Infrared Radiation, Definition, Characteristics, Applications ... - ir rays uses
Among Canadians who reported using a laser product, 1.1%E (95% CI: 0.7, 1.4) reported experiencing discomfort or injury within the past 12 months. This included skin injuries such as rash, itch or pain and eye injuries such as itchiness, pain, visible floating objects, blurred vision, burn, flash blindness, excessive watering or loss of sight (Table 3). Approximately 44.9%E of the respondents who reported an injury indicated it occurred only once in the past 12 months, while 49.5%E indicated at least two occurrences in the past 12 months (Table 3). Among those who reported an injury from a laser product, 41.3%E declared the injury or discomfort occurred to their skin, while 59.1% reported an injury to the eyes. Sight injury prevalence did not appear to vary by sex (data not shown). Among those who reported harm caused by a laser device, 63.9% indicated that the discomfort or injury lasted two days or less, while 34.0%E of individuals reported that the injury lasted more than two days (Table 3).
Compared with the prevalence in Ontario, the prevalence of Canadians who were exposed to or used laser products was found to be significantly higher (p < 0.05) in the Western provinces (i.e., Manitoba, Saskatchewan, Alberta and British Columbia) and significantly lower (p < 0.05) in Quebec (Table 1).
Dhoot DS, Xu D, Srivastava S. High-powered laser pointer injury resulting in macular hole formation. Journal of Pediatrics 2014; 64: 668.e1.
While laser products were used in many consumer products prior to 1999, relatively few non-military laser injuries were reported in the scientific literature. At that time, most consumer laser products used red diode lasers (630 nm to 650 nm) that operated at a lower accessible emission level because of limitations in laser technology at that time. Furthermore, published accounts of laser injuries may not have been captured. Most incidents would not have been presented in scientific journals as case reports or may have been misdiagnosed as an ocular disease.Note 29 Finally, laser trauma incurred in industrial, commercial, military and medical settings could go unreported because of a lack of knowledge regarding reporting systems. Some incidents may have gone unreported because a person failed to follow protocols (e.g., did not use protective eyewear) and feared workplace disciplinary action. Laser incidents in which eye or skin effects resolved quickly may also not have been reported.
Diagram A and Diagram B show the appearance of your image when you sight in one of the single faces of the mirror. These two plane mirror images exhibit the left-right reversal that was discussed earlier in Lesson 2. While the object is raising her left hand, the image appears to be raising the right hand. This image characteristic is not unusual, for we have already discussed it in detail earlier in Lesson 2. These two images are sometimes referred to as primary images. When viewing a primary image, light is reflecting off a single mirror before arriving at your eye. Diagram C shows the appearance of the middle image, sometimes referred to as a secondary image. The secondary image does not exhibit left-right reversal; a careful inspection of Diagram C reveals that while the object is raising the left hand, the image is also raising the left hand. Why the difference? Why would the secondary image not produce the left-right reversal that we observe in most plane mirror images?
Dielectricmirror
A number of limitations are associated with the findings of this study. The assessment for injuries was not ideal because the questionnaire did not report the specific type of injury incurred to each tissue type (i.e., eye [flash blindness, floaters or loss of sight] or skin [burns, pigment change or scarring]) and included discomfort in the same category. Furthermore, respondents were asked about injuries from lasers sustained only in the previous 12 months. Lifetime injuries, particularly among older respondents who no longer use such devices, may have provided a more comprehensive picture of the injury prevalence. Lastly, because of the small sample size of reported injuries, the statistics regarding the type of laser product (excluding medical devices) that caused the injury were coded as “E.” This indicates a high degree of variability and that they should be interpreted with caution. Despite the low number of injury cases, the values are still reportable. However, the inclusion of a bigger sample size or of other national or provincial surveillance resources is required for a more accurate representation of the numbers and types of injuries that occur, as well as of the circumstances of the occurrence. One of the strengths of the survey is that the results are representative of the Canadian population. The survey had a large sample size of 19,765 respondents and an overall response rate of 62.3%, which is difficult to achieve for a survey of this kind. It is also the first of its kind to document the impact of laser device use in Canada. The survey suggests that the risk for harm is higher depending on the type of laser product used and who is using it.
