AU586454B2

AU586454B2 – Ultraviolet radiation monitoring device
– Google Patents

AU586454B2 – Ultraviolet radiation monitoring device
– Google Patents
Ultraviolet radiation monitoring device

Info

Publication number
AU586454B2

AU586454B2
AU51918/86A
AU5191886A
AU586454B2
AU 586454 B2
AU586454 B2
AU 586454B2
AU 51918/86 A
AU51918/86 A
AU 51918/86A
AU 5191886 A
AU5191886 A
AU 5191886A
AU 586454 B2
AU586454 B2
AU 586454B2
Authority
AU
Australia
Prior art keywords
timing function
prescribed timing
signal
magnitude
radiation
Prior art date
1984-11-26
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)

Ceased

Application number
AU51918/86A
Other versions

AU5191886A
(en

Inventor
Anthony Paul Pearson
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)

HEALTHRONICS Ltd

Original Assignee
HEALTHRONICS Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
1984-11-26
Filing date
1985-11-26
Publication date
1989-07-13

1985-11-26
Application filed by HEALTHRONICS Ltd
filed
Critical
HEALTHRONICS Ltd

1986-06-18
Publication of AU5191886A
publication
Critical
patent/AU5191886A/en

1989-07-13
Application granted
granted
Critical

1989-07-13
Publication of AU586454B2
publication
Critical
patent/AU586454B2/en

2005-11-26
Anticipated expiration
legal-status
Critical

Status
Ceased
legal-status
Critical
Current

Links

Espacenet

Global Dossier

Discuss

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Classifications

A—HUMAN NECESSITIES

A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE

A61B—DIAGNOSIS; SURGERY; IDENTIFICATION

A61B5/00—Measuring for diagnostic purposes; Identification of persons

A61B5/44—Detecting, measuring or recording for evaluating the integumentary system, e.g. skin, hair or nails

A61B5/441—Skin evaluation, e.g. for skin disorder diagnosis

A61B5/444—Evaluating skin marks, e.g. mole, nevi, tumour, scar

A—HUMAN NECESSITIES

A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE

A61B—DIAGNOSIS; SURGERY; IDENTIFICATION

A61B5/00—Measuring for diagnostic purposes; Identification of persons

A61B5/0059—Measuring for diagnostic purposes; Identification of persons using light, e.g. diagnosis by transillumination, diascopy, fluorescence

A—HUMAN NECESSITIES

A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE

A61B—DIAGNOSIS; SURGERY; IDENTIFICATION

A61B5/00—Measuring for diagnostic purposes; Identification of persons

A61B5/72—Signal processing specially adapted for physiological signals or for diagnostic purposes

A61B5/7235—Details of waveform analysis

A61B5/7242—Details of waveform analysis using integration

A—HUMAN NECESSITIES

A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE

A61N—ELECTROTHERAPY; MAGNETOTHERAPY; RADIATION THERAPY; ULTRASOUND THERAPY

A61N5/00—Radiation therapy

A61N5/06—Radiation therapy using light

G—PHYSICS

G01—MEASURING; TESTING

G01J—MEASUREMENT OF INTENSITY, VELOCITY, SPECTRAL CONTENT, POLARISATION, PHASE OR PULSE CHARACTERISTICS OF INFRARED, VISIBLE OR ULTRAVIOLET LIGHT; COLORIMETRY; RADIATION PYROMETRY

G01J1/00—Photometry, e.g. photographic exposure meter

G01J1/42—Photometry, e.g. photographic exposure meter using electric radiation detectors

G01J1/429—Photometry, e.g. photographic exposure meter using electric radiation detectors applied to measurement of ultraviolet light

G—PHYSICS

G01—MEASURING; TESTING

G01J—MEASUREMENT OF INTENSITY, VELOCITY, SPECTRAL CONTENT, POLARISATION, PHASE OR PULSE CHARACTERISTICS OF INFRARED, VISIBLE OR ULTRAVIOLET LIGHT; COLORIMETRY; RADIATION PYROMETRY

G01J1/00—Photometry, e.g. photographic exposure meter

G01J1/42—Photometry, e.g. photographic exposure meter using electric radiation detectors

G01J1/44—Electric circuits

G01J1/46—Electric circuits using a capacitor

G—PHYSICS

G01—MEASURING; TESTING

G01J—MEASUREMENT OF INTENSITY, VELOCITY, SPECTRAL CONTENT, POLARISATION, PHASE OR PULSE CHARACTERISTICS OF INFRARED, VISIBLE OR ULTRAVIOLET LIGHT; COLORIMETRY; RADIATION PYROMETRY

G01J1/00—Photometry, e.g. photographic exposure meter

G01J1/02—Details

G01J2001/0257—Details portable

G—PHYSICS

G01—MEASURING; TESTING

G01J—MEASUREMENT OF INTENSITY, VELOCITY, SPECTRAL CONTENT, POLARISATION, PHASE OR PULSE CHARACTERISTICS OF INFRARED, VISIBLE OR ULTRAVIOLET LIGHT; COLORIMETRY; RADIATION PYROMETRY

G01J1/00—Photometry, e.g. photographic exposure meter

G01J1/42—Photometry, e.g. photographic exposure meter using electric radiation detectors

G01J1/44—Electric circuits

G01J2001/4406—Plural ranges in circuit, e.g. switchable ranges; Adjusting sensitivity selecting gain values

Abstract

A diminutive ultraviolet radiation monitoring device comprising a sensor (10, 35), integrator (22, 43) and control (17, 51). The sensor (10, 35) senses impinging ultraviolet radiation and generates a sensing signal commensurate to the magnitude of the radiation. The integrator (22, 43) integrates the sensing signal in accordance with a first timing function related to an admonished accumulative effect of the radiation on a person’s skin, and generates an active signal proportional to the integration. The control (17, 51) monitors the active signal and issues an alarm when it attains a threshold level related to the optimum cumulative radiation to which the skin is desired to be exposed. The integrator includes a memory (16, 45) to store the active signal magnitude and allows the magnitude to diminish in acordance with a second timing function related to an admonished decay in the residual effect of the previous radiation on the skin after it is removed from the radiation or vice versa.

