Patent Abstract:
A communications network comprised of a source of information to be transmitted in the form of a signal, one or more transmitters which emit light suitable for illumination and including means for modulating the light with the information signal, a medium such as a fluid through which the light passes, and one or more receivers for receiving the light and demodulating the signal to obtain the information. A user for the information may be a device, such as a computer or a compact disk player, or it may be a person, perhaps with some form of sensory or mental impairment. The information may be encrypted, may provide directional guidance, such as to a user moving in a vehicle, and/or may be transmitted simultaneously over multiple channels. Various types of visible light assemblies may be employed, with varying power inputs and outputs.

Full Description:
CROSS REFERENCE TO RELATED APPLICATIONS 
     This application is related to, and claims priority from, U.S. Provisional Patent Application Nos. 60/081,866 filed Apr. 15, 1998, 60/108,287 filed Nov. 13, 1998 and 60/115,374 filed on Jan. 11, 1999, all of which are now abandoned. 
    
    
     BACKGROUND OF THE INVENTION 
     A communication network is a means for conveying information from one place to another. The information can be in audio, digital data, video, text, graphics, data, sign language or other forms. The network can be a wide area network such as an intranet in an office, store or factory. Establishing and maintaining communication networks is one of the oldest known activities of mankind ranging from the shouting and drum signals of prehistory through written messages, signal flags, signal fires, smoke signals, signal mirrors, heliographs, signal lanterns, telegraphs, radios, telephones, televisions, microwave signals, linked computers and the internet. Improving communication networks will continue to be a major technical focus in the future. 
     The ideal communication network would be non-intrusive, inexpensive, extremely large information carrying capability (wide bandwidth), instantaneous and suitable for use with a broad variety of transmission and reception technologies. 
     There have been a few reports of the use of visible lighting as a carrier in electronic communication networks. The earliest reference to using lighting to send electronic information as well as to provide illumination appears to be Dachs (U.S. Pat. No. 3,900,404) disclosing an analog amplitude-modulation (AM) scheme to modulate the arc current in a fluorescent lamp, the “carrier” signal, with an audio information signal. King, Zawiski and Yokoun (U.S. Pat. No. 5,550,434) disclosed an updated electronic circuit that also provides for AM modulation of the arc current with an analog signal. Smith (U.S. Pat. No. 5,657,145) teaches a method for encoding low-bandwidth digital information into the lamp light using a pulsed AM technique. The encoding technique involves chopping 100 microsecond slices of current out of the arc waveform. Nakada ( Japanese Patent application 60-32443, Feb. 19, 1985.)reports a FM modulation and a frequency shift keying (FSK) scheme to transmit digital data using visible lighting. Gray (U.S. Pat. No. 5,635,915 Jun. 3, 1997 and PCT WO90/13067, Oct. 11, 1991.) has reported a product pricing system for supermarket shelf labels where a signal is sent from visible lighting to individual product price labels on shelves to cause the listed prices to change when desired. 
     Other communication schemes have been proposed that do not use the lamp light as the carrier, but instead use the lamp fixture as an antenna for transmitting conventional radio wave or microwave signals. In Uehara and Kagoshima (U.S. Pat. No. 5,424,859), for example, the inventors disclose techniques for mounting a microwave antenna on the glass surface of fluorescent and incandescent lamps. Buffaloe, Jackson, Leeb, Schlecht, and Leeb, ( “Fiat Lux: A Fluorescent Lamp Transceiver,” Applied Power Electronics Conference, Atlanta, Ga. 1997) first outlined the possibility of using pulse-code modulation to transmit data with a fluorescent lamp. In the latter reference, a three-level code shifts the arc frequency to one of three possibilities every Tsw=2 milliseconds. The result is a steady light output, on average, with no perceptible flicker. A one or a zero bit does not correspond to a particular arc frequency, but rather, to a three level pattern in arc frequency. A logic zero bit is transmitted by varying the arc frequency first to 40 kHz, then to 38 kHz, and finally to 36 kHz. A logic one bit is transmitted by the arc frequency pattern beginning with 38 kHz, followed by 40 kHz, and ending with 36 kHz. A unique start bit, used to demarcate the beginning of a transmitted byte, is represented by a sequence in the arc frequency beginning with 36 kHz, followed by 38 kHz, and ending with 36 kHz. 