Mayer JE, Goldberg DJ. Injuries Attributable to Cosmetic Procedures Performed by Unlicensed Individuals in the United States. The Journal of Clinical and Aesthetic Dermatology 2015; 8(10): 35-37.
International Electrotechnical Commission. IEC 60825-1, Safety of Laser Products - Part 1: Equipment classification and requirements, Ed 3.0, 2014-05.
Since 2012, the manufacturing, advertising, import, lease and sale of high-powered (i.e., Class 3B and 4) handheld, battery-operated lasers and laser pointers has been prohibited in Canada.Note 6 Despite restrictions on the sale, lease or import of high-powered laser pointers in many countries, several recent studies have reported that a large number of laser pointers labelled as low-powered devices (e.g., Class 1, 2 or 3R) were found to exceed their claimed IEC 68025-1 classification level and were actually Class 3B devices.Note 7Note 8Note 9 In 2013, National Institute of Standards and Technology researchers found that nearly 90% of green laser pointers and about 44% of red laser pointers tested were non-compliant with U.S. federal safety regulations. Half of these devices exceeded the accessible emission limit for Class 3R laser devices by a factor of two or more.Note 7 Furthermore, Internet purchases with direct shipping from overseas vendors to Canadian consumers represent a challenge for the enforcement of the existing prohibition, especially if the laser class is not accurately represented on the product. This may result in an increased number of high-powered, handheld battery-operated laser devices in the hands of Canadians. Consequently, the surveillance of the prevalence of laser device usage and injury among Canadians is important for monitoring the risk that laser devices pose to Canadians.
The International Commission on Non-Ionizing Radiation Protection (ICNIRP) is an independent organization of scientific experts that provides advice on the health and environmental effects of non-ionizing radiation, including laser radiation. ICNIRP has established guidelines on limits of exposure to laser radiation.Note 2 These exposure limits serve as the scientific basis for the hazard classification by the International Electrotechnical Commission (IEC) of laser devices (i.e., classes 1, 1M, 1C, 2, 2M, 3R, 3B and 4) according to their accessible radiation properties (IEC 60825-1).Note 3
American National Standards Institute. American national standard for safe use of lasers. Orlando, FL: ANSI, 2000. ANSI Z136.1-2000.
The CCHS rapid response laser beam exposure module was organized into sections. The first set of questions asked respondents whether they used or were exposed to a laser product in the previous 12 months. Respondents who responded positively were asked to identify the type of laser product they used or were exposed to. Respondents were presented with the following product options:
The diagrams below depict the three images of a right angle mirror system. The location where a person must sight to view his image and the left-right orientation of the resulting image is shown. In each case, the object is raising his left hand.
As discussed earlier in Lesson 2, the apparent left-right reversal of a plane mirror image is explained by the flipping of reference frames. Instead of viewing your shirt from behind the shirt, you are viewing your shirt from the perspective of a person standing in front of your shirt. It is as though your frame of reference has been rotated 180 degrees about the imaginary axis that extends from your head to your toes. This switching of reference frames leads to the appearance of left-right reversal. So a single reflection causes NIKE to reverse once, producing EKIN (but again, the letters themselves would be reversed). But in viewing the secondary image, you are viewing an image of an image - a double reflection. The double reflection of light (as is the case with the middle image) causes the letters of NIKE to reverse to EKIN and then to reverse again back to NIKE. The double reflection of light causes the reference frame to rotate a full 360 degrees. A 360-degree rotation about an axis is a complete rotation, returning you to your usual frame of reference.
Thus far we have focused on the images formed by a single plane mirror. Occasionally, there are optical systems that consist of two or more mirrors. One such system that is often found in homes is a pair of plane mirrors adjoined at right angles to each other. Such a system is called a right angle mirror (pretty clever, huh?). Perhaps you have a right angle mirror set in one of your house's bathrooms.
This information will help improve the knowledge base in Canada regarding laser injuries. This will also strengthen risk assessment of laser products, inform risk management strategies, and support evidence-based advice and recommendations.