Description

“Ultraviolet Radiation Monitoring Device”
THIS INVENTION relates to an electromagnetic radiation monitoring device which is particularly applicable to monitoring the amount of ultraviolet radiation falling upon a body such as the exposed skin of a person and pro¬ viding an indication to the person when an optimum amount of ultraviolet radiation has been absorbed over a period of time.
In the past two hundred years, many millions of Caucasians have emigrated from temperate and cool climates to warmer tropical climates throughout the world, vis. America, South Africa, Australia, Israel, South East Asia et al. In light of the fact that it takes thousands of years for any biological change to occur in man, these immigrants and their hereditary offspring in future generations will very probably suffer from one form of skin cancer, or another. This is largely attributed to the absorption of an excessive * amount of ultraviolet radiation by such persons in their biologically new environment, which may far exceed the level of ultraviolet radiation to which their bodies are accustomed, and, in fact are biologically capable of absorbing without detriment.
In Australia, particularly, it has become socially expe¬ dient for persons to acquire a suntan of their skins and so beachgoers and holiday makers spend a significant portion of their time sunbathing in the summer months. In most cases, such persons shall expose themselves to abnor¬ mal levels of ultraviolet radiation. unfortunately, statistics show this activity to be extremely dangerous since it is considered to be a major contributing cause to skin cancer. In Australia alone, approximately six people die of skin cancer every week, and many tens of thousands more receive medical and surgical treatment for skin cancer related complaints every year. In the majority of cases, the afflicted person was totally ignorant of the

fact that he or she could be exposed to a dangerous level of ultraviolet radiation by obtaining a bad sunburn on a minimal number of occasions.
It is an object of the present invention to provide moni¬ toring of electromagnetic radiation impinging a body and provide a sensorially perceptible alarm when the cumula¬ tive radiation to which the body is exposed attains a threshold level.
It is a preferred, although not essential, object of the invention to provide a device for monitoring ultraviolet radiation in accordance with a prescribed method which device is capable of being embodied as a self-contained, diminutive and portable unit, which can be carried on one’s person during exposure to ultraviolet radiation.
In accordance with one aspect of the present invention, there is provided a device for monitoring electromagnetic radiation comprising: a sensing means for sensing radia¬ tion impinging a body and to generate a sensing signal proportional to the magnitude of said impinging radiation; an integrating means to integrate said sensing signal in accordance with a first prescribed timing function and generate an active signal proportional to the magnitude of said integration; and control means to monitor the rela¬ tive magnitude of said active signal and generate a sen¬ sorially perceptible signal in response to said active signal magnitude attaining a threshold level; wherein said first prescribed timing function is related to an admoni¬ shed accumulative effect of said impinging radiation on said body and said threshold level is related to the optimum cumulative radiation to which said body is desired to be exposed.

Preferably, the integrating means includes memory means to store said active signal magnitude and allow the active signal magnitude to diminish in accordance with a second prescribed timing function in response to a reduction in said sensing signal magnitude, said second prescribed timing function being related to an admonished decay in the residual effect of previously impinging radiation on said body pursuant to said body being removed from said impinging radiation of vice versa.
Preferably, the integrating means includes selector means to select different first prescribed timing functions.
Preferably, the integrating means is adapted to generate a reference signal which defines said threshold level and said control means includes comparator means to compare the relative magnitudes of said active signal and said reference signal to detect when said active signal mag¬ nitude attains the threshold level specified by said reference signal.
Preferably, the reference signal is generated by inte¬ grating said sensing signal in accordance with a third prescribed timing function, said third prescribed timing function comprising initial and subsequent components, said initial component providing an initial integration at a greater rate than said first prescribed timing function, and said subsequent component providing a subsequent integration at a lesser rate than said first prescribed timing function.
Preferably, the integrating means includes a further memory means to store said reference signal magnitude and allow the reference signal magnitude to diminish in accor¬ dance with a fourth prescribed timing function in response to a reduction in said, sensing signal magnitude, the rate

of decay as provided by said fourth prescribed timing function being significantly less than the rate of decay as provided by said second prescribed timing function.
Preferably, either or both of the memory means may be independently reset by a further switching means.
Preferably, the control means includes a transducing means to generate said sensorially perceptible signal, and an electronic switching means to activate said transducing means on detection of said active signal magnitude attain¬ ing said threshold level.
Preferably, the control means includes triggering means to incite generation of said sensorially perceptible signal for a short period on supplying power to said device.
Preferably, the sensing means includes delay means to negative its function substantially during said short period.*-
Preferably, the sensing means includes filtering means and detecting means, said filtering means being characterised to only allow electromagnetic radiation in the ultraviolet region of the electromagnetic spectrum to impinge said detecting means, and said detecting means being enhanced to accurately detect the impinging radiation in said region and to generate said sensing signal in response thereto.
In accordance with another aspect of the present inven¬ tion, there is provided a method for monitoring electro¬ magnetic radiation comprising the steps of:-

sensing radiation impinging a body; generating a sensing signal proportional to the magnitude of said impinging radiation; integrating said sensing signal in accordance with a first prescribed timing function; generating an active signal proportional to the magnitude of said integration; monitoring the relative magnitude of said active signal; and generating a sensorially perceptible signal in res¬ ponse to said active signal magnitude attaining a threshold level;
wherein said first prescribed timing function is related to an admonished accumulative effect of said impinging radiation on said body and said threshold level is related to the optimum cumulative radiation to which said body is desired to be exposed.
Preferably, the method includes the step of storing said active signal magnitude and allowing the active signal magnitude to diminish in accordance with a second pres¬ cribed timing function in response to a reduction in said sensing signal magnitude, said second prescribed timing function being related to an admonished decay in the residual effect of previously impinging radiation on said body pursuant to said body being removed from said im¬ pinging radiation or vice versa.
Preferably, the method includes the step of generating a reference signal which defines said threshold level and comparing the relative magnitudes of said active signal and said reference signal to detect when said active sig¬ nal magnitude attains the threshold level specified by said reference signal.

