[0001] This invention relates to the detection of a change in a pattern of radiation and
is concerned especially, though not exclusively, with the detection of such a change
as a result of the movement of an object and/or of its shadow and/or of an image of
an object, such as, for example, a television picture thereof. The term "radiation"
throughout this specification is to be taken to include ultra-violet radiation, visible
light and infra- red radiation.
[0002] In one of its applications, the invention has for its aim the provision of an improved
apparatus and method for the security, in the sense of protection from theft or improper
handling, of works of art in general and pictures in particular. In this connection,
insurers of high value works of art do not favour having any devices in direct contact
with a picture or, for that matter, its frame or mounting. In addition, when such
a picture is displayed in a public gallery or museum or in the private premises of
its owner, it is generally desired that nothing overt in the way of apparatus should
detract from appreciation of the picture.
[0003] An obvious and frequently used method of protection as aforesaid is to use "space"
or "volume" detectors capable of indicating the intrusion of an object or person into
a defined area, a signal being obtained by noting a change from steady state conditions
such as, for example, the movement of the intruding object.
[0004] This is most commonly achieved by irradiating the area under surveillance with either
centimeter or millimeter wave energy or with ultrasonic acoustic energy and detecting
standing wave or Doppler effects caused by a moving object. There are obvious difficulties
in connection with the above. For example, electro-magnetic radiation cannot be readily
constrained to a precise area due to restraints in aerial design and reflections from
stationary objects and a tendency to "leak" through windows can lead to alarm signals
from moving objects outside the area under surveillance. In the case of the acoustic
approach there are difficulties in restricting the area under surveillance and false
alarm conditions can be set up due to air movements such as draughts and thermal disturbances
caused by central heating and ventilation, as well as by man made ultrasonic noise
such as leaking compressed air or motor or engine noise. Both radio and acoustic devices
have to be positioned carefully and frequencies have to be selected to avoid mutual
interference between neighbouring equipment. In the case of radio detector equipment,
at least in the United Kingdom, special licence clearance is needed.
[0005] Other methods of detection make use of infra-red radiation as one or more beams interrupted
or modified in intensity by a moving object. Alternatively, in a passive system the
thermal radiation from a human or animal body is detected. There are difficulties
associated with the techniques hereinbefore outlined due to the reflectivity or the
absorptivity of clothing in the infra-red region and variations in ambient temperature,
the latter being of most significance when detecting very small signals due to body
radiation.
[0006] Many ingenious techniques have been developed to minimise these various problems
but they all have drawbacks and tend to increase the complexity and cost of the apparatus
involved.
[0007] The present invention provides a technique of space or volume surveillance using
optical methods depending on the illumination of a scene with, for example, visible
and/or near infra-red radiation be this daylight or radiation from an artificial light.
source, using inexpensive optical components and being capable of overcoming many
of the difficulties referred to above.
[0008] According to the invention, there is provided apparatus for detecting a change in
a pattern of radiation incident on the apparatus, wherein lens means, a first sens-
. ing means sensitive to said incident radiation and adapted to give a first output
signal characteristic of said pattern, and a second such sensing means, adapted to
give a second such output signal, said sensing means having different configurations
and/or orientations of radiation-sensitive areas and said lens means together with
said sensing means constituting an optical system, are arranged for incidence on said
sensing means through said lens means of said radiation, and connected to comparator
means in such a way that the latter receives said output signals, the arrangement
being such that any change in said pattern of radiation causes a first consequent
change in said first output signal and a second consequent change in said second output
signal, said second consequent change being different from said first consequent change
by virtue of said different configurations and/or orientations of radiation-sensitive
areas, and said comparator means being arranged to supply a signal which is a function
of the said differing output signals and hence indicative of a change in said pattern
of radiation.
[0009] The said sensing means may each comprise a combination of a radiation sensitive cell
and a mask, the mask being interposed between the source of radiation and the cell
and including alternate areas opaque to and transparent to the radiation.