Khedr YA, Khedr AH. Photoblepharokeratoconjunctivitis caused by invisible infrared radiation emitted from a green laser pointer. British Medical Journal Case Reports 2014; 11.
Education appeared as a significant factor associated with laser use and exposure. The prevalence of laser use or exposure was 58.6% among Canadians with a “university certificate, diploma or degree,” which was higher than among those with “some postsecondary education (certificate or diploma including trades)” (50.2%; 1.4 OR; 95% CI: 1.21, 1.62; data not shown) and among those with a “secondary diploma or equivalent or less” (39.1%; 2.11 OR; 95% CI: 1.84, 2.42) (Table 1). A statistically significant (p < 0.0001) positive linear trend in the use of or exposure to laser devices was also present across income levels, such that the higher the household income, the higher the probability of using or being exposed to a laser device. Canadians who were self-employed reported a slightly lower prevalence of exposure or usage of laser products compared with those who were employed by a company or organization (53.4% versus 58.7%) (Table 1).
Vano-Galvan S, Jaen P. Complications of nonphysician-supervised laser hair removal: case report and literature review. Canadian Family Physician 2009; 55(1): 50-52.
Xu M, Lin T. Bilateral central scotomas following laser pointer misuse. Canadian Medical Association Journal 2014; 186: E341.
Jeon S, Lee WK. Inner retinal damage after exposure to green diode laser during a laser show. Clinical Ophthalmology 2014; 8: 2467-2470.
The last set of questions pertained to the type of laser device that caused the discomfort or injury, where the device was obtained and whether the injury was the result of personal use or someone else’s use of the device.
Petrou P, Patwary S, Banerjee PJ, Kirkby GR. Bilateral macular hole from a handheld laser pointer. Lancet 2014; 383: 1780.
Overall, 31,709 households were in scope for the CCHS rapid response module on laser beam exposure. Valid responses were obtained for 19,765 individuals. This yielded an overall response rate of 62.3%. A detailed description of the CCHS methodology and sources used is available on the Statistics Canada website.
Sex differences regarding use or exposure identified in the survey were supported by published case reports of harm from 1999 to 2016, in which the majority of laser injuries from cosmetic treatments (e.g., hair removal, skin treatment or tattoo removal) occurred in females,Note 10Note 11Note 12Note 13Note 14Note 15Note 16 whereas most injuries incurred from a laser pointer, entertainment or measurement device occurred among males.Note 4Note 9Note 10Note 11Note 12Note 13Note 14Note 15Note 16Note 17Note 18Note 19Note 20Note 21Note 22Note 23Note 24Note 25Note 26Note 27Note 28Note 29
Together, these exclusions represented less than 3% of the population aged 12 or older. The rapid response module of the CCHS on laser beam exposure covered the same population as the CCHS, except that it excluded participants from the three territories (i.e., Yukon, the Northwest Territories and Nunavut).
Flatmirror
The analyses were based on a sample of 19,765 respondents aged 12 or older in the 10 provinces. To be representative of the Canadian population, the data were weighted and analyses were carried out using SAS EG 5.1 (SAS Institute Inc., United States). The SAS procedure SURVEYFREQ was used to calculate percentages and coefficients of variation (CVs). Data with a CV from 16.6% to 33.3% are identified by an (E) and should be interpreted with caution; data with a CV greater than 33.3% are suppressed (F) because of extreme sampling variability. To test differences in prevalence between sociodemographic groups, the procedure SURVEYLOGISTIC was used to calculate odds ratios (ORs) and corresponding confidence intervals (CIs) with Bonferroni adjustments for pairwise comparisons. The ESTIMATE statement of the procedure SURVEYLOGISTIC was used to test for a linear trend in the use of or exposure to a laser device across income levels. Both procedures accounted for sampling weights and estimated variance using bootstrap weights.
Alsulaiman SM, Alrushood AA, Almasaud J, et al. King Khaled Eye Specialist Hospital Collaborative Retina Study Group. High-power handheld blue laser-induced maculopathy: the results of the King Khaled Eye Specialist Hospital Collaborative Retina Study Group. Ophthalmology 2014; 121: 566-572.