     In our previously filed patent applications Ser. No. 09/291,706 filed Apr. 14, 1999 and entitled “Dual-Use Electronic Transceiver Set for Wireless Data Networks” and application Ser. No. 07/292,126 filed Apr. 14, 1999 entitled “Analog and Digital Electronic Receivers for Dual-Use Wireless Data Networks”, we have disclosed visible light communications networks for analog and digital data based on frequency modulation of light. The modulation techniques include direct FM, 2 level half weight bit coding and other orthogonal bit coding schemes. 
     The visible light case mentioned above is a specific case of our invention which, stated generally, involves simultaneous intentional dual use of transmitted electromagnetic radiation for two completely different useful purposes. 
     SUMMARY OF THE INVENTION 
     With the new technology disclosed in our previously filed applications, the recent advances in computer technology and other improvements in electronics, a number of applications and uses are now enabled. These applications are most preferentially executed using our new technology. However, in some cases, they may be executed using some of the other technologies known in the prior art. 
     With reference to FIG. 4, our communication network contains the following elements in series: 
     a) A source ( 50 ) of the information which will be transmitted; 
     b) A transmitter ( 54 ), which includes lamp and a means for controlling the modulation of the lamp to cause the lamp to carry a signal; 
     c) A medium ( 56 ) through which the light passes from the transmitter to the receiver ( 60 ,  76  or  108 ); 
     d) A receiver for receiving and demodulating the light in order to obtain the information; and 
     e) A user ( 62 ,  96  or  98 ) for the information. This user can be a device, like a computer or a compact disk player, or it can be a person. 
     Our invention embodies a number of uses and purposes for the light based communication network. One purpose is to process the signal from the light is by the receiver to control the selection of information from a computer memory, CD or other storage device for large scale storage of data, greatly increasing the effective bandwidth of the information which can be transmitted. Another purpose is to provide data to the user from the receiver from both a large scale data storage device, like a computer memory, compact disk or other such device, and from the information transmitted by the light, with segments of data from the sources interspersed in presentation to the user. Another purpose is to provide data from a device source, like a computer chip, a tape cassette a compact disk or other such device, to the transmitter. Another purpose is to repeat continually the data from the device source, providing a continuous signal of finite period to the user. Another purpose is to use two or more transmitting lights, each transmitting its own signal at the same frequency to provide spatial resolution of signal so that the receiver will receive and provide to the user information from only one of the lights at any time and the receiver may shift its reception from one light to another. Another purpose is to transmit two or more different signals simultaneously at different frequencies from one light in such a manner that two or more receivers can each pick up the different signals. Another purpose is to transmit two or more different signals containing the same information in two or more different languages or codes so that by selecting the proper frequency, the user can select information in the language or code they deem most suitable. Another purpose is to encrypt the information prior to transmission and decrypted it subsequent to receipt. Another purpose is to use the lighting of an individual exhibit to provide to the user a description of some aspect of the exhibit. Another purpose is to transmit information over the network is used to provide assistance to individuals who are visually impaired. Another purpose is to transmit information transmitted over the network to provide assistance to individuals who are hearing impaired. Another purpose is to transmit over the network to provide assistance to individuals who are mentally impaired. Another purpose is to transmit the information transmitted over the network for processing by the user and subsequent sending out of a responding signal by the user using some means. Another purpose is to use the network to provide information to a receiver and user which are moving. Another purpose is to use the network to provide information inside an aircraft, boat, submarine, bus, auto, train or other vehicle. Another purpose is to use the network to provide guidance information to a receiver and user which are moving. Another purpose is to use the network to provide safety or warning information. Another purpose is to use create a network where the same information is being provided by a plurality of different lights. Another purpose is to use the network to provide paging information to the user. Another purpose is to provide information in classrooms and other meeting rooms. Another purpose is to create a repeater network where the modulated signal initiated by one light will be received by an adjoining light, that light started modulating, etc. until all lighting in a network is being modulated and carrying the signal. Another purpose is to create a network in which the electromagnetic radiation which is modulated is infrared radiation. Another purpose is to create a network in which the electromagnetic radiation which is modulated is ultraviolet radiation. Another purpose is to create a network in which the electromagnetic radiation which is modulated is radio frequency radiation. Another purpose is to create a network in which the electromagnetic radiation which is modulated is microwave radiation. Another purpose is to create a network in which the electromagnetic radiation which is modulated is X-ray radiation. Another purpose is to create a network to transmit compressed data. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a schematic illustration of the invention. 