[0010] Alternatively, each sensing means may be a radiation sensitive cell having at least
one radiation sensitive area formed in a pre-determined pattern.
[0011] The apparatus can be arranged to survey a specified area and to operate at short
or long range as determined by the configuration of the optical system employed. Large
optical apertures can be used so as to achieve a low light capability without the
performance of the apparatus being seriously affected by the consequent restriction
in the depth of field.
[0012] The apparatus can operate with substantially constant sensitivity from a very high
illumination level down to a low and eventually a minimum level, and may be adapted
to initiate an alarm at such a minimum illumination level.
[0013] In one embodiment of the invention, no focusing of the optical system is needed in,
for example, a range of 2 metres to 100 metres. This embodiment at a high sensitivity
setting can detect a walking child at a distance of 100 metres.
[0014] By choice of optical system parameters the ability to detect a very small object
and/or a very rapidly moving object can be so reduced as to lessen the possibility
of a false alarm.
[0015] The apparatus is substantially unaffected by air movements, by ambient temperature
changes or by slow changes in ambient illumination. The apparatus responds equally
well to light reflected from a moving object or to a "silhouette" of such an object.
This means that shadows passing over a scene are detecting as moving objects.
[0016] The nature of the iluumination is not critical. The use of incandescent, gas discharge
or flourescent lighting operating on normal alternating current supply (50Hz) or direct
current supply is satisfactory and movement detection in a scene reproduced on a television
screen or screens is possible in spite of the nature of the scanning process.
[0017] The minimum speed of movement of an object to be detected can be set at such a low
value that it becomes effectively impracticable to introduce or to remove an object
from the field of view of the apparatus without detection. Further, the absence of
lateral or vertical movement of an object will not avoid detection as movement towards
or away from the apparatus will also yield a movement signal.
[0018] Successful tampering with the apparatus becomes extremely difficult because the movement
of the apparatus is equivalent to movement of the complete scene and would cause an
alarm to be initiated. The low power consumption of the apparatus permits the use
of self contained batteries, thus avoiding any external connections. The alarm signal
may, for example, be given either by a light signal or acoustically or both. The output
signal from the comparator means produced by movement observed by the apparatus may
be used or processed in accordance with any of the established techniques well known
to those skilled in the art.
[0019] A method of detecting a change in a pattern of radiation emanating, for example,
from an article such as a work of art or from a scene under surveillance comprises
causing the said radiation to form or to be so refracted that in the absence of obstruction
or of further refraction it would form two essentially identical but spatially displaced
images, causing predetermined zones of the radiation which forms or which would form
one of the images to impinge on the radiation sensitive member of a first radiation
sensitive device and predetermined but different zones of the radiation which forms
or which would form the other image to impinge on the radiation sensitive member of
a second radiation sensitive device, the sizes and dispositions of the said zones
being such that when the article or scene under surveillance and hence the pattern
of radiation emanating therefrom is undisturbed, the output signals from each of the
radiation sensitive devices remain in a predetermined relationship with each other,
but that when there is any change in the pattern of radiation forming the images,
the resulting change or changes in the pattern of radiation incident on each of the
said radiation sensitive devices will be different for each of the said devices and
will cause one or more changes in the relationship between the output signals from
them.
[0020] The resulting change or changes may be used to activate an indicating device or an
alarm.
[0021] The radiation-sensitive devices may be light-sensitive cells, such as cadmium sulphide
cells and preferably, the signal outputs from each of the radiation-sensitive devices
are substantially equal when an article or scene, for example, under surveillance
is undisturbed.
[0022] One form of apparatus embodying the invention and modifications thereof will now
be described, by way of example only, with reference to the accompanying diagrammatic
drawings in which:-
Figure 1 is a perspective view of the basic optical integers of the apparatus;
Figure 2 shows an electrical bridge circuit employed in the apparatus;
Figure 3 shows masks in the form of so-called "bar gratings" forming part of the sensing
means of the apparatus, and the effect on the output signals from said sensing means
and from the comparator means by a moving object detected by the apparatus;
Figure 4 shows a simplified practical electrical circuit of the apparatus;
Figure 5 shows the optical system of a modified form of the apparatus and
Figure 6 is a fragmentary perspective view of yet another modification of the optical
system of the apparatus.