Preferably, the method includes the step of integrating said sensing signal in accordance with a third prescribed timing function to generate said reference signal, said third prescribed timing function comprising initial and subsequent components, said initial component providing an initial integration at a greater rate than said first prescribed timing function, and said subsequent component providing a subsequent integration at a lesser rate than said first prescribed timing function.
Preferably, the method includes the step of storing said reference signal magnitude and allowing the reference signal magnitude to diminish in accordance with a fourth prescribed timing function in response to a reduction in said sensing signal magnitude, the rate of decay as provi¬ ded by* the fourth prescribed timing function being signi¬ ficantly less than the rate of decay as provided by said second prescribed timing function.
The invention will be better understood in the light of the following description of several specific embodiments thereof. The description is made with reference to the accompanying drawings wherein:-
Fig. 1 is a block diagram of the monitoring device in accordance with the first embodiment of the inven¬ tion;
Fig. 2 is a circuit diagram of the monitoring device in accordance with the second embodiment of the invention;
Fig. 3 is a plan view of the physical arrangement of the monitoring device; and Fig. 4 is a side elevation of Fig. 3.
The first embodiment is directed towards an ultraviolet radiation monitoring device of diminutive size to enable the device to be worn on one’s person.

ith reference to Figs. 1, 3 and 4, the device comprises an outer casing 25 which encapsulates an electronic cir¬ cuit, generally shown at Fig. 1, and appropriate trans¬ ducers.
The casing 25 is provided with a window 27 which forms a surface 29 beneath which is located a sensing means 10 (see Fig. 1) comprising a filtering means 11 and detecting means 12. The filtering means 11 is a special ultraviolet filter which allows only ultraviolet radiation in the wavelength range of 290 nanometres to 400 nanometres to impinge the detecting means 12. This range is better known as including the UVA (320 nm to 400 nm) and the ϋVB (290 nm to 320 nm) types of ultraviolet radiation, the latter being the type that actually causes sunburn of the skin and the former being the type that causes wrinkling of the skin. The detector means 12 is a special type of transducer, being an enhanced silicon detector which provides a sensing signal in the form of an electric potential across a pair of terminals in response to im¬ pinging radiation. The magnitude of the signal is propor¬ tional to the instantaneous magnitude of the impinging radiation at any point in time. The output terminals of the detecting means 12 are in turn connected to a preamp¬ lifier 13 which amplifies the sensing signal created by the electric potential.
The output of the preamplifier 13 is connected to an integrating means 22 which includes a selector means 14, first resistor means 15, and memory means 16.
The selector means 14 is a single pole multi-throw switch, whereby a different value of first resistor means 15 is connected to respective terminals of the switch to accord with the designation of a first prescribed timing function of the integrating means. The first prescribed timing

function is related to an admonished accummulative effect of the impinging radiation on the body of a person. To effect integration of the sensing signal, the memory means 16 includes a capacitor means, thus forming an R-C cir¬ cuit. Accordingly the capacitor means stores charge dependent on the magnitude of the sensing signal at a rate prescribed by the time constant of the R-C circuit de¬ fining the first prescribed timing function.
The memory means also has a second resistor means (not shown) coupled in parallel with the capacitor means. The second resistor means provides a path for the capacitor means to discharge in the absence of the sensing signal magnitude. Accordingly the active signal magnitude is allowed to diminish at a rate determined by a second prescribed timing function which is defined by the time constant of the capacitor means and second resistor means. The second prescribed timing function is related to an admonished decay in the residual effect of previously impinging radiation on the body pursuant to said body being removed from said impinging radiation or vice versa.
The integrating means 22 consequently generates an active signal at its output proportional to the magnitude of the integration which output is connected to a control means 17.
The control means 17 effectively monitors the relative magnitude of the active signal and generates a sensorially perceptible signal in response to the active signal magni¬ tude attaining a threshold level. The control means 17 comprises a comparator means and electronic switching means 24 which is open in response to the capacitor means having a stored charge, represented by the active signal magnitude, below a prescribed threshold level determined by a preset reference signal magnitude at the comparator

means input, and is closed in response to the active signal magnitude exceeding the threshold level. The threshold level is related to the optimum cumulative radiation to which the body of a person is desired to be exposed. In the present embodiment, the electronic swit¬ ching means is of the relay type which is interposed between a power source 19 and a transducing means 18 which generates the sensorially perceptible signal providing an alarm.
The power source 19 is a d.σ. battery which is connected to a recharging circuit 20 comprising an encapsulated solar cell 26 disposed in juxtaposed relation to another window 28 of the casing. Serially connected between the transducing means and the switch is a photo electric switch 21. The switch is closed upon light impinging thereon and open in the absence of such, thereby providing additional means to disable operation of the device.
With reference to the physical arrangement of the device, as shown in Figs. 3 and 4, the selector means 14 is provi¬ ded in the form of a multi-range switch 32. Accordingly the switch is provided with a number of positions which accord with the selection of a specific first resistor means 15 of the integrating means 22. The windows 27, 28 for the sensing means 10 and solar cell 26 are disposed on a sloping face 34 of the casing which is arranged at an oblique angle to the base and ends of the casing 25. This is to enable the windows to be exposed to impinging ultra¬ violet radiation in most attitudes that the casing would be likely to presume when carried by a user of the device. To achieve the best results, the casing is attached to a clothing item such as the hat of a user, where the sloping face 34 can be exposed to the ultraviolet radiation source for example the sun, continuously, irrespective of whether the user is vertical or horizontal to the ground.