     FIG. 2 is a schematic illustration of a guidance embodiment of the invention. 
     FIG. 3 is a schematic representing the relationship among various elements that may comprise the communication network of the present invention. 
     FIG. 4 is a schematic illustrating another embodiment of the communication network of the present invention. 
     FIG. 5 is a schematic illustrating how the communication network of the present invention may be used in connection with a vehicle. 
     FIG. 6 is a schematic representing the relationship among various elements that may comprise the communication network of the present invention. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENT 
     A Computer as a User 
     One important application for our communication network involves inputting data into a computer. In one usage of this approach, light can be used as a positional locator or a data source. One such device which would use light provided digital data we will refer to as a Personal Locator and Minder or PLAM. In this system, each modulated light will deliver a relatively simple unique signal. This signal could either be a random signal which is uniquely assigned to that light, or else could be based on some kind of geographical matrix. The Personal Locator and Minder will receive the signal from the nearest modulated light, identify the location of that light from information in its memory, compare the location of that light with the location the PLAM is scheduled to be at that particular moment, and then carry out appropriate actions in accordance with its preprogramming. This aspect has application to patients in a hospital or assisted care facility context. 
     Since each patient has their own PLAM programmed with their own schedule, the system can accommodate as many different patients simultaneously as is desired. Each light will be continuously communicating location. The individual patient&#39;s PLAM will be reading this location information and then giving the individualized guidance to the patient. 
     The second programming feature which can be included in the PLAM will be the ability to record the daily activities and mobility of a patient. In addition to providing and cueing a personal schedule for a patient, the PLAM can also record how many warnings or inconsistencies in schedule versus actual location occurred during the course of an arbitrary time interval. This information could be stored in the PLAM and downloaded when convenient giving a unique and highly detailed record of a patient&#39;s mobility and awareness at every location and time during a day. 
     Another important application for the computer as user will involve the use of an addressable electronic memory device. This device can be a RAM type device, ROM computer memory or storage device like a CD. The addresses can be partially or totally selected based on information provided over modulated lights. The information from the memory can then be used for any of the purposes well known in the art. 
     Still another application for the computer as user involves the decryption of an encrypted message. As illustrated in FIG. 3, the message is encrypted using a method known in the prior art for which there is a decryption key  64 . The key  64  is not provided to the user  68  and is not retained in the computer. The decryption key  64  is supplied continually over the modulated lights. Only when the lights are providing the key  64  can the user  68  decode the information. The security code can be varied in a timed fashion or some other method known in the art. This providing of the decryption code  66  by the lights will provide an additional level of security since only when the user is in the physical presence of the lights will the encrypted message be able to be decoded. 
     The most general statement of our invention is that it involves simultaneous intentional dual use of transmitted electromagnetic radiation for two or more functionally different useful purposes. An example of such a dual use of electromagnetic radiation other than visible radiation would involve the frequency modulation of a radar signal used to track civilian aircraft so that it also would carry audio information to the aircrew. Another such example would involve the modulation of an infrared illuminator used to allow night vision goggles to be used so that the operator of the illuminator could communicate with the wearer of the night vision goggles or with another user in the field of vision of the infrared illuminator. One preferred embodiment of this invention in electromagnetic wavelength ranges outside the visible is in the infrared wavelength range, another preferred embodiment is in the ultraviolet wavelength range, another preferred embodiment is in the X-ray wavelength range, another is in the radio wavelength range, another is in the microwave wavelength range. 
