FR2801400A1 - Optical signal intruder detection system, having intense pulse source/target broadcast diffuser multiple photon rays providing and different position detectors detecting signal change - Google Patents

Abstract

A detection system uses an optical signal source and an optical detection system that receives light emitted from the source. A processor is connected to the optical detection system and triggers an indication of an intrusion in response to a change in the detected optical signal. The optical detection system includes a number of optical outputs distributed over different locations. In a preferred example, these are connected in common to an isolated photon detector via a passive optical network.

Description

The present invention relates to an intruder detection system, and particularly to a system that uses an optical signal to detect the presence of an intruder.

It is well known to construct an intruder detection system by aligning an optical source and an optical detector, and then recording any interruption of the optical signal as an intruder passes between the source and the detector. A significant weakness of conventional systems is that a potential intruder may observe the path of the optical signal, for example as a result of the diffusion of the signal by particles in the atmosphere. This makes it possible for the intruder to avoid the optical signal path, or use countermeasures to avoid detection. Even though the optical signal is in the infrared range, and therefore not directly visible, it can still be seen if the intruder is using appropriate aids such as night vision binoculars.

According to a first aspect of the present invention, there is an intruder detection method comprising a) the transmission of optical signal b) the detection of the optical signal, and c) the triggering indication of an intrusion in response to a variation of the detected optical signal, characterized in that step (b) comprises receiving optical signals scattered at a number of spatially distributed optical inputs.

The present invention makes it more difficult for an intruder to observe and avoid the traj of the optical signal, by detecting the scattered signals at a number of different locations, instead of simply detecting a localized beam.

From <SEP> preference, <SEP> the <SEP> method <SEP> includes <SEP> the <SEP> transmission
<tb> optical <SEP> signals <SEP> from <SEP><SEP> multiple <SEP> optical <SEP> inputs
<tb> dispatches <SEP> in <SEP> the <SEP> space to <SEP> a common <SEP><SEP> detector.
<tb> preference <SEP> the <SEP> process <SEP> includes <SEP> the <SEP> application of <SEP> different
<tb> respective <SEP> delays <SEP> to <SEP><SEP><SEP> signals received <SEP> to <SEP> different <SEP> entries
<tb> optics.
<tb> characteristics <SEP> preferred <SEP> of <SEP> the invention <SEP> make
<tb> possible <SEP> to get <SEP>SEP><SEP> benefits of <SEP><SEP><SEP> detection points
<tb> multiple <SEP> without <SEP> increase <SEP> significant <SEP> of <SEP> cost
<tb> system. <SEP> This <SEP> is <SEP> obtained <SEP> in <SEP> using <SEP> a <SEP> common <SEP> detector
<tb> for <SEP> different <SEP> entries.
<tb> preferably, <SEP> the <SEP> method <SEP> includes <SEP> the <SEP> detection <SEP> of the
<tb> signal <SEP> optical <SEP> in <SEP> using <SEP> a <SEP> detector <SEP> of <SEP> isolated photons <SEP>.
<tb>'use<SEP> of a <SEP> detector <SEP> of <SEP> photons <SEP> isolated <SEP> allows
<tb> the <SEP> detection <SEP> same <SEP> of <SEP><SEP> signals <SEP> low <SEP> resulting <SEP> from a
<tb> broadcast, <SEP> this <SEP> which <SEP> makes <SEP> difficult <SEP> than <SEP> the <SEP><SEP> signal broadcast <SEP> is
<tb> observed. <SEP> Of <SEP> preference, <SEP> the <SEP> signal <SEP> Optical <SEP> is <SEP> a <SEP> signal <SEP> to
<tb> narrow <SEP> band, <SEP> and <SEP> the <SEP> step consisting of <SEP> to <SEP> detect <SEP> the <SEP> signal
<tb> Optical <SEP> includes <SEP><SEP><SEP> Passage of <SEP><SEP> Optical <SEP> Signal to <SEP> across
<tb> of a <SEP> filter <SEP> to <SEP> band <SEP> narrow <SEP> adapted <SEP> to <SEP> the <SEP> source <SEP> to <SEP> band
<tb> narrow. <SEP> This <SEP> help <SEP> more <SEP> to <SEP> the <SEP> discrimination <SEP> of a <SEP> signal
<tb> optic <SEP> low <SEP> in <SEP> presence <SEP> of a <SEP> ambient <SEP> light.
<tb> In accordance with <SEP> at <SEP> a <SEP> second <SEP> aspect <SEP> of <SEP><SEP> presents
<tb> invention, <SEP> it <SEP> is <SEP> realized <SEP> a <SEP> system <SEP> of <SEP> detection <SEP> of intruders
<tb> including <SEP>.
<tb> a) <SEP> a <SEP> source <SEP> of <SEP> optical <SEP> signal
<tb> b) <SEP> a <SEP> system <SEP> of <SEP> optical <SEP> detection, <SEP> and
<tb> c) <SEP> A <SEP> Processor <SEP> Connected <SEP> To <SEP> System <SEP> From <SEP> Optical <SEP> Detection
<tb> and <SEP> willing <SEP> of <SEP> way <SEP> to <SEP> trigger <SEP> a <SEP> indication
<tb> of a <SEP> intrusion <SEP> in <SEP> response <SEP> to <SEP> a <SEP><SEP> variation of the <SEP> signal
<tb> optical <SEP> detected,
<tb> characterized <SEP> in <SEP> this <SEP> as <SEP> the <SEP> system <SEP> of <SEP> detection <SEP> optics <SEP> (b)
<tb> includes <SEP> a <SEP> certain <SEP><SEP> number of <SEP><SEP> distributed <SEP> optical inputs in
<tb> space.