A cover 30 is attached to the casing to enable it to be moved from an open to a closed position and vice versa. In the closed position, the cover is adapted to impede the passage of ultraviolet radition and light to the filtering means 11 and the photo electric switch 21 respectively, thereby disabling the device. In the open position, this impediment is removed and the device maybe enabled for operation.
Alternately an on/off switch is provided next to the skin type selector switches.
In operation the device receives ultraviolet radiation through the filtering means 11 which discriminates between the various frequencies of the impinging radiation and only allows the pas -age of radiation which causes sunburn and wrinkling, i.e. UVB and UVA, respectively through to the detecting means 12. The detecting means then produces a potential that is ►proportional in magnitude to the amount or magnitude of radiation applied thereto and thus generates a sensing signal which is amplified by the preamplifier and subsequently applied to the integrating means 22. The integration performed by the integrating means in accordance with the first prescribed timing function effectively provides monitoring of the amount of harmful radiation falling upon the device over a period of time. Accordingly when the active signal magnitude, representing the amount of charge stored within the memory means, exceeds the threshold level, the control means activates the transducing means 18 which generates a sen¬ sorially perceptible signal to the user or wearer of the device.
In the absence of incident radiation passing through the filtering means, the stored charge in the storage means will not be replenished- and hence will effectively dimi-

nish in accordance with the second prescribed timing func¬ tion.
In practice, the rate that the active signal increases and diminishes is set to correspond to the adaptability of the skin of a user or wearer to absorb ultraviolet radiation. Thus the device will be very sensitive on the user’s first day of exposure to ultraviolet radiation, by selecting a first resistor means 15 to combine with the capacitor means of the memory means 16 to provide a first prescribed timing function imposing a relatively fast rate of in¬ crease of the active signal subject to the presence of the sensing signal. Accordingly the alarm will be activated after only a relatively short time of exposure to the sun. On subsequent days, as the Melanin in the skin of the user builds up, another first resistor means can be selected which combines with the capacitor means to provide a first prescribed timing function imposing a slower rate of increase in the active signal. Accordingly the alarm will be activated after a longer period of time of re-exposure of the user and the device to the radiation. Similarly as the skin of the user is progressively tanned, other first resistor means can be selected to provide longer delays. It should be noted however, that on the user sheltering himself from the sun, the active signal diminishes at a rate imposed by the second prescribed timing function. Thus the memory means operates to cater for situations where the user may be re-exposed to the ultraviolet radia¬ tion after only a short period of time has elapsed. In such cases the capacitor means would not be fully dis¬ charged and thus will cause the active signal to approach the threshold level after a very much shorter period of time than before. This is commensurate with the adapt¬ ability of the user’s skin to absorb further radiation after only a short relaxation from previous exposure, which in most cases is .not very great. The provision of

the selector means allows the device to be adjusted to match the different types of skin sensitivity of users of the device. In addition, the selector means allows a particular user to dampen the sensitivity of the device if the user has already acquired a partial tan before using the device, thereby increasing the allowable time of exposure of the skin to impinging ultraviolet radiation.
The second embodiment is directed towards an ultraviolet radiation monitoring device incorporating several improve- ments over the device described in the preceding embodi¬ ment. The present embodiment is described with reference to Figs. 2, 3 and 4 of the drawings.
As in the preceding embodiment, the present device gene¬ rally comprises a sensing means, integrating means and control means. The electronic circuitry of the sensing means is shown generally at 35 and includes a filtering means (not shown) and detector means 37 as described in the preceding embodiment.
The output of the detector means 37 is connected to the input of the preamplifier 39 which is in the form of an operational amplifier. As shown in Fig. 2, the opera¬ tional amplifier is connected in the non-inverting ampli- fyer mode, wherein the output of the detecting means 37 is connected to the non-inverting input of the operational amplifier 41 and the gain of the amplifier is provided by means of resistors Rl and R2. For the present applica¬ tion, these resistors are set to provide a gain of app¬ roximately 80. Coupled in parallel to resistor Rl in the feedback loop of the amplifier is a capacitor C5, which forms a delay means, the function of which shall be des¬ cribed in more detail later.

The output of the preamplifier 39 is connected to the integrating means 43, which generally comprises a memory means 45, a further memory means 47 and a selector means 49.
The selector means 49 comprises a plurality of differently valued first resistor means R3 to R7. These resistor means are arranged in order of increasing value and are arranged so that a single resistor can be coupled in series with the memory means 45 and the output of the preamplifier 39. The memory means 45 comprises a capaci¬ tor means Cl which combines with the particular selected first resistor means to provide a time constant which defines a first prescribed timing function. This first prescribed timing function is of a similar kind as defined in the first embodiment, but when considered in the con¬ text of the present embodiment, is determined on a sligh¬ tly different conceptual basis than the latter. This shall be discussed in more detail later.
Coupled in parallel to the capacitor means Cl is a second resistor means R8 which provides another time constant for the discharge of the capacitor means, so defining a second prescribed timing function. The second prescribed timing function is substantially identical to that described in the preceding embodiment.
The further memory means 47 comprises a further capacitor means C2 which is also connected to the output of the preamplifier, but via a third resistor means R9. The third resistor means R9 combines with the capacitor means C2 to provide a further time constant defining in part, a third prescribed timing function.
Coupled in parallel to the third resistor means R9 is a bypass capacitor means -C4 which also combines with the

further capacitor means C2 to define the other part of the third prescribed timing function.
Accordingly, the third prescribed timing function consists of an initial and a subsequent component, wherein the initial component is defined by the combination of the bypass capacitor means C4 connected in series when the further capacitor means C2, and the subsequent component is provided by the combination of the third resistor means R9 connected in series with the further capacitor means C2. The function of these components is arranged such that the initial component provides an initial integration of a signal appearing at the output of the preamplifier 39 at a greater rate than the first prescribed timing func¬ tion, and the subsequent component provides a subsequent integration at a lesser rate than the first prescribed timing function.
The respective outputs of the capacitor means Cl and C2 are connected via diodes Dl and D2 respectively to the inputs of the control means 51. These diodes prevent the discharge of the respective capacitor means back through the input circuit of the integrating means. Thus, in the case of capacitor means C2, discharge of the same is only provided by its innate leakage which defines a fourth prescribed timing function. Obviously, the fourth pres¬ cribed timing function provides a rate of decay signi¬ ficantly less than the rate of decay as provided by the second prescribed timing function for the capacitor Cl.
The integrating means is provided with a further switching means 60 which is incorporated into the selector means 49 to enable independent discharging or resetting of the capacitor means Cl and C2 by the user. This is provided by directly connecting the output of the preamplifier to a capacitor means selected by the further switching means