     When the wavelength range of the electromagnetic radiation used for one or more simultaneous functionally different useful purposes is outside the visible wavelength range, we will refer to that radiation as “non-visible radiation.” With reference to FIGS. 3 and 6, it is understood that under some circumstances, a source  50  which is intended to generate electromagnetic radiation outside the visible wavelength range will also generate some visible radiation, such as through transmitter  54 . If one or more of the simultaneous useful purposes makes principal use of radiation outside the visible wavelength range, it will be considered “non-visible radiation” notwithstanding the generation of the visible radiation. An example would be a suntanning booth in which the UV light source would be modulated by a means  52  in order to allow communication with the user. Even though the UV light source  50  would simultaneously generate some visible electromagnetic radiation, the useful purpose of tanning the skin would make principal functional use of ultraviolet radiation, so this radiation would qualify as “non-visible radiation.” This designation as “non-visible radiation” would pertain whether the modulated UV light is detected by the receiver  60  and used for communication, or the simultaneously generated visible electromagnetic radiation is detected by the receiver and used for communication. Since one useful purpose, namely tanning the skin, makes principal use of electromagnetic radiation outside the visible wavelength range, the radiation qualifies as “non-visible radiation.” 
     In one preferred embodiment of this invention, one useful functional purpose of the embodiment is communication and the other useful functional purpose is some purpose other than communication. In another preferred embodiment, both useful functional purposes of the embodiment are some purpose other than communication. 
     In one preferred embodiment of the invention, one of the useful functional purposes makes primary use of electromagnetic radiation outside of the visible wavelength range. In another preferred embodiment of the invention, two or more of the useful functional purposes make primary use of electromagnetic radiation outside of the visible wavelength range. 
     An essential part of this invention is that the electromagnetic radiation must be free from application unacceptable flicker. Generally, this application unacceptable flicker occurs when variations due to the second utility of the radiation interfere with the first utility or vice versa. An example of application unacceptable flicker for visible radiation would be visually perceptible flicker such that the light is considered unacceptable for illumination. For other examples, such as a radar set, application unacceptable flicker could mean that the flicker would interfere with radar detection. 
     In the examples below, the exact circuitry and systems can be designed and built by an individual of ordinary skill in the art of electrical engineering using, where appropriate, the unique communication network of our previously filed patent applications identified above. 
     EXAMPLE 1 
     Personal Locator and Minder Network 
     As is shown in FIG. 1, the network is created with a plurality of modulated lights  30 , each transmitting its own unique signal. In a preferred embodiment, each modulated light  30  is self contained, except optionally for a power supply, which can be either line power or battery power. The modulated lights are not controlled from a central location. 
     The PLAM in this example contains a photocell  32  capable of receiving light and circuitry capable of demodulating the signal from the nearest light and identifying the unique signal, a clock  34 , a computer memory  36  capable of storing the desired location of the PLAM at any specified time, and a computer  38  capable of evaluating signal received from the photocell  32 , comparing that signal with the desired location of the PLAM and presenting information to the user based on the comparison. This information could be reassurance or silence if the signal received is the desired preprogrammed location signal, while it could be guidance or remonstrance if the signal received is not the desired preprogrammed location signal. 
     Each of a plurality of users can have their own PLAM programmed with their own schedule. Each light will be continuously communicating location. The individual user&#39;s PLAM will be reading this location information and then giving the individualized guidance to the user. 
     PLAM and its enhancements can be valuable to a number of users including brain disabled individuals, such as individuals suffering from traumatic brain injury, Alzheimer&#39;s disease or other dementia; children in a child care environment; and individuals in a secure environment whose movements must be monitored and recorded. 
     EXAMPLE 2 
     Enhanced Personal Locator and Minder 
     PLAM is programmed with the planned schedule for the user. When the time for one of the day&#39;s scheduled activities is noted by PLAM, the device takes note of the nearest modulated light and compares that with the location where the patient should be. If the light is in the place where the user is scheduled to be, the device simply notes this. However, if the user is in a place other than where he or she is scheduled to be, the device will remind the user of their scheduled location. A more sophisticated version of PLAM will also have in its memory the proper route for the patient to take to proceed to their desired location. As the user would proceed along the path to their desired location, PLAM will take note of the lights which the device is passing and correct the patient if they should take a wrong turn or stop. 
     EXAMPLE 3 
     Personal Locator and Minder with Alarm 
     The PLAM also contains a radio transmitter, microwave transmitter or other transmitter device. If the user of the PLAM is determined by the computer to be in an unauthorized area, this PLAM sends a signal to an attendant. This attendant could be a nurse in a hospital environment, a teacher or day care attendant in a day care environment or a security guard in a secure environment. 
