Preselector

Circuit of a very simple preselector. For any one frequency, using a larger tuning coil results in a narrower bandwidth, i.e. greater rejection of out-of-tune signals.

A preselector is a name for an electronic device that connects between a radio antenna and a radio receiver. The preselector is a band-pass filter that blocks troublesome out-of-tune frequencies from passing through from the antenna into the radio receiver (or preamplifier) that otherwise would be directly connected to the antenna.

Purpose

A preselector improves the performance of nearly any receiver, but is especially helpful[a] to receivers with broadband front-ends that are prone to overload, such as scanners and ordinary consumer-market shortwave and AM broadcast receivers.

Frequency response curves for a simple preselector with tuning capacitor setting of 10, 30, 100, or 300 pF

A preselector typically is tuned to have a narrow bandwidth, centered on the receiver's operating frequency. The preselector passes through unchanged the signal on its tuned frequency (or only slightly diminished) but it reduces or removes off-frequency signals, cutting down or eliminating unwanted interference.[b]

Extra filtering can be useful because the first input stage ("front end") of receivers contains at least one RF amplifier, which has power limits ("dynamic range"). Most radios' front ends amplify all radio frequencies delivered to the antenna connection. So off-frequency signals constitute a load on the RF amplifier, wasting part of its dynamic range on unused and unwanted signals. "Limited dynamic range" means that the amplifier circuits have a limit to the total amount of incoming RF signal they can amplify without overloading; symptoms of overload are nonlinearity ("distortion") and ultimately clipping ("buzz").

When the front-end overloads, the performance of the receiver is severely reduced, and in extreme cases can damage the receiver.[1] In situations with noisy and crowded bands, or where there are strong local stations, the dynamic range of the receiver can quickly be exceeded. Extra filtering by the preselector limits frequency range and power demands that are applied to all later stages of the receiver, only loading it with signals within the preselected band.

Multifunction preselectors

A preselector can be engineered so that in addition to attenuating interference from unwanted frequencies, it will perform other services which may be helpful for a receiver: It can limit input signal voltage to protect a sensitive receiver from damage caused by static discharge, nearby voltage spikes, and overload from nearby transmitters' signals; it can provide a DC path to ground, to drain off noisy static charge from building up on the antenna; it can also incorporate a small radio frequency amplifier stage to boost the filtered signal. None of these extra conveniences are necessary for the function of preselection, and in particular, for typical use an amplifier in the preselector serves no helpful purpose.

Antenna preamplifiers (preamps) can be made "tunable" by incorporating a front-end preselector circuit to improve their performance. The integrated device is both a preamplifier and a preselector, and either name is correct. This ambiguity sometimes leads to confusion – conflating preselection with amplification.

A regular, ordinary, standard preselector is sometimes called a "passive" preselector to emphasize that it has no internal amplifier and requires no power supply. Ordinary "passive" preselectors typically work well with modern receivers, with no noticeable signal loss.

Preselect filter bank

Spectrum analyzers and some wideband software-defined radio receivers incorporate a bank of switchable preselectors to reject out-of-band signals that could result in spurious signals at the frequencies being analyzed. In the case of software-defined radio receivers, many of which have limited dynamic range, a preselect filter bank also serves to limit strong out-of-band signals that could potentially saturate the receiver front-end.[2]

Bandwidth vs. signal strength trade-off

With all preselectors there is some very small loss at the tuned frequency; usually, most of the loss is in the inductor (the tuning coil). Turning up the inductance gives the preselector a narrower bandwidth (or higher Q, or greater selectivity) and slightly raises the loss, which nonetheless remains small.

Most preselectors have separate settings for one inductor and one capacitor (at least).[c] So with at least two adjustments available to tune to just one frequency, there are often a variety of possible settings that will tune the preselector to frequencies in its middle-range.

For the narrowest bandwidth (highest Q), the preselector is tuned using the highest inductance and lowest capacitance for the desired frequency, but this produces the greatest loss. It also requires retuning the preselector more often while searching for faint signals, to keep the preselector's pass-through frequency adequately close to the radio's receiving frequency.