[0023] Referring firstly to Figures 1 to 3, the apparatus comprises twin optical systems
in close juxtaposition, each consisting of lens means 1 arranged to produce an image
of the scene under surveillance in an image plane 2. The images so produced will have
the same information content and will be of the same brightness. Light passing through
the image plane is gathered by means of a lens system 3 and the emerging light falls
upon first and second devices 4a, 4b, the said devices being sensitive to the light.
The devices 4a, 4b are opto-electronic transducers, such as light dependent resistors,
for example, cadium sulphide cells. The optical arrangement is preferably one which
gives no movement of the illumination on the cells when movement takes place in the
scene and consequently at the image plane. The resistance of each device 4a, 4b gives
a measure of the mean brightness of its related optical image.
[0024] If the two devices 4a, 4b are of equal sensitivity and are connected in an electrical
bridge circuit such as that shown in Figure 2, the potential difference between output
terminals 5 and 6 of the bridge circuit will remain zero at all times when the average
illumination of each device is equal. Under these circumstances no potential difference
will appear if there is a brightness change of the original scene.
[0025] Let us now assume, that in the absence of the "bar gratings" hereinbefore mentioned
(Figure 3) the scene being viewed is a plain white background and that a black rectangular
object enters the viewed area from one side, traversing the area and leaving from
the other side. The average brightness of both images of the scene will change, will
become progessively less until the black rectangle is fully within the viewed area,
will remain constant at this value until the black rectangle leaves the scene whereupon
an increase in brightness to the original value will take place.
[0026] Provided the characteristics of the two optical systems and their transducers are
precisely matched, there will have been no electrical signal at the bridge terminals
5,6.
[0027] In the image plane 2 there are "bar gratings" 8a, 8b having equal bar and slot widths,
as shown in Figure 3. However, the longitudinal axes of the bars of one of the two
optical systems is at an angle of, say, 90 degrees to the longitudinal axes of the
bars of the other optical system. Thus the devices 4a 4b together with their associated
bar gratings 8a 8b define respectively a first and a second sensing means having different
configurations of radiation-sensitive areas. For the unobstructed white scene, the
mean value of optical flux reaching each of the devices 4a 4b is reduced by 50%.
[0028] The introduction of a black rectangle 7 as aforesaid now produces an entirely different
result. At first there will be a progressive reduction in light falling on both of
the devices 4a 4b but this reduction will not proceed at the same rate for both sensing
means, and when the rectangle 7 is fully within the image area, the light on one device
4a (i.e. the one associated with the bar grating 8a) will remain constant at a reduced
brightness (as shown by curve a) whereas the light on the other device 4b will alternate
in strength by virtue of the associated bar grating 8b as shown by curve b, the frequency
of the alterations being governed by the dimensions of the grating in relation to
the size of the image of the rectangle 7 and its rate of movement across the grating.
[0029] As the electrical output signals of the devices 4a, 4b are "bridged" and are in effect
in opposition, the output from the bridge circuit will represent the difference of
the output signals from the devices. This is illustrated by curve c. In theory there
will be a generally diagonal path of movement of the rectangle image 7 in relation
to the bar gratings 8a, 8b, which will yield a zero output from the-bridge circuit.
In fact, this is extremely unlikely to happen because regular geometric shapes and
the uniform illumination of the field under surveillance rarely occur in practice.
Further, the fact that the shadow of an object generally fails to follow a path identical
to that of the object itself would introduce a further complication.
[0030] The bars of the gratings 8a, 8b need not be straight and the slots need not be of
uniform width along their lengths, provided that the obscuration is the same for both-of
the sensing means.