     EXAMPLE 4 
     Personalized Voice Messages 
     In the previous examples, the computer memory of the PLAM is programmed with a voice of personal significance to the user. We define a voice of personal significance to the user to be a voice of a person who has some significant emotional and/or historical tie to the user. Most preferred as voices of personal significance would be the voice of the person themself, or the voices of the person&#39;s parents, siblings, children, spouse, business partners, or close friends. Other examples of voices of personal significance, not intending to be limiting, would be the person&#39;s former spouse(s), school classmates, friends and acquaintances, coworkers, current or former neighbors, and physicians, nurses or other caregivers. 
     EXAMPLE 5 
     Enhanced PLAM with Recording Capability 
     To the PLAM of Example 2 will be the ability to record the daily activities and mobility of a user. In addition to providing and cueing a personal schedule for a user, the PLAM can also record how many warnings or inconsistencies in schedule versus actual location occurred during the course of an arbitrary time interval. This information could be stored in the PLAM and downloaded when convenient by a monitor, such as a skilled care provider, giving a unique and highly detailed record of a user&#39;s mobility and awareness at every location and time during a day. 
     EXAMPLE 6 
     Programming the PLAM Using Modulated Lighting 
     To the PLAM of Example 2 will be add the ability to have the programming in the computer changed by information received over the lighting. The programming information is transmitted over light using one of the techniques previously taught. The information is prefaced with a code to indicate to the computer that it is programming information. The programming information so received is then stored in the computer memory and used by the computer in making decisions and in giving guidance to the user. 
     EXAMPLE 7 
     Message Selected from Computer Memory 
     A memory device such as a computer memory, CD, or tape is loaded with a number of messages which can prove useful. Each message is stored in a coded, identifiable location in the memory device. A coded signal is sent over the network indicating which coded location and which message should be played. The coded signal is received, processed by a computer and used to identify and call up the message from the memory. The message from the memory is presented to the user. This message could be an audio message, textual message, graphical message or other message. 
     EXAMPLE 8 
     Mixed Message from Computer Memory and Light Carried Message 
     The devices of Example 7 have an enhanced capability to receive and process more extensive information from the lights. The system has the capability to present information in a mixed fashion. As an example, the system could be cued to present and then present aurally “This is the office of” from the computer memory and then “Mr. Smith” from the light transmitted audio message. 
     EXAMPLE 9 
     Encryption Code 
     A message is encrypted using one of a number of encryption techniques known in the art which require an decryption code. The user is not provided with the decryption code. The computer or other device provided to the user has a receptor circuit which can receive and process encoded signals from the lighting in the area. The ambient lighting is modulated to contain the decryption code. The computer is able to process and decrypt the encrypted message only so long as the receptor circuit is viewing and processing the decryption code. 
     EXAMPLE 10 
     Multiple Channels 
     With reference to FIG. 4, a network is constructed with two or more lights  72 ,  74  in proximity transmitting information on two or more different frequencies or else with one or more lights each transmitting information on two or more different frequencies creating channels of information. A receiver  76  is provided which is able to receive and process information from these channels. Different information is transmitted on the different channels, which may be received by different users  96 ,  98 . 
     EXAMPLE 11 
     Multiple Channels to Transmit Different Languages 
     In the network of Example 10, information is transmitted using the different channels to transmit different languages. As an example, one channel could transmit information in English and another channel to transmit the same information in Spanish. 
     EXAMPLE 12 
     Lighting to Provide Descriptions of Exhibits 
     In an facility where there are two or more areas with different items being exhibited, each area is provided with its own separate lighting. This lighting is modulated to provide a description of the exhibit which is being lighted. The user is provided with a receptor which will allow the user to receive a description of the exhibit. As the user moves from one exhibit to another, the lighting provides the appropriate description of the exhibit which they are viewing. 
     EXAMPLE 13 
     Assistance to the Visually Impaired 
     The lights in a facility are modulated to provide guidance information to individuals who are visually impaired. This information could be of the sort of “Office X is on the right” or “The stairs are on the left.” A visually impaired individual would have a receptor to process this information and receive the guidance. 