60, which effectively sinks the stored charge within the selected capacitor means.
The control means 51 comprises comparator means 53, trans¬ ducing means 55 and electronic switching means 57. The comparator means 53 has its inputs 5 and 6 connected to the outputs of the memory means 45 and further memory means 47 respectively, and its own output 7 connected serially to the transducing means 55 and electronic swit¬ ching means 57.
The electronic switching means is in the form of a tran¬ sistor connected in the common emitter configuration. The base and collector terminals of the transistor are both driven by the output 7 of the comparator means and so switched on only in response to an active output signal being provided by the comparator means. The transducing means 55 is in the form of a piezzo-electric crystal having an integrated oscillating circuit provided therein. The electronic switching means 57 is connected interme¬ diate the comparator means 53 and transducing means 55 to enable and disable the piezzo-electric crystal and oscil¬ lating means in response to the condition of the compara¬ tor means. On activation of the piezzo-electric crystal the oscillating means functions to drive the crystal at a prescribed frequency enabling the same to produce a sen¬ sorially perceptible signal, particularly perceptible to the aural senses of a person using the device.
The control means also includes a triggering means 59 in the form of an actuating capacitor means C3 coupled bet¬ ween a power source 51 for the device and the output of the memory means 45. The triggering means 59 is provided to incite generation of the sensorially perceptible signal by the control means for a short period on initially supplying power to the device. The operation of this shall be described in more detail later.

The power source 61 is in the form of a solar cell provid¬ ing power to the device via a switch 63. To facilitate operation of the solar cell, a storage capacitor C6 is connected across the power terminals thereof to sustain the output voltage of the cell.
With reference to the physical configuration of the de¬ vice, as shown in Figs. 3 and 4, the arrangement is sub¬ stantially identical to that of the preceding embodiment. Thus, the filtering means and detecting means 37 are provided beneath the window 27, the solar cell 61 is provided beneath the window 28, and the selector means 49 is provided by way of the multi-range switch 32 of the device. In addition, the power switch 63 can be provided separately on the casing as shown at 65, or incorporated into a position provided on the multi-range switch, where¬ by the device may be turned off or on by moving the switch into or out of this position respectively.
The operation of the device shall now be described.
The filtering means and detecting means of the sensing means 35 operates substantially the same as in the preced¬ ing embodiment. A sensing signal is provided at the output of the detecting means 37 which is input to the non-inverting input of the operational amplifier 41 and is subsequently amplified by the preamplifier arrangement 39 to provide a sensing signal input to the integrating means 43.
The integrating means 43 essentially integrates this sensing signal via two parallel paths which are defined respectively by the memory means 45 and further memory means 47. The first path integrates the sensing signal in accordance with the first prescribed timing function and generates an active signal at the output of the memory

means 45. The second path integrates the sensing signal in accordance with the third prescribed timing function and generates a reference signal at the output of the further memory means 47. As previously described, the rate of integration of the further memory means 47 is initially greater than that of the memory means 45 since on the initial generation of the sensing signal the bypass capacitor means C4 functions to bypass the third resistor means R9 associated therewith and so enabling the further capacitor means C2 to charge very rapidly. This rapid charge will continue until the additive charge of the further capacitor means C2 and bypass capacitor means C4 approaches the magnitude of the sensing signal, whereon additional accumulative charge will be diverted through resistor R9. This diversion subsequently has the effect of the further capacitor means C2 charging at a subsequent rate prescribed by the subsequent component of the third prescribed timing function. Thus, effectively the further capacitor means C2 charges at an initial rate which is greater than the charging rate of capacitor means Cl, so providing a reference signal magnitude that is initially higher than that of the active signal. However, on subse¬ quent charging, the further capacitor means C2 will pro¬ ceed at a charging rate slower than that of the capacitor means Cl. Thus after a time which is prescribed by the selected values of the first resistor means R3 to R7, third resistor means R9 and the capacitor means Cl, C2 and C, the active signal magnitude shall eventually attain the threshold level set by the reference signal magnitude.
The comparator means 53 of the control means 51 effec¬ tively monitors the relative magnitudes of the active signal and reference signal, so that during the period that the active signal is less than the reference signal the output of the comparator means is deactivated, and on the active signal magnitude attaining the threshold level

set by the reference signal magnitude, the comparator means output will be activated. On activation of the comparator means output, the electronic switching means will be turned on enabling the operation of the trans¬ ducing means 55.
It should be noted that an important feature and diffe¬ rence of the present embodiment over the preceding embodi¬ ment, is that due to the integrating means 43 providing a rising reference signal and thus rising threshold level, which effectively rises progressively at two different rates in accordance with the third prescribed timing function, the first prescribed timing function can be chosen having consideration to fewer parameters than is required in the preceding embodiment. Therefore the first prescribed timing function need be only chosen with res¬ pect to a particular person’s skin type and need not be changed on exposure to the impinging ultraviolet radiation by the user on different days as the user’s tolerance to radiation increases. >
This effect is achieved principally by providing a refe¬ rence signal magnitude which automatically increases on increased exposure of the device to ultraviolet radiation, and having the further capacitor means C2 diminishing the reference signal magnitude only in response to the fourth prescribed timing function, in contrast to the capacitor means Cl diminishing the active signal magnitude in accor¬ dance with the second prescribed timing function. More¬ over the second and fourth timing functions are set so that the capacitor means Cl discharges fully overnight, whereas the further capacitor means C2 discharges fully only over a period of approximately 1 week. Thus, on a person exposing themselves to ultraviolet radiation on successive days for the prescribed periods of time as determined by the device, the further capacitor means C2

