Editing Bat detector (section)

==Bat detector types==

===Heterodyne===
[[File:FreqMixing.svg|thumb|Illustration of heterodyne mixing. An incoming down chirp is combined with a constant 50 kHz frequency signal (LO, Fig. A). Fig. B shows the resulting signal with low (difference) and high (sum) frequency components. Figs. C:/D: depicts the resp. magnitudes in the frequency domain.]] 
[[Heterodyne]] detectors are the most commonly used, and most self-build detectors are of this type. A heterodyne function is often also built into the other types of detector. A heterodyne bat detector simply shifts all the ultrasound frequencies downward by a fixed amount so we can hear them.

A "heterodyne" is a beat frequency such as can be heard when two close musical notes are played together. A heterodyne bat detector combines the bat call with a constant internal frequency so that sum and difference frequencies are generated. For instance, a bat call at 45&nbsp;kHz and an internal frequency of 43&nbsp;kHz produces output frequencies of 2&nbsp;kHz and 88&nbsp;kHz. The 88&nbsp;kHz frequency is inaudible and is filtered out and the 2&nbsp;kHz frequency is fed to a loudspeaker or headphones. The internal frequency is displayed on a dial or on a display.

A better quality version of a heterodyne, or direct conversion, bat detector is the super-heterodyne detector. In this case the bat signal is mixed with a high frequency oscillator, typically around 450–600&nbsp;kHz. The difference frequency is then amplified and filtered in an 'intermediate frequency' or i.f. amplifier before being converted back to audible frequencies again. This design, which is based on standard radio design, gives improved frequency discrimination and avoids problems with interference from the local oscillator.

In more recent DSP-based detectors, the heterodyne conversion can be done entirely digitally.

It is also possible to use a 'comb spectrum' generator as the local oscillator so that the detector is effectively tuned to many frequencies, 10&nbsp;kHz apart, simultaneously.

Some early bat detectors used ex-Navy low frequency radio sets, simply replacing the aerial with a microphone and pre-amplifier. It is also possible to modify a portable Long Wave radio to be a bat detector by adjusting the tuning frequencies and replacing the [[ferrite rod]] aerial with a microphone and pre-amplifier.

====How it is used====
The operator guesses the likely species to be present and tunes the frequency accordingly. Many users will start listening around 45&nbsp;kHz. If a bat is seen or a bat-like call is heard, the frequency is tuned up and down until the clearest sound is heard.

Species like Pipistrelles which end their call with a "hockey stick" CF component can be recognised according to the lowest frequency which gives the clearest "plop" sound. Horseshoe bats give a peeping sound at a frequency depending on their species. FM calls all tend to sound like clicks, but the start and end frequencies and the call repetition pattern can give clues as to the species.

====Pros and cons====
The advantages of a heterodyne bat detector is that it works in real time, exaggerates the frequency changes of a bat call, is easy to use, and is the least expensive. It is easy to recognise a [[Doppler effect|doppler shift]] in CF calls of flying bats due to their speed of flight. Stereo listening and recording is possible with models such as the CSE stereo heterodyne detector, and this can help to track bats when visibility is poor.

The disadvantages of a heterodyne bat detector are that it can only convert a narrow band of frequencies, typically 5&nbsp;kHz, and has to be continually retuned, and can easily miss species out of its current tuned range.

===Frequency division===
[[File:FreqDiv-(dkrb).svg|thumb|Frequency division: Original signal is converted into square waves and then divided by a fixed factor (here: 16).]]
Frequency division (FD) bat detectors synthesise a sound which is a fraction of the bat call frequencies, typically 1/10. This is done by converting the call into a [[Square wave (waveform)|square wave]], otherwise called a zero crossing signal. This square wave is then divided using an electronic counter by 10 to provide another square wave. Square waves sound harsh and contain [[harmonic]]s which can cause problems in analysis so these are filtered out where possible. Some recent all-digital detectors can synthesise a sine wave instead of a square wave. One example of a detector which synthesises a sine-wave FD output is the Griffin.