[0031] The output signals from the bridge circuit or other suitable comparator means may
be amplified by low frequency alternating current amplifiers, and processed in any
of the ways well understood by those skilled in the art.
[0032] There is, however, a further aspect of the invention that suggests that the initial
stages of electrical amplification should preferably include, or perform as, a "low
pass" filter such that frequency components above a chosen frequency shall not be
appreciably amplified. A typical choice for the cut-off frequency is for example about
15Hz to 20Hz.thus permitting the use of light sources operating from an alternating
current supply, which, in consequence, have some brightness modulation. This modulation
will normally be at twice the supply frequency but may have components at the fundamental
frequency.
[0033] Further, such low pass filtering can be arranged to permit the apparatus to be used
for viewing a television raster or rasters without disturbance from frame flicker
frequencies.
[0034] In practice it can be shown that sharp focus and image perfection is not required
in the apparatus described, provided the two sensing means and the associated optical
systems are substantially identical, and it has been found possible to employ moulded
components in the form of large aperture plastic aspheric lenses. Objects may lie
at widely differing distances from the apparatus without detriment to its operation.
[0035] The use of such moulded optical components offers the possibility of constructing
the complete optical assembly as a single moulding comprising lenses, masks and cell
mounting, thus improving rigidity and reducing manufacturing and assembly costs.
[0036] Further, the devices 4a, 4b, typically cadmium sulphide cells, although other types
can of course be employed, could with advantage be manufactured as a single, three-
electrode device having two radiation sensitive areas which could be made to have
closely matching characteristics. Yet again, in a somewhat simplified form of apparatus,
the radiation sensitive devices may be made with the radiation sensitive areas in
the form of strips separated by non- sensitive areas, thus eliminating the need for
separate gratings 8a, 8b and the associated lenses 3. Such a form of apparatus is
illustrated in Figure 6.
[0037] Experience shows that exact alignment of the two optical paths is unnecessary.
[0038] A further form of optical system is shown in Figure 5. In this system a single imaging
lens 1 is employed in conjunction with one of the various forms of "beam splitter"
9 such that two separate and identical images are formed and these are then used in
the same manner as for the apparatus described with reference to Figures 1 to 3. A
disadvantage of this system is that there is a reduction of about 50% in the intensity
of the light or other radiation incident on each of the devices 4a and 4b. Further,
the cost is higher due to the use of the beam splitter 9. The use of such an arrangement
may, however, be justified when it is desired to view a scene with a more specialized
and expensive optical system, such as for example a long range telephoto lens.
[0039] The simplified diagram of the electrical circuit (Figure 4) of the apparatus shows
not only the devices 4a, 4b, the bridge circuit of Figure 2, the aforesaid low pass
filter, an amplifier and a signal rectifier (all of conventional design and well understood
by those skilled in the art), said rectifier yielding a positive going voltage when
movement occurs in the scene under surveillance, but also a single comparator amplifier
stage arranged to produce an alarm signal when the mean illumination on the devices
4a, 4b falls below an operationally acceptable minimum. The two devices 4a, 4b connected
in series will draw current through a resistor 10, dependent on the incident illumination
and the lower the illumination the higher the total resistance of the devices and,
consequently the lower the current flowing through the resistor 10. This results in
a rising voltage across the devices with decreasing illumination and the comparator
stage relates this voltage to a pre-set reference voltage. The increasing voltage
across the devices, on passing a critical reference value, will cause the comparator
to change its output voltage and this signal can be used to trigger an alarm circuit.
To render the comparator insensitive to momentary fluctuations of brightness, a capacitor
11 is added to the circuit providing a resistance capacity time constant RC of suitably
chosen magnitude.
[0040] It will be appreciated that, although the invention has been particularly described
with reference to an optical system suitable for the protection of works of art from
theft and improper handling, the scope of the invention and its field of application
are both very much broader. Thus, the radiation incident on the apparatus may be at
a wavelength other than that of light, e.g. of infra-red or ultraviolet, and the change
in the pattern of radiation need not necessarily be caused by the movement of an object,
but may, as previously indicated, be due to the movement of, or some other change
in, an image of such an object.