will have some residual charge after a previous days use of the device, thereby providing a reference signal at a higher level of magnitude on commencing use of the device than the previous day. Accordingly, the capacitor means Cl will take a longer period of time to attain the level of the reference signal and so by selecting suitable component values, the integrating means can be arranged to simulate the build-up of Melanin in the skin of the user of the device and thus allow for safe prolonged periods of exposure to ultraviolet radiation ensuring the safe pro¬ gressive tanning of the user’s skin.
Therefore, it is only necessary for a user to select the appropriate position of the multi-range switch 32 to match his particular skin type, whereinafter by following the prescribed method of use of the device, the allowable exposure of the user to ultraviolet radiation will auto¬ matically be compensated for by the device on progressive exposure to the radiation.
»
On initial switch-on of the device, the triggering means 59 operates to provide an active signal which is initially higher in magnitude than the reference signal for a very short period of time, and which is sufficient to incite generation of the sensorially perceptible signal for a short period. This period will only last until the actua¬ ting capacitor C3 charges up to the potential of the power source supplied to the device. To enable this action to occur without detriment to the subsequent operation of the integrating means 43, the delay means operates to negative the function of the sensing means for the duration of the period that the active signal exceeds the level of the reference signal. This is achieved by the bypass capaci¬ tor C4 negating the effect of the feedback resistor Rl for a short period of time thus suppressing the gain of the

preamplifier until such time as C4 charges to divert the feedback current through feedback resistor Rl. By the time that the gain of the preamplifier is reinstated, the effect of the triggering means 59 would have been comple¬ ted.
An incidental feature of the device is that the comparator means 53 is provided with further triggering means in the form of an intrinsic capacitance at each of its inputs (not shown). This capacitance is inherent within the circuit as configured within an integrated circuit arran¬ gement. Accordingly, whenever the sensing signal which is input to the integrating means 43 is absent concurrent with power being supplied to the device, as may arise when the detecting means 37 is obstructed from impinging radia¬ tion by some impediment, the intrinsic capacitance dis¬ charges back through the integrating means via the refe¬ rence and active lines respectively. The time constants for the respective discharge lines will conseqently be determined by the third and first prescribed timing func¬ tions respectively. Since the bypass capacitor means C4 determines the initial component of the third prescribed timing function, the intrinsic capacitance will be allowed to rapidly discharge initially by bypassing the third resistor means R9, in contrast to the discharge of the intrinsic capacitance via the first resistor means R3-R7 of the active line. Consequently, the reference signal will initially rapidly diminish in comparison to the active signal causing the reference level to be attained by the latter, and so activating the comparator means output enabling the operation of the transducing means 55.
Thus the sensorially perceptible signal will be generated whenever impinging radiation is intentionally or uninten¬ tionally obstructed from the detecting means by some impediment. For example by a fly or suntan lotion landing on the device covering the sensing window 27.

The particular advantages that are capable of being provi¬ ded by the device as described in any of the preceding embodiments include:-
(1) guarding against skin cancer and premature skin ageing;
(2) recognising different skin types and automati¬ cally setting an ultraviolet dose limit accordingly;
(3) remembering the ultraviolet dose of previous days and modifying current dose accordingly;
(4) matching the Melanin build up in the user’s skin day by day so giving maximum safety in addition to a tan and with or without a skin protection cream;
(5) the unit can be completely sealed and is self-contained and so can be worn on a hat or other apparel such as bathing costumes etc. of a person even when swimming, thereby continuously operating to monitor the dose of ultraviolet radiation received;
(6) the device is ideal for sunbathing by providing a means to inform the user of excessive “exposure to the sun at any time the user is exposed; and
(7) the device can be used in any number of situa¬ tions where persons may be working on road construc¬ tion, building sites, farming, oil and mineral explo¬ ration, watching sporting events, gardening, washing the car etc, with or without a skin protection cream.
It should be appreciated that the scope of the present invention is not limited to the scope of the embodiment herein described. Particularly the switching means is not limited to the use of a cover and photo electric switch, but may consist of other suitable means. In addition, the sensorially perceptible alarm, is not necessarily limited to an aural signal but may also include a visual indicator to provide a visual signal. Furthermore, the power source is not necessarily limited to, a solar cell but may consist

of any other suitable device, such as a replacable bat¬ tery.

Claims (28)

THE CLAIMS defining the invention are as follows:-

1. A device for monitoring electromagnetic radiation comprising: a sensing means for sensing radiation im¬ pinging a body and to generate a sensing signal propor¬ tional to the magnitude of said impinging radiation; an integrating means to integrate said sensing signal in accordance with a first prescribed timing function and generate an active signal proportional to the magnitude of said integration; and control means to monitor the rela¬ tive magnitude of said active signal and generate a sen¬ sorially perceptible signal in response to said active signal magnitude attaining a threshold level; wherein said first prescribed timing function is related to an admoni¬ shed accumulative effect of said impinging radiation on said body and said threshold level is related to the optimum cumulative radiation to which said body is desired to be exposed.

2. A device as claimed at claim 1, wherein said inte¬ grating means includes memory means to store said active signal magnitude and allow active signal magnitude to diminish in accordance with a second prescribed timing function in response to a reduction in said sensing signal magnitude, said second prescribed timing function being related to an admonished decay in the residual effect of previously impinging radiation on said body pursuant to said body being removed from said impinging radiation or vice versa.

3. A device as claimed at claim 2 , wherein said memory means comprises a capacitor means, and said first prescri¬ bed timing function is determined by a first resistor means coupled in series with said capacitor means, and said second prescribed timing function is determined by a second resistor means coupled in parallel with said capa¬ citor means.

4. A device as claimed at any of the preceding claims, wherein said integrating means includes selector means to select different first prescribed timing functions.