<SEP> systems <SEP> setting <SEP> in <SEP> work <SEP> the <SEP> present <SEP> invention
<tb> will be <SEP> now <SEP> described <SEP> more <SEP> in <SEP> detail, <SEP> to <SEP> title
<tb>'example<SEP> only, <SEP> in <SEP> doing <SEP> reference <SEP> drawings
<tb> appended, <SEP> in <SEP> which ones
<tb> The <SEP> figure <SEP> 1 <SEP> is <SEP> a <SEP> schema <SEP> representing <SEP> first
<tb> example <SEP> of a <SEP> system <SEP> of <SEP> detection <SEP> of intruders.
<tb> The <SEP> figure <SEP> 2 <SEP> is <SEP> a <SEP> schema <SEP> representing <SEP> second
<tb> example <SEP> of a <SEP> system <SEP> of <SEP> detection <SEP> of intruders.
<tb> The <SEP> figure <SEP> 3 <SEP> is <SEP> a <SEP> schema <SEP> representing <SEP> third
<tb> example <SEP> of a <SEP> system <SEP> of <SEP> detection <SEP> of intruders.
<tb> The <SEP> figure <SEP> 4 <SEP> is <SEP> a <SEP> schema <SEP> representing <SEP> system <SEP> of
<tb> detection <SEP> of intruders <SEP> employing <SEP> a <SEP> multiplexing <SEP> in <SEP> length
<tb> wave.
<tb> The <SEP> figure <SEP> 5 <SEP> is <SEP> a <SEP> schema <SEP> representing <SEP> system <SEP> of
<tb> detection <SEP> optical <SEP> employing <SEP> a <SEP> source <SEP> optics <SEP> of <SEP> photons
<tb> isolated <SEP> in <SEP> combination <SEP> with <SEP> a <SEP> multiplexing <SEP> length
<tb> wave.
<tb> As <SEP> specified <SEP> on <SEP> the <SEP> figure <SEP> 1, <SEP> a <SEP> system <SEP> of <SEP> detection
<tb> intruder <SEP> includes <SEP> a <SEP> source <SEP> 1 <SEP> of <SEP> short <SEP><SEP> pulses to
<tb> multiple photons <SEP>. <SEP> The <SEP> source <SEP> 1 <SEP> sends <SEP> a <SEP> bundle <SEP> B <SEP> which <SEP> is
<tb> directed <SEP> to <SEP> a <SEP> target <SEP> of <SEP> broadcast <SEP> 2. <SEP> In <SEP> this <SEP> example, <SEP>
<tb> source <SEP> 1 <SEP> is <SEP> mounted <SEP> near <SEP> of <SEP><SEP> level of <SEP> soil <SEP> on <SEP><SEP> wall <SEP > and
<tb> target <SEP> of <SEP> broadcast <SEP> 2 <SEP> is <SEP> mounted <SEP> on <SEP> a <SEP> ceiling <SEP> of <SEP>
<tb> piece <SEP> in <SEP> where <SEP> the <SEP> system <SEP> of <SEP> detection <SEP> is <SEP> deployed. <SEP> The
<tb> target <SEP> of <SEP> broadcast <SEP> diffuse <SEP> the <SEP> photons <SEP> of a <SEP> way <SEP> general
<tb> at <SEP> through <SEP> of <SEP><SEP> part <SEP> in <SEP><SEP> three <SEP> dimensions. <SEP> certain
<tb><SEP><SEP><SEP><SEP> optics <SEP><SEP><SEP><SEP><SEP><SEP><SEP>
<tb> from <SEP><SEP> part <SEP> to <SEP> different <SEP> locations. <SEP> The <SEP> entry <SEP> points
<tb> optics <SEP> include <SEP><SEP> Optical <SEP> Elements <SEP> of <SEP><SEP> Collection
<tb> harness <SEP> linked <SEP> to <SEP> a respective <SEP> fiber <SEP> optical <SEP>. <SEP> Each <SEP> fiber
<tb> optical <SEP> form <SEP> a <SEP> branch <SEP> of a <SEP> network <SEP> optical <SEP> passive <SEP> (PON).
<tb> different <SEP> branches <SEP> of <SEP> network <SEP> optical <SEP> passive
<tb> include <SEP> different <SEP> respective <SEP> optical <SEP> delays, <SEP> of <SEP> so
<tb><SEP> Optical <SEP> signals <SEP> from <SEP> of an <SEP> optical <SEP> input
<tb> different <SEP> are <SEP> separated <SEP> in <SEP> the <SEP><SEP> domain of the <SEP> time. <SEP> The

