International, 2006 . * Gulati, R. R., ''Modern Television Practice Principles,Technology and Servicing'', New Age International, 2002 . * Iniewski, Krzysztof, ''CMOS Nanoelectronics: Analog and RF VLSI Circuits'', McGraw Hill Professional, 2011 . * Maheswari, L. K.; Anand, M. M. S., ''Analog Electronics'', PHI Learning, 2009 . * Moxon, L. A., ''Recent Advances in Radio Receivers'', Cambridge University Press, 1949 . * Pederson, Donald O.; Mayaram, Kartikeya, ''Analog Integrated Circuits for Communication'', Springer, 2007 . * Sedha, R. S., ''A Textbook of Electronic Circuits'', S. Chand, 2008 . * Wiser, Robert, ''Tunable Bandpass RF Filters for CMOS Wireless Transmitters'', ProQuest, 2008 {{ISBN, 0549850570. Electronic amplifiers Signal processing filter