5. A device as claimed at claims 3 and 4, wherein said selector means comprises a plurality of differently valued first resistor means and a switching means to selectively couple a single first resistor means to said capacitor means at any one time.

6. A device as claimed at any of the preceding claims, wherein said integrating means is adapted to generate a reference signal which defines said threshold level and said control means includes comparator means to compare the relative magnitudes of said active signal and said reference signal to detect when said active signal magni¬ tude attains the threshold level specified by said refe¬ rence signal.

7. A device as claimed at claim 6, wherein said refe¬ rence signal is generated by integrating said sensing signal in accordance with a third prescribed timing func¬ tion, said third prescribed timing function comprising initial and subsequent components, said initial component providing an initial integration at a greater rate than said first prescribed timing function, and said subsequent component providing a subsequent integration at a lesser rate than said first prescribed timing function.

8. A device as claimed at claim 7, wherein said inte¬ grating means includes a further memory means to store said reference signal magnitude and allow the reference signal magnitude to diminish in accordance with a fourth prescribed timing function in response to a reduction in said sensing signal magnitude, the rate of decay as provi¬ ded by said fourth prescribed timing function being signi- ficantly less than the rate of decay as provided by said second prescribed timing function.

9. A device as claimed at claim 8, wherein said further memory means comprises a further capacitor means, and the initial component of said third prescribed timing function is determined by a bypass capacitor means coupled in series to said further capacitor means, and the subsequent component of said third prescribed timing function is determined by a third resistor means coupled in series with said further capacitor means and in parallel with said bypass capacitor means.

10. A device as claimed at claim 9, wherein said fourth prescribed timing function is determined by the innate leakage of said further capacitor means.

11. A device as claimed at any of the preceding claims as dependent upon claim 2 or 8, wherein either or both of said memory means may be independently reset by a further switching means.

12. A device as claimed at any of the preceding claims, wherein said control means includes a transducing means to generate said sensorially perceptible signal, and an elec¬ tronic switching means to activate said transducing means on detection of said active signal magnitude attaining said threshold level.

13. A device as claimed at any of the preceding claims, wherein said control means includes triggering means to incite generation of said sensorially perceptible signal for a short period on supplying power to said device.

14. A device as claimed at claim 13, wherein said trig¬ gering means comprises an actuating capacitor means coup- led between a power source for the device and the active signal output of said integrating means, such that on supplying power to said device, said active signal magni¬ tude will rapidly attain said threshold level and subse¬ quently return to a typical magnitude specified by said integrating means consequential to said actuating capaci¬ tor charging.

15. A device as claimed at claims 13 or 14, wherein said sensing means includes delay means to negative its func¬ tion substantially during said short period.

16. A device as claimed at any of the preceding claims, wherein said sensing means includes filtering means and detecting means, said filtering means being characterised to only allow electromagnetic radiation in the ultraviolet region of the electromagnetic spectrum to impinge said detecting means, and said detecting means being enhanced to accurately detect the impinging radiation in said’ region and to generate said sensing signal in response thereto.

17. A device as claimed at any of the preceding claims, including further triggering means to incite generation of said sensorially perceptible signal in the absence of said sensing signal after power has been supplied to said device.

18. A method of monitoring electromagnetic radiation comprising the steps of:-
sensing radiation impinging a body; generating a sensing signal proportional to the mag¬ nitude of said impinging radiation; integrating said sensing signal in accordance with a first prescribed timing function; generating an active signal proportional to the magnitude of said integration; monitoring the relative magnitude of said active signal; and generating a sensorially perceptible signal in res¬ ponse to said active signal magnitude attaining a threshold level;
wherein said first prescribed timing function is related to an admonished accumulative effect of said impinging radiation on said body and said threshold level is related to the optimum cumulative radiation to which said body is desired to be exposed.

19. A method as claimed at claim 18, including the step of storing said active signal magnitude and allowing the active signal magnitude to diminish in accordance with a second prescribed timing function in response to a reduc¬ tion in said sensing signal magnitude, said second pres¬ cribed timing function being related to an admonished decay in the residual effect of the impinging radiation on said body pursuant to said body being removed from said impinging radiation or vice versa.

20. A method as claimed at claim 18 or 19, including the step of generating a reference signal which defines said threshold level and comparing the relative magnitudes of said active signal and said reference signal to detect when said active signal magnitude attains the threshold level specified by said reference signal.

21. A method as claimed at claim 20 including the step of integrating said sensing signal in accordance with a third prescribed timing function to generate said reference signal, said third prescribed timing function comprising initial and subsequent-components, said initial component providing an initial integration at a greater rate than said first prescribed timing function, and said subsequent component providing a subsequent integration at a lesser rate than said first prescribed timing function.

22. A method as claimed at claim 21, including the step of storing said reference signal magnitude and allowing the reference signal magnitude to diminish in accordance with a fourth prescribed timing function in response to a reduction in said sensing signal magnitude, the rate of decay as provided by the fourth prescribed timing function being significantly less than the rate of decay as provi¬ ded by said second prescribed timing function.

23. A method as claimed at any of claims 18 to 22, in¬ cluding the step of inciting generation of said sen¬ sorially perceptible signal for a short period on supply¬ ing power to monitor said electromagnetic radiation.

24. A method as claimed at claim 23, including the step of negativing the sensing step substantially during said short period.

25. A method as claimed at any of claims 18 to 24, in¬ cluding the step of filtering said electromagnetic radia¬ tion to only allow radiation in the ultraviolet region of the electromagnetic spectrum to be sensed.

26. A method as claimed at any of claims 18 to 25, in¬ cluding the step of inciting generation of said sen¬ sorially perceptible signal in the absence of said sensing signal after supplying power to monitor said electromag¬ netic radiation.

27. A device for monitoring electromagnetic radiation substantially as herein- described in any embodiment with reference to the drawings mutatis mutandis.

28. A method for monitoring electromagnetic radiation substantially as herein described in any embodiment with reference to the drawings mutatis mutandis.