delays <SEP> optical <SEP> can <SEP> be <SEP> performed <SEP> by <SEP> loops <SEP> of
<tb> fiber <SEP> optical <SEP> of <SEP> different <SEP> lengths.
<tb> The <SEP> Network <SEP> optical <SEP> passive <SEP> is <SEP> connected <SEP> to <SEP> its <SEP> head <SEP> of <SEP> network
<tb> to <SEP> a <SEP> system <SEP> of <SEP> optical <SEP> detection. <SEP> The <SEP> system <SEP> detection
<tb> optical <SEP> includes <SEP> a <SEP> filter <SEP> to <SEP> band <SEP> close <SEP> and <SEP> a
<tb> photodetector. <SEP> In <SEP> the <SEP> present <SEP> example, <SEP> the <SEP> photodetector
<tb> is <SEP> a <SEP> detector <SEP> of <SEP> isolated photons <SEP>. <SEP> The <SEP> Filter <SEP> to <SEP> Tape
<tb> narrow <SEP> is <SEP> adapted <SEP> to <SEP> the <SEP> length <SEP> wave <SEP> the <SEP> source
<tb> optics. <SEP> The <SEP> output <SEP> of the <SEP> detector <SEP> of <SEP> photons <SEP> isolated <SEP> is
<tb> processed <SEP> by <SEP> a <SEP> computer <SEP> staff <SEP> 6. <SEP>'computer
<tb> personnel <SEP> has <SEP> a <SEP><SEP> electrical <SEP> connection with <SEP> the <SEP> source
<tb> optical <SEP> 1 <SEP> and <SEP> receives <SEP><SEP> pulses <SEP> from <SEP> synchronization
<tb> electrical <SEP> from <SEP> of <SEP><SEP> source <SEP> 1. <SEP> In <SEP> operation, <SEP> the
<tb><SEP> rate of <SEP> count <SEP> of <SEP><SEP> events of <SEP> detection <SEP> in <SEP> on
<tb> detector <SEP> photons <SEP> isolated <SEP> which <SEP> are <SEP> synchronized <SEP> with <SEP> la
<tb> production <SEP> of <SEP> pulses <SEP> by <SEP> the <SEP> source <SEP> 1 <SEP> is <SEP> measured. <SEP> In
<tb> computer <SEP> 6, <SEP><SEP> rate <SEP> of <SEP> count <SEP> is <SEP> compared <SEP> to <SEP> of
<tb><SEP><SEP><SEP> Upper <SEP> and <SEP> Lower <SEP> Threshold values predefined. <SEP> Si
<tb> these <SEP><SEP><SEP> threshold <SEP> values are <SEP> exceeded, <SEP> by <SEP><SEP><SEP> example does
<tb> that a <SEP> intruder <SEP> is <SEP> entered <SEP> in <SEP> the <SEP> part <SEP> and, <SEP> in <SEP>'<SEP> so, <SEP> a
<tb> reduces <SEP> the <SEP><SEP> level of <SEP><SEP> light reaching <SEP> a <SEP> or <SEP> multiple <SEP> of <SEP>
<tb> detectors <SEP> then <SEP> an <SEP> alarm <SEP> intrusion <SEP> is <SEP> triggered. <SEP> The
<tb><SEP> levels of <SEP> threshold <SEP> for <SEP> a <SEP> detection <SEP> of intruders <SEP> can <SEP> be
<tb> set <SEP> in <SEP> making <SEP> run <SEP> the <SEP> system <SEP> of <SEP> detection <SEP> in
<tb> a <SEP><SEP> learning phase <SEP> during <SEP> which <SEP> the computer
<tb> measure <SEP> the <SEP> rate <SEP> of <SEP> count <SEP> and <SEP> the <SEP> variation <SEP> of <SEP> rate <SEP> of
<tb> count <SEP> the absence <SEP> of any <SEP> intruder <SEP>. <SEP> This <SEP> establishes
<tb> then <SEP> the <SEP> limits <SEP> of the <SEP><SEP> possible <SEP> variations of <SEP><SEP> rate of
<tb> count <SEP> and <SEP> any <SEP> gap <SEP> by <SEP> report <SEP> to <SEP> these <SEP> imitates <SEP> is <SEP> taken
<tb> for <SEP> indicate <SEP> the <SEP> presence <SEP> of an <SEP> intruder. <SEP> Optionally, <SEP> of
<tb> way <SEP> to <SEP> strengthen <SEP> still <SEP> the <SEP> sensitivity <SEP> of the <SEP> system <SEP> all <SEP> in
<tb> retaining <SEP> a <SEP> low <SEP> acceptable <SEP> rate <SEP> of <SEP> false <SEP> alarms,
<tb> the <SEP> machine can <SEP> use <SEP> a <SEP><SEP> heuristic <SEP> algorithm for
<tb> learn <SEP> the <SEP> expected <SEP> profile <SEP> of <SEP><SEP> count <SEP> events in