[0041] Among the possible applications of apparatus according to the invention are those
in which, a "warning"or "count" signal is required in the event of a change in a scene
under surveillance, whilst others require a signal which represents an "alarm" condition
with the necessary low incident of false alarms. The following are some of these applications:
1. Protection of individual works of art or exhibits.
2. Guarding access to strong rooms, strong room doors, safe deposits and safes.
3. General space protection.
4. Surveillance of security TV screens to warn of scene changes.
5. Watch over sleeping or unconscious patients in medical care.
6. "Baby" alarm.
7. Surveillance of entries and vehicle areas of car parks, particularly underground
or multistorey car parks.
8. Remote surveillance of hostage conditions.
9. Remote counting of persons.
10. Remote counting of vehicles.
11. Remote counting of components etc. as in produc tion lines.
12. Warning of failure of moving apparatus particularly where conditions are dirty
or hazardous, as in chemical plants and nuclear installations. For an application
of this type the apparatus of the invention would be used in such a way that an output
would be produced when movement ceases rather than when movement is detected. This
could be done by causing the signal due to movement to hold open a normally closed
switch in an alarm circuit. Cessation of movement would then remove the signal from
the switch and thus allow it to close so that the alarm would be sounded.
1. Apparatus for detecting a change in a pattern of radiation incident on the apparatus,
comprising lens means, a first sensing means sensitive to said incident radiation
and adapted to give a first output signal characteristic of said pattern, and a second
such sensing means, adapted to give a second such output signal, said sensing means
having different configurations and/or orientations of radiation-sensitive areas and
said lens means together with said sensing means constituting an optical system, are
arranged for incidence on said sensing means through said lens means of said radiation,
and connected to comparator means in such a way that the latter receives said output
signals, the arrangement being such that any change in said pattern of radiation causes
a first consequent change by virtue of said different configurations and/or orientations
of radiation-sensitive areas, and said comparator means being arranged to supply a
signal which is a function of the said differing output signals and hence indicative
of a change in said pattern of radiation.
2. Apparatus according to claim 1 wherein each sensing means comprises a combination
of a radiation sensitive cell and a mask with the mask interposed between the source
of radiation and the cell and including alternate areas which are opaque to and transparent
to the radiation.
3. Apparatus according to claim 1 wherein each sensing means is a radiation sensitive
cell having at least one sensitive area formed in a predetermined pattern.
4. Apparatus according to any preceding claim including an alarm or indicating device
operable upon receipt of the output signal from the comparator.
5. Apparatus according to claim 3 or claim 4 wherein the radiation sensitive cell
is light sensitive and wherein the signal outputs from each said cell are substantially
equal in a normal undisturbed state.
6. A method of detecting a change in a pattern of radiation emanating from a subject
under surveillance comprises causing the said radiation to form or to be so refracted
that in the absence of obstruction or of further refraction it would form two essentially
identical but spatially displaced images, causing predetermined zones of the radiation
which forms or which would form one of the images to impinge on the radiation sensitive
member of a first radiation sensitive device and predetermined but different zones
of the radiation which forms or.which would form the other image to impinge on the
radiation sensitive member of a second radiation sensitive device, the sizes and dispositions
ofthe said zones being such that when the article or scene under surveillance and
hence the pattern of radiation emanating therefrom is undisturbed, the output signals
from each of the radiation sensitive devices remain in a predetermined relationship
with each other, but that when there is any change in the pattern of radiation forming
the images, the resulting change or changes in the pattern of radiation incident on
each of the said radiation sensitive devices will be different for each of the said
devices and will cause one or more changes in the relationship between the output
signals from them.
7. A method according to claim 6 wherein the resulting change or changes is used to
activate an alarm or indicating device.