Canada Consumer Product Safety Act (CCPSA) prohibition: Recalls and safety alerts. Handheld Lasers or Laser Pointers May Cause Permanent Vision Damage and Burns. Available at: http://healthycanadians.gc.ca/recall-alert-rappel-avis/hc-sc/2012/15008a-eng.php?_ga=2.103038083.2035911206.1519153286-213351845.1503087760. Accessed February 20, 2018.
If you have a chance to look carefully at the images formed by right angle mirrors, then you will notice that right angle mirrors produce three images. Interestingly, a single mirror produces a single image; another single mirror produces a second image; but when you put the two single mirrors together at right angles, there are three images. So why are there three images and how can the three images be compared and contrasted?
Raoof N, Chan TK, Rogers NK, Abdullah W, Haq I, Kelly SP, Quhill FM. ‘Toy’ laser macular burns in children. Eye 2014; 28:231-234.
45degree mirror
An inspection of the diagram shows that image #1 is located directly across the face of the mirror and the same distance behind the mirror as the object is in front of the mirror (nothing surprising yet). Image #2 is located directly across the other face of the mirror and the same distance behind the mirror as the object is in front of the mirror (still nothing surprising). Image #3 is located directly through the crease of the mirror and the same distance from the crease as the object is from the crease (now that might be surprising). In fact, a diagonal line drawn from the object location through the crease of the mirror will pass through the third image. So the image locations for the primary images are found in the usual way; but the image location for the secondary image must be found by measuring the object's distance to the crease of the mirror and then measuring along the diagonal line the same distance behind the mirror.
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In 2014, Health Canada provided questions pertaining to the prevalence of and injury from laser product usage or exposure in the previous 12 months on Statistics Canada’s nationally representative Canadian Community Health Survey (CCHS). This information was gathered to support efforts to monitor and address an emerging health concern regarding laser products. Specifically, the CCHS data assisted in analyzing parameters such as:
The ray diagrams for all three images of a right angle mirror are shown in the diagram at the right. Observe that the two primary images (images #1 and #2) are seen by the eye as the result of a single reflection of light off a single mirror. However, the secondary image (image #3) is seen by the eye as the result of a double reflection. That is, light must reflect off both mirror surfaces in order to view the secondary image. This helps to explain the observation that the primary images exhibits left-right reversal but the secondary image does not. When looking at your NIKE shirt in one of the mirror faces, the NIKE lettering appears as EKIN. Not only would the order of letters appear reversed, but also the letters themselves would appear reversed (which is not easily done when typing from a keyboard). However when looking at your NIKE shirt in the crease of the mirror, NIKE remains NIKE.
Marshall J, O'Hagan JB, Tyrer JR. Eye hazards of laser 'pointers' in perspective. British Journal of Ophthalmology 2016; 100(5): 583-584.
TrueMirror
According to the CCHS, cosmetic laser treatments (e.g., hair or tattoo removal) were the cause of most injuries or discomfort (39.1%E). This may be because of the nature of the treatment itself, particularly to the skin, or because aestheticians, cosmetologists or individuals have no formal training, or inadequate training, or lack experience operating such devices. Several studies have suggested that misuse may be the cause of injuries from elective cosmetic procedures since these procedures are often associated with unlicensed and inadequately trained personnel.Note 10Note 11Note 12Note 13Note 14Note 15Note 16 These types of injuries (resulting from the misuse of products) may be more prevalent because unlicensed establishments often offer more affordable rates for their procedures. This places individuals who seek these treatments at higher risk. That being said, many cosmetic procedures can cause discomfort or mild injury to the skin to achieve the desired cosmetic outcome.
Löfgren S, Thaung J, Lopes C. Laser pointers and Eye injuries: An analysis of reported cases, 2013 Swedish Radiation Safety Authority Report number: 30, ISSN:2000-0456. Available at: http://www.laserpointersafety.com/2013-laser-eye-injuries.html. Accessed April 19, 2017.