the absence <SEP> of a <SEP> intruder. <SEP> The <SEP> heuristic <SEP> algorithm can
<tb> use <SEP> a <SEP><SEP> technology of <SEP> neural network <SEP>.
<tb> The <SEP> components <SEP> used <SEP> in <SEP> the <SEP> system <SEP> and <SEP> the
<tb> operation <SEP> of <SEP> system <SEP> will be <SEP> now <SEP> described <SEP> with
<tb> more <SEP> of <SEP> details.
<tb> The <SEP> source <SEP> optics <SEP> 1 <SEP> of <SEP> this <SEP> example <SEP> is <SEP> laser <SEP> to
<tb> semiconductor <SEP> pulsed. <SEP> A suitable <SEP><SEP> device <SEP> is <SEP> available
<tb> in <SEP> the <SEP> trade <SEP> under <SEP><SEP> reference <SEP> PDL <SEP> 800 <SEP> (PicoQuant <SEP> GmbH).
<tb> The <SEP> laser <SEP> to <SEP> semiconductor <SEP> is <SEP> attacked <SEP> by <SEP> a <SEP> generator
<tb> of pulses.
<tb> The <SEP> detector <SEP> of <SEP> photons <SEP> isolated <SEP> can <SEP> be, <SEP> by <SEP> example,
<tb> a <SEP> photodiode <SEP> to <SEP> avalanche <SEP> (APD) <SEP> polarized <SEP> -del <SEP>
<tb><SEP> reverse <SEP> and <SEP> failure <SEP> running in <SEP><SEP>SEP> Geiger <SEP> mode of
<tb> way <SEP> get <SEP> a <SEP> sensitivity <SEP> on <SEP> a <SEP> only <SEP> photon. <SEP>
<tb> photodiodes <SEP> APD <SEP> at <SEP> silicon <SEP> such <SEP> as <SEP> the <SEP> photodiode <SEP> SPCM 100-AQ <SEP> (EG <SEP> and <SEP > G <SEP> Opto-Electronics <SEP> Canada) <SEP> can <SEP> be
<tb> used <SEP> in <SEP><SEP> range <SEP> of <SEP><SEP><SEP> lengths of <SEP> 400 <SEP> to
<tb> 1060 <SEP> nm, <SEP> then <SEP> than <SEP><SEP> devices <SEP> to <SEP> germanium <SEP> or <SEP> to <SEP> InGaAs
<tb> such <SEP> as <SEP> the <SEP> devices <SEP> NDL5131P1 <SEP> (NEC <SEP> Corporation) <SEP> or
<tb> C30644JT <SEP> (EG <SEP> and <SEP> G <SEP> Opto-Electronics <SEP> Canada) <SEP> may <SEP> be
<tb> used <SEP> in <SEP><SEP><SEP> range of <SEP><SEP> wave lengths <SEP> 1000 <SEP> to
<tb> 1550 <SEP> nm <SEP> with <SEP> an <SEP> avalanche <SEP> circuit <SEP>
<tb> appropriate. <SEP> The <SEP> filters <SEP> to <SEP> band <SEP> narrow <SEP> used <SEP> at the <SEP><SEP> level of the
<tb> detector <SEP> can <SEP> be <SEP> made <SEP> by <SEP> using <SEP> one
<tb>SEP> technology of <SEP><SEP> network of <SEP> diffraction <SEP> of <SEP> photosensitive Bragg <SEP>,
<tb> or <SEP> a <SEP> technology <SEP> of <SEP><SEP> dielectric <SEP> to <SEP> thin <SEP> thin
<tb> micro-optics <SEP> (by <SEP> example <SEP> TB1300A <SEP> manufactured <SEP> by <SEP> JDS-Fitel).
<tb> The <SEP> Personal <SEP> (PC) <SEP> computer is <SEP> a <SEP> system <SEP> available
<tb> in <SEP><SEP> Commerce <SEP> using, <SEP> by <SEP> example, <SEP> a <SEP> microprocessor
<tb> Pentium <SEP> III <SEP> (trademark <SEP> of <SEP> trade). <SEP> The <SEP> computer includes <SEP> one
<tb><SEP> card of <SEP> count <SEP> of <SEP> photons <SEP> such <SEP> as <SEP><SEP> card <SEP> TimeHarp <SEP> 100
<tb> (PicoQuant <SEP> GmbH) <SEP> which <SEP> processes <SEP> the <SEP> output <SEP> of <SEP><SEP> photodiode <SEP> to
<tb> avalanche <SEP> APD. <SEP> The <SEP> card <SEP> returns <SEP> a <SEP><SEP> value for <SEP> the <SEP><SEP> rate of
<tb><SEP> count of <SEP> photons <SEP> to <SEP> a <SEP><SEP><SEP> detection <SEP> application of intruders
<tb> running <SEP> on <SEP> the personal <SEP> computer. Figure 2 shows a second example of a system embodying the present invention. In this case, the multiple optical input points 3 of the system of FIG. 1 are replaced by multiple combined I / O points 3. As in the first example, optical access points are connected to a passive optical network (PON ) with a tree topology. passive optical network is connected at its headend to a pulsed optical source 1. Each entry / exit point directs a light beam to a broadcast target 2. The broadcast from the target and another backscatter eventual from the walls of the room and / or objects of the room creates a complex network of sensor paths. The scattered light is received at the level of the multiple input / output points and is transmitted via the passive optical network via an optical circulator to an optical detection system 5. The detection system 5, as in the first example includes an isolated photon detector and a narrow band filter. The output of the detection system is processed by a personal computer running the intruder detection application, as previously described with respect to Fig. 1. A suitable circulator is commercially available as Model 0803-A (New Focus Inc). .).