Some FD detectors output this constant level signal which renders background noise and bat calls at the same high level. This causes problems with both listening and analysis. More sophisticated FD detectors such as the Batbox Duet measure the incoming volume level, limiting the noise threshold, and use this to restore the output level variations. This and other sophisticated FD detectors also include a heterodyne detector and provide a jack output so that independent outputs can be recorded for later analysis.

====How it is used====
With dual output FD detectors, headphones can be used to monitor both outputs simultaneously, or the loudspeaker used with the heterodyne function and the FD output recorded and analysed later. Alternatively, listening to the FD output gives an audible rendering of the bat call at 1/10 frequency. An example of a dual detector is the Ciel CDB301.

Dual FD/heterodyne detectors are useful for cross country transects especially when there is a function provided for recording voice notes such as times, locations and recognised bat calls. The output or outputs are recorded on cassette tape, Minidisc or solid state recorders, downloaded to a computer, and analysed using custom software. Calls missed by the heterodyne function, if present, can be seen and measured on the analysis.

====Pros and cons====
Advantages, As with a heterodyne detector, an FD detector works in real time with or without a heterodyne function. Bat calls can be heard in their entirety over their whole range rather than over a limited frequency range. Retuning with an FD detector is not required although this is done with a dual type with heterodyne. By analysing the recording later, the entire call frequency range and the call pattern can be measured.

A serious disadvantage with real time listening is that the speed of a bat call remains fast, often too fast for the species to be recognised. The frequency changes of CF calls are not exaggerated as with a heterodyne detector and so are less noticeable. Also with some species such as the Lesser Horseshoe bat with a call around 110&nbsp;kHz, the resulting frequency is still quite high although it can be recorded. The synthesising of the call means that only one bat call can be reproduced at a time and a muddle is caused by simultaneous calls. Surprisingly, this is not a great disadvantage when analysing a recording later

===Time expansion===
[[File:TimeExpansion-(dkrb).svg|thumb|20fold time expansion. Signal amplitude and shape are retained while the expanded signal gets lowered 20fold in frequency content and its duration expanded respectively.]]
Time expansion (TE) detectors work by digitising the bat calls at a high sampling rate using an [[analog-to-digital converter]] and storing the digitised signal in an on-board memory.

TE detectors are "real time" devices in that they can be monitored at the time of recording, but there is an inevitable delay while the high speed sampled extract is slowed down and replayed.

====How it is used====
In real time mode, with or without an associated heterodyne or FD detector, the slowed down calls can be heard as a drawn-out bat call at audible frequencies. Therefore, fast FM calls can be heard as a descending note instead of a click. Thus it is possible to hear the difference between FM calls which just sound like clicks on the other types of detector.

After downloading an audio recording to a computer, the original calls are analysed as if they were still at the original non-expanded rate.

====Pros and cons====
The output can be recorded with an audio recorder as with FD detectors, or with more recent units, the signal can be recorded directly to an internal digital memory such as a compact flash card. The whole waveform is recorded with the full call range being preserved, rather than 1/10 of the waveform as in a FD detector. Since both frequency and amplitude information are preserved in the recorded call, more data is available for species analysis.

Early units were equipped with small memories which limited the length of time that could be digitised. Once the memory was filled (usually only a few seconds maximum), the unit would then replay the recording at slower rate, typically between 1/10 to 1/32 of the rate of the original recording. While the recorded sample is being played back slowly, nothing is being recorded, so the bat calls are being sampled intermittently. For instance, when a 1-second call is being played back at 1/32 rate, 32 seconds of bat calls are not being recorded.

More recent time-expansion recorders use large flash-based memories (such as removable compact-flash cards) and high-bandwidth direct-to-card recording to provide continuous, full-bandwidth real-time recording. Such units can record continuously for many hours while maintaining the maximum information within the signal.

Some units are also equipped with an auto-record function and these can be left in-the-field for many days.

Some units also include a pre-buffer feature to capture events that happened shortly before the 'record' button was pressed which can be useful for manual surveys.

TE detectors are typically used for professional and research work, as they allow a complete analysis of the bats' calls at a later time.