Kontadakis GA, Karagiannis D, Kandarakis AS. Macular injury with rapid onset of choroidal neovascularization from laser epilation. JAMA Ophthalmology 2015; 133: 488-490.
International Commission on Non-Ionizing Radiation Protection. ICNIRP Guidelines on Limits of Exposure to Laser Radiation of Wavelengths between 180 nm and 1,000 μm. Health Physics 2013; 105(3): 271-295.
Respondents who replied positively to using or being exposed to a laser product were next asked about any injury or discomfort they experienced. They were asked what body part was affected (i.e., eye, skin, other), as well as about the frequency and duration of the discomfort or injury. Respondents with multiple reports of discomfort or injury were asked to provide answers for the worst injury or discomfort they sustained.
The Canadian Community Health Survey findings indicate that consumer laser product usage and exposure are very prevalent among Canadians aged 12 and older. A detectable number of discomfort or injury cases within the past year were reported in this survey. Moreover, strong associations were observed between certain groups (e.g., age, sex), the type of devices that were used and the types of injuries reported. The data show that cosmetic laser treatments place females at greater risk for skin injury and that males are at greater risk of eye injury related to the use of survey tools, pointers or entertainment devices employing lasers. In summary, the majority of the laser injuries reported in this survey occurred to the eyes, as compared with the skin, and were usually the result of usage by another person.
Statistics Canada is committed to serving its clients in a prompt, reliable and courteous manner. To this end, the Agency has developed standards of service which its employees observe in serving its clients.
Statistics Canada’s CCHS collects health-related data from the Canadian population for use at the national, provincial and regional levels. Derived from Cycle 4 of the CCHS, the rapid response data analyzed in this article were collected during telephone surveys conducted from March to June 2014. Respondents were asked about their laser product usage or exposure during the previous 12 months.
In 2014, 48.1% of Canadians aged 12 or older (an estimated 14.5 million) reported using or being exposed to beams from a laser device in the previous 12 months. A small but statistically significant sex difference was present: the odds of Canadian males using or being exposed to a laser device were 1.12 times higher than for females (Table 1). A higher prevalence of exposure was also reported in each age group compared with the 45 or older age group.
Overton G, Nogee A, Belforte DA, Holton C. Annual Laser Market Review & Forecast: Can laser markets trump a global slowdown? Available at: http://www.laserfocusworld.com/articles/print/volume-52/issue-01/features/annual-laser-market-review-forecast-can-laser-markets-trump-a-global-slowdown.html. Accessed March 9, 2017.
Now that we know where the images are located, we are ready to draw ray diagrams for the three images. Ray diagrams for the primary images are constructed in the same manner as demonstrated earlier in Lesson 2. The secondary image is the only new twist to drawing ray diagrams for right angle mirror systems. The method begins in the usual way: once the secondary (or middle) image has been located, use the line of sight method to determine how light reflects off the second face of the mirror to the eye. Then the twist occurs: now use the law of reflection to determine how light reaches the second face of the mirror. That is, draw a normal line, measure the angle the reflected ray males with the normal and then draw the incident ray to the second surface. This incident ray will originate at the first face of the mirror; thus, the incident ray on the second face of the mirror is merely the reflected ray from the first face. Now that you have determined the point of incidence on the first face, draw the incident ray from the object to this point of incidence. These three steps are illustrated below.
The increasing availability and sales of consumer laser products to Canadians, particularly through online purchases of high-powered handheld lasers, may increase the risk of ocular or skin injuries caused by laser radiation exposure. Currently, estimates of the prevalence of laser injury can be derived only from published accounts (e.g., case reports) in the scientific literature. Published accounts of injuries likely represent a small percentage of the total number of laser injuries sustained. The majority of incidents would not be formally published in scientific journals, since they are not typically reported outside the clinical setting.Note 4 The lack of information regarding the prevalence among Canadians of injuries caused by laser product usage or exposure presents a challenge for surveillance, risk assessment and risk management.
Parver DL, Dreher RJ, Kohanim S, Zimmerman P, Garrett G, Devisetty L, Pasquale LR. Ocular injury after laser hair reduction treatment to the eyebrow. Archives of Ophthalmology 2012; 130: 1330-1334.