Figure 3 shows a third system example embodying the present invention. This example is generally similar to the system of Figure 2 except that the combined I / O points of Figure 2 are replaced by separate access points for optical output and inputs. optical, respectively. The optical output points are distributed at different locations in space and are connected via a first passive optical network to a conventional source. The optical inputs are connected via a second passive optical network to the optical detection system described above with reference to FIG. In the examples considered so far, the optical signals undergo a loss in their path through the passive optical back network. that is, if, for example, we have 10 sensors (1:10 separator) there will be a loss of 10 dB for each photon entering the receiving network. With large numbers of sensors, this would limit the count rate received and thereby reduce the efficiency of the system. However, if ambient light collection is not a limiting factor of the system, a wider bandwidth source (and a matched filter) can be used together with WDM (Length Division Multiplexing) techniques. waveform) to reduce the loss on the track for individual sensors. For example, if we use a source with a central wavelength L and a wide bandwidth, dL, the separator can be replaced by a networked waveguide multiplexer (AWG) that divides the light on the single fiber input example 10 output fibers, each carrying a distinct wavelength wavelength -dL / 10 (i.e. each sensor now operates at a different wavelength dispersed over the range L- dL / 2 to L + dL / 2). The receiving PON will now contain another AWG multiplexer in place of a splitter that recombines the wavelengths on a single output fiber that is connected to the detector. In principle, the loss in each return channel can be reduced to zero using this technique, although in practice the improvement will depend on the loss of the AWG multiplexer (these are widely available components commonly used for multiplexing and demultiplexing in dense WDM multiplexing communications systems). Short pulses are still used in this embodiment to preserve the resolution over time, but the pulses are now strongly frequency-modulated to provide the wider bandwidth required by this embodiment. A suitable AWG multiplexer device is commercially available as AWG-MD-lx32 from Photonic Integration Research Inc.