AU51918/86A
1984-11-26
1985-11-26
Ultraviolet radiation monitoring device

Ceased

AU586454B2
(en)

Applications Claiming Priority (2)

Application Number
Priority Date
Filing Date
Title

AUPG8290

1984-11-26

AUPG829084

1984-11-26

Publications (2)

Publication Number
Publication Date

AU5191886A

AU5191886A
(en)

1986-06-18

AU586454B2
true

AU586454B2
(en)

1989-07-13

Family
ID=3770853
Family Applications (1)

Application Number
Title
Priority Date
Filing Date

AU51918/86A
Ceased

AU586454B2
(en)

1984-11-26
1985-11-26
Ultraviolet radiation monitoring device

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EP
(1)

EP0235141B1
(en)

AT
(1)

ATE93639T1
(en)

AU
(1)

AU586454B2
(en)

DE
(1)

DE3587551D1
(en)

WO
(1)

WO1986003319A1
(en)

Families Citing this family (9)

* Cited by examiner, † Cited by third party

Publication number
Priority date
Publication date
Assignee
Title

US4535244A
(en)

*

1983-05-19
1985-08-13
Bpa Calscan, Inc.
Photodosimeter

US4704535A
(en)

*

1985-04-11
1987-11-03
Teledyne Industries, Inc.
Ultraviolet dosimetry

BE1002351A6
(en)

*

1988-08-09
1991-01-08
Salles George

LIGHTING MEASURING APPARATUS.

DE4329666C1
(en)

*

1993-09-02
1995-01-05
Se Scient Electronics Muenchen
Radiation meter for protection from high UV radiation loading

DE4329665C1
(en)

*

1993-09-02
1994-05-11
Se Scient Electronics Muenchen
EM radiation sensor for monitoring UV radiation dosage – has lens system focussing received radiation onto detector providing electrical signal

FR2753793B1
(en)

*

1996-09-20
1998-12-04

INDIVIDUAL NATURAL ELECTROMAGNETIC RADIATION DOSIMETER WITH CENTRALIZED RADIATION MEASUREMENT

DE102007041395A1
(en)

2007-08-31
2009-03-05
Thüringisches Institut für Textil- und Kunststoff-Forschung e.V.

UV dosimeter with self-supply and warning signal (display)

CN103559778B
(en)

*

2013-11-15
2016-09-14
王宁利
Depending on load monitoring and warning device and method

US10837826B2
(en)

2016-06-30
2020-11-17
Thueringisches Institut Fuer Textil-Und Kunststoff-Forschung E.V.
UV dosimeter with color change

Citations (3)

* Cited by examiner, † Cited by third party

Publication number
Priority date
Publication date
Assignee
Title

US3710115A
(en)

*

1969-08-04
1973-01-09

J Jubb

Sunburn warning device comprising detecting the ultra-violet component of solar radiation

US3878496A
(en)

*

1971-06-14
1975-04-15

Us Energy

Selectable level alarming personal dosimeter

US4348664A
(en)

*

1978-10-30
1982-09-07

Elder Pharmaceuticals, Inc.

Device for measuring ultraviolet light exposure

Family Cites Families (11)

* Cited by examiner, † Cited by third party

Publication number
Priority date
Publication date
Assignee
Title

US3443097A
(en)

*

1968-01-05
1969-05-06
Atomic Energy Commission
Pocket radiation dosimeter utilizing capacitor integrator

CH578728A5
(en)

*

1974-07-16
1976-08-13
Biviator Sa

US3999061A
(en)

*

1975-04-30
1976-12-21
Canadian Patents And Development Limited
Radiant energy integrating meter

US4015116A
(en)

*

1975-10-20
1977-03-29
Rho Sigma Corporation
Measurement of solar radiation

US4229733A
(en)

*

1978-08-10
1980-10-21
Thomas N. Tulenko
Exposure detecting device

JPS5552918A
(en)

*

1978-10-13
1980-04-17
Matsushita Electric Ind Co Ltd
Sunburn warning device

US4279254A
(en)

*

1978-10-30
1981-07-21
Paul B. Elder Company
Ultraviolet light control

US4313067A
(en)

*

1979-07-16
1982-01-26
Miles Laboratories, Inc.
Sensor-integrator system

JPS5637777A
(en)

*

1979-09-05
1981-04-11
Canon Inc
Flicker preventing system for solid state image pickup device

US4428050A
(en)

*

1981-04-02
1984-01-24
Frank Pellegrino
Tanning aid

US4539567A
(en)

*

1983-09-12
1985-09-03
Micrometrics, Ltd.
Microwave monitor

1985

1985-11-26
EP
EP85905747A
patent/EP0235141B1/en
not_active
Expired – Lifetime

1985-11-26
WO
PCT/AU1985/000294
patent/WO1986003319A1/en
active
IP Right Grant

1985-11-26
AU
AU51918/86A
patent/AU586454B2/en
not_active
Ceased

1985-11-26
DE
DE85905747T
patent/DE3587551D1/en
not_active
Expired – Lifetime

1985-11-26
AT
AT85905747T
patent/ATE93639T1/en
not_active
IP Right Cessation

Patent Citations (3)

* Cited by examiner, † Cited by third party

Publication number
Priority date
Publication date
Assignee
Title

US3710115A
(en)

*

1969-08-04
1973-01-09
J Jubb
Sunburn warning device comprising detecting the ultra-violet component of solar radiation

US3878496A
(en)

*

1971-06-14
1975-04-15
Us Energy
Selectable level alarming personal dosimeter

US4348664A
(en)

*

1978-10-30
1982-09-07
Elder Pharmaceuticals, Inc.
Device for measuring ultraviolet light exposure

Also Published As

Publication number
Publication date

EP0235141B1
(en)

1993-08-25

ATE93639T1
(en)

1993-09-15

EP0235141A1
(en)

1987-09-09

DE3587551D1
(en)

1993-09-30

WO1986003319A1
(en)

1986-06-05

EP0235141A4
(en)

1988-12-15

AU5191886A
(en)

1986-06-18

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