The CCHS questionnaire was administered directly to respondents using computer-assisted telephone interviewing. The CCHS covers the household population aged 12 or older in the provinces and territories. The survey excluded:
Table 2 represents the weighted distribution of respondents that used or were exposed to laser products, with distributions shown for different product types. The most commonly reported product types by those who used or were exposed to a laser device included laser scanners, laser pointers, lasers for entertainment and laser survey tools (Table 2). Sex differences were observed depending on the type of laser product. A significantly (p = 0.0109) higher proportion of females (51.7%) reported being exposed to or using laser scanners than males (48.3%). The prevalence of laser pointer usage or exposure was significantly (p < 0.0001) higher for males than females (58.5% versus 41.5%). Use or exposure to lasers for entertainment was significantly (p = 0.0023) higher among males than females (55.0% versus 45.0%). A significantly (p < 0.0001) higher proportion of males used laser survey tools (81.0% versus 19.0%) (Table 2). More specifically, the odds of using or being exposed to laser pointers were 1.5 times higher for males than for females. Conversely, females had 4.2 times higher odds of using or being exposed to cosmetic lasers than males (data not shown).
The IEC classification of the hazard level of laser devices is based on the accessible exposure level, wavelength, emission duration and angular subtense of the apparent source (i.e., beam geometry and radiation pattern). According to the IEC standard, laser devices with a beam below the accessible emission limit of Class 3R represent a minimal risk to the eye since there are adequate safety margins, innate rapid aversion responses and blink reflexes. As a result, unintentional or reflected exposures would rarely reflect worst-case conditions. However, the risk of injury is still present with the use of telescopic optics and intentional viewing, and this risk increases with exposure duration. Exposure to a direct or reflected high-powered (Class 3B and Class 4) laser beam has the potential to cause serious eye or skin damage and may also pose a fire hazard.Note 3
PrismMirror
Hadler J, Tobares E, Dowell M. Random testing reveals excessive power in commercial laser pointers. Journal of Laser Applications 2013; 25.
Anaya-Alaminos R, Muñoz-Ávila JI, González-Gallardo MC, Mora-Horna ER, García-Serrano JL, Ramírez-Garrido MV. Accidental foveal photocoagulation secondary to alexandrite laser. European Journal of Ophthalmology 2014; 24: 808-810.
Canada owes the success of its statistical system to a long-standing partnership between Statistics Canada, the citizens of Canada, its businesses, governments and other institutions. Accurate and timely statistical information could not be produced without their continued co-operation and goodwill.
Shum JW, Iu LP, Cheung DN, Wong IY. A case of accidental ocular injury from cosmetic laser burn. Retinal Cases and Brief Reports 2016; 10(2): 115-120.
Mirrors Optics
An analysis of published case reports since 1999 Note 4Note 9Note 10Note 11Note 12Note 13Note 14Note 15Note 16Note 17Note 18Note 19Note 20Note 21Note 22Note 23Note 24Note 25Note 26Note 27Note 28Note 29 shows that of all the cases of eye injury caused by exposure to laser radiation, the majority involved the misuse of a handheld battery-operated laser product by an adult or a child. Most of these injuries were the result of irresponsible use or deliberate staring at a laser by a child, or the result of the inappropriate use of a high-powered laser device (Class 3B or 4) in an “uncontrolled environment”.Note 4Note 9Note 10Note 11Note 12Note 13Note 14Note 15Note 16Note 17Note 18Note 19Note 20Note 21Note 22Note 23Note 24Note 25Note 26Note 27Note 28Note 29 The number of annual reported cases of eye injury caused by laser products has increased in the past decade. In 2008, no cases of eye injury caused by a laser products were reported. However, 29 cases of laser injury related to handheld battery-operated laser products were reported in 2014, accounting for 85% of all reported cases for that year. These injuries have occurred worldwide; however, a higher number of cases have been reported in Europe, the Middle East and North America. One case was reported in Canada in 2014.Note 17 In the cases reported in 2014 that included long-term follow-up injury reporting, about one-half of the ocular injuries resolved within one to two weeks, with the other 50% of patients sustaining longer-term visual impairments.Note 12Note 13Note 17Note 18Note 19Note 20Note 21Note 22Note 23Note 24Note 25Note 26Note 27Note 28
Zhang L, Zheng A, Nie H, et al. Laser-Induced Photic Injury Phenocopies Macular Dystrophy. Ophthalmic Genetics 2016; 37(1):59-67.