For lowest loss (and widest bandwidth), the preselector is tuned using the lowest inductance and highest capacitance (and the lowest Q, or least selectivity) for the desired frequency. The wider bandwidth allows more interference through from nearby frequencies, but reduces the need to retune the preselector while tuning the receiver, since any one low-inductance setting for the preselector will pass a broader span of nearby frequencies.

Different from an antenna tuner

Although a preselector is placed inbetween the radio and the antenna, in the same electrical location as a feedline matching unit, it serves a different purpose: A transmatch or “antenna” tuner connects two transmission lines with different impedances and only incidentally blocks out-of-tune frequencies (if it blocks any at all).

A transmatch matches transmitter impedance to feedline impedance and phase, so that signal power from the radio transmitter smoothly transfers into the antenna's feed cable; a properly adjusted transmatch prevents transmitted power from being reflected back into the transmitter (“backlash current”). Some antenna tuner circuits can both impedance match and preselect,[3] for example the Series Parallel Capacitor (SPC) tuner, and many ‘tuned-transformer’-type matching circuits used in many balanced line tuners (BLT) can be adjusted to also function as band-pass filters.[d]

See also

Footnotes

  1. ^ Despite being helpful for reducing off-frequency interference on relatively wideband antennas, such as dipoles and random wire antennas, a preselector provides little or no benefit to receivers or preamps when they are fed from a narrow-band source, such as a tuned small loop antenna.
  2. ^ Note that a preselector cannot remove any interference that comes through on the same frequency that it and the receiver are both tuned to.
  3. ^ The setting dials may be labeled as "BAND" (inductor, possibly also selection of a capacitor bank) and "TUNE" (capacitor, or extra capacitance for fine-tuning). Regardless of the labeling, if more than one setting of the two is possible for the same frequency, the settings' bandwidths will differ along with other properties like output and input impedances.
  4. ^ Some simpler types of antenna tuners that are not band-pass circuits can also provide limited preselection. The now-common C L C-type ‘T’‑network is a high-pass circuit which always essentially eliminates frequencies below the operating frequency, but even when adjusted for greatest selectivity, cannot block higher frequencies nearly as well as a conventional preselector.[4] It can, however, be adjusted for high operating Q that might attenuate noise above the operating frequency by as much as 20 dB.[5] The complementary π-network that was customarily incorporated in the final stage of ‘vintage’ tube transmitters and amplifiers is a low-pass circuit; it always essentially eliminates frequencies above the tuned frequency, and can be similarly adjusted to provide attenuation below the tuned frequency by as much as 20 dB.[5]

References

  1. ^ Cutsogeorge, George (2014) [2009]. Managing Interstation Interference with Coaxial Stubs and Filters (2nd ed.). Aptos, CA: International Radio Corporation.
  2. ^ "A primer on RF filters for software-defined radio". Software-Defined Radio Simplified (blog). 24 February 2020. Retrieved 17 April 2022.
  3. ^ Stanley, John (K4ERO) (1999). "The filtuner". ARRL Antenna Compendium. Vol. 6. Newington, CT: American Radio Relay League.{cite book}: CS1 maint: numeric names: authors list (link)
  4. ^ Griffith, Andrew S. (W4ULD) (January 1995). "Getting the most out of your 'T'‑network antenna tuner". QST Magazine Magazine. Newington, CT: American Radio Relay League. pp. 44–47. ISSN 0033-4812. OCLC 1623841.{cite magazine}: CS1 maint: numeric names: authors list (link)
  5. ^ a b Stanley, John, K4ERO (September 2015). "Antenna tuners as preselectors". Technical Correspondence. QST Magazine. Newington, CT: American Radio Relay League. p. 61.{cite magazine}: CS1 maint: multiple names: authors list (link) CS1 maint: numeric names: authors list (link)

External links