Figure 4 shows a detection system employing wavelength multiplexing as described above. The detection system is broadly similar to that of Figure 2 in that it uses combined optical output / input points. However, instead of the separator used to combine the signals from the branches of the optical network into the system of Figure 2, a networked waveguide multiplexer (AWG) is used.

 For ease of illustration, the figure represents only four branches of the optical network and four corresponding wavelength channels. In practice more branches and more channels can be used. For example, ten channels may be used as described above. It should be noted that in this embodiment, the sensors 1 to 10 each have distinct output wavelengths L1 to L10. Any given sensor (number 1 for example) can receive / collect scattered photons having wavelengths in the range of L1 to L10, because these photons could originate from any of the sensor outputs. However, due to the effect of wavelength filtering of the AWG multiplexer, only the wavelength photons L1 received by the sensor 1 will reach the detector. That is to say that each sensor will "see" only its own photons in return. So that unlike the previous embodiment, no crosstalk between the sensors is possible and therefore the number of possible detection paths is reduced.

 The AWG multiplexer device described above is also suitable for use in the systems of our pending GB9906208.5 application filed March 17, 9, the contents of which are hereby incorporated by reference. FIG. 5 shows a system of this type in which a source of frequency-modulated isolated photon pulses is connected via a first AWG multiplexer and a corresponding first passive optical network to produce multiple beams in the beam. 'free space. The beams are received at corresponding optical input points, are transmitted through a second passive optical network 8b and are connected via a second AWG multiplexer to a single optical fiber 4 which transmits them. to the optical detection system 5.

Claims (2)

An intruder detection method comprising a) transmitting an optical signal, b) detecting the optical signal, and c) triggering an indication of an intrusion in response to a variation of the detected optical signal. characterized in that step (b) comprises receiving optical signals broadcast at a number of inputs. optics distributed in space. The method of claim 1 comprising transmitting optical signals from the plurality of spatially distributed optical inputs to a common detector. The method of claim 2 including applying different respective delays to received signals at different optical inputs. A method as claimed in any preceding claim including detecting the optical signal using an isolated photon detector. A method according to any preceding claim, wherein the optical signal is a narrowband signal, and the optical signal detection step comprises passing the optical signal through a narrowband filter adapted to the tape source. narrow. . an intruder detection system comprising a) an optical signal source, b) an optical detection system, and c) a processor connected to the optical detection system and arranged to trigger an indication of an intrusion in response to a variation of the detected optical signal, characterized in that the optical detection system (b) comprises a certain number of spatially distributed optical inputs. 7. System according to claim 6, comprising a number of optical outputs distributed in one space. The system of claim 7 comprising a number of combined optical input / output points. 9. System according to any one of claims 6 to 8, wherein the plurality of spatially distributed optical inputs are connected in common to a single detection system. The system of any one of claims 6 to 9, wherein the optical detection system comprises an isolated photon detector. An intruder detection method comprising a) transmitting an optical signal, b) detecting the optical signal, and c) triggering an indication of an intrusion in response to a variation of the detected optical signal. , characterized in that in step (b) the signal is detected by an isolated photon detector. An intruder detection method comprising a) transmitting an optical signal, b) detecting the optical signal, and c) triggering an indication of an intrusion in response to a variation of the detected optical signal. characterized in that step (a) comprises scoring optical signals at a number of different wavelengths and in step (c) signals from a number of different locations. spaced apart inputs are connected to a common detector via a wavelength multiplexer. The method of any one of claims 1 5, wherein step (a) comprises transmitting signals at a number of different wavelengths and at step (c) signals from a plurality of different wavelengths. a number of spatially distributed input locations are connected to a common detector via a wavelength multiplexer.