When recalling their discomfort or injury, respondents were asked what type of laser product, excluding medical devices, caused the harm. The majority of injuries were the result of cosmetic laser treatments (e.g., hair or tattoo removal) (39.1%E). Laser pointers accounted for 26.3%E of injuries, while survey tools, lasers for entertainment, lasers for materials processing, laser barcode scanners and other laser products not identified in this survey accounted for the remaining 34.1%E of injuries (Table 3). Interestingly, 74.9% of respondents indicated that their injury was the result of someone else’s use of a laser product, while approximately 25.0%E reported their injury was caused by their own personal use of a laser product (Table 3).
Since the 1990s, improvements in laser technology and reduced manufacturing costs have facilitated the integration of laser products into daily life in an expanding array of applications, including medicine and cosmetics, security, communications, instrumentation, and entertainment. Many novel and low-cost laser products are increasingly available in the consumer marketplace. This is reflected by an increase in laser product sales, with industry analysts reporting a rise in total revenue for the global laser market from $6.32 billion in 2009 to $9.56 billion in 2014 (an increase of 51%).Note 1
Historically, laser devices were typically located in medical, industrial, commercial, research and military settings because of the cost and complexity of operating these devices. As a result, the safety of operating laser devices could be controlled through occupational training and the education of users regarding laser safety principles.Note 5 In recent years, decreased production costs have led laser devices to become increasingly prevalent in a variety of consumer products, including children’s toys. The increasing prevalence of consumer laser products, especially high-powered devices, may represent an increasing risk to Canadians, particularly if consumers lack the competency, knowledge or skills required to operate these devices safely. The use of Class 3B and 4 laser devices in an uncontrolled setting, particularly by an untrained or unknowledgeable operator, creates a risk not only to the user but also to observers and bystanders who may be unaware of the risks associated with laser exposure and may not be able to mitigate the risk using appropriate safety measures.
Birtel J, Harmening WM, Krohne TU, Holz FG, Charbel Issa P, Herrmann P. Retinal Injury Following Laser Pointer Exposure. Deutsches Arzteblatt International 2017; 114(49): 831-837.
The current study results indicated that approximately one-half of Canadians have used or been exposed to laser devices in some form in the previous 12 months. Males reported a higher prevalence of laser product usage or exposure. Sex differences become more apparent with certain laser product categories. A higher proportion of males used or were exposed to lasers for entertainment or measurement purposes, whereas females were more likely to use or be exposed to lasers for cosmetic reasons. Approximately 1% of users indicated they had suffered a laser-related injury or discomfort in the past year, among which harm to the eyes was more prevalent.
To answer these questions, we need to begin developing an understanding of the image locations for these three images and to generate the ray diagrams for these three images. It has already been pointed out that an image is the location in space where all the reflected light appears to diverge from. Everyone viewing the image would be sighting at the same location. Thus, if you were able to sight at the image from at least two different locations and extend the lines of sight behind the mirror, you would be able to determine the image location. This line of sight method is often used in Physics labs to determine the location of the three images. The diagram below shows the lines of sight that are required to view the three different images produced by a right angle mirror system. Lines of sight are drawn for two different eye locations. When these lines of sight are extended backwards, three intersection points are made - one for each image.
Lim ME, Suelzer J, Moorthy RS, Vemuri G. Thermal macular injury from a 154 mW green laser pointer. Journal of American Association for Pediatric Ophthalmology and Strabismus 2014; 18: 612-614.
Keunen JE, Delbecq AL, Cruysberg JR, et al. Laser pointers are not toys; eye injury with permanent loss of visual acuity. Nederlands Tijdschrift Voor Geneeskunde 2014; 158:A7813.