     EXAMPLE 14 
     Assistance to the Hearing Impaired—Aural 
     The lights in a facility are modulated to provide information to individuals who are hard of hearing and require assistance. The information could be provided through a speaker, earphones or through a neck loop into a magnetic induction type hearing aid. 
     EXAMPLE 15 
     Assistance to the Hearing Impaired—Textual 
     The lights in a facility are modulated to provide information to individuals who are deaf or hard of hearing and require assistance. The information could be textual, graphical or pictorial information. 
     EXAMPLE 16 
     User which is Moving 
     The lights in an area are modulated to contain information. A user which is moving is provided with a receiver. Information is transmitted to the user which is moving. 
     EXAMPLE 17 
     Lighting Inside a Vehicle 
     The lighting  58  inside or on a vehicle  82  is modulated to contain information. A user  62  inside or on the vehicle is provided with a receiver  60 . Information is transmitted to the user  62  which is inside or on the vehicle. The vehicle can be an aircraft, boat, submarine, bus, auto, tank, other military vehicle, wheelchair, spacecraft or other vehicle. The vehicle can be moving or stationary. 
     EXAMPLE 18 
     Guidance and Directional Information to a Vehicle 
     Lighting  58  outside a vehicle  86  is modulated to provide information. Each light or sequence of lights is modulated to contain directional information or guidance information. The vehicle has sensors which in a sequential form will view the lights. By processing the information from the lights in sequence, and determining which lights are and are not in the field of view of the sensors, the vehicle can maintain its direction of travel. This is shown in the FIG. 2 below. 
     EXAMPLE 19 
     Modulated Running Lights 
     Circuitry is provided to modulate the running lights on a vehicle  88 . These lights will carry information generated by a source  50  inside the vehicle  88 . A receiver  60  outside the vehicle can receive and process this modulated light and process the information to a user  62  outside the vehicle. Another embodiment of this example would be the modulation of the headlights on a vehicle. 
     EXAMPLE 19 
     Repeater Network 
     One light in a facility is modulated with a signal to carry information. An adjoining light has a receptor which is positioned to view the signal from the first light. This signal is processed by the circuitry in the second light and the signal from the second light is modulated to transmit the same signal as is contained in the modulated signal from the first light. A third light has a receptor which is positioned to view the signal from the second light. This light also has a repeater circuit similar to the second light. A network of lights throughout the facility is, in this manner, modulated to carry the same signal as the first light. 
     EXAMPLE 20 
     Transmission Through Fluid 
     A light is modulated to carry a signal. The electromagnetic radiation from this light is allowed to fall on a receiver/receptor  60  and the signal is processed. Water  90  is placed in the path between the light and the receiver  60 . No change is observed in the signal which is processed. The light is carried by a SCUBA diver who is underwater and is using the light for underwater illumination. The receiver is carried by another SCUBA diver who makes use of the information transmitted by the modulated light. 
     EXAMPLE 21 
     Transmission Through Vacuum or a Reduced Pressure Medium 
     A light is modulated to carry a signal. The electromagnetic radiation from this light is allowed to fall on a receiver/receptor and the signal is processed. Air or any other gas is partially or completely removed from the medium between the light and the receiver to a pressure below 0.5 atmospheres. No change is observed in the signal which is processed. The light is carried by an astronaut who is in space and is using the light for illumination. The receiver is carried by another astronaut or by a spacecraft which makes use of the information transmitted by the modulated light. 
     EXAMPLE 22 
     Signal Source from Computer Memory Provides Repetitive Signal 
     A computer memory is programmed to repeat, continuously, an information signal. This information signal is used to control the modulation of a light signal. A receiver receives and processes this information. 
     EXAMPLE 23 
     Signal Source Provides Non Repetitive Signal 
     A non repetitive signal is provided from a microphone, tape, CD, record or other information storage device. This non-repetitive signal is used to control the modulation of a light signal. A receiver receives and processes this information. 
     EXAMPLE 24 
     Lecture Hall 
     A network is created in a facility where two or more users are present. The users each have individual receivers and make personal use of the information transmitted by the lights. 
     EXAMPLE 25 
     Non-visible Radiation—Ultraviolet 
     A mercury vapor lamp capable of producing ultraviolet radiation which can tan the skin modulated to carry information. A receiver of the type taught in the co-pending application above is able to detect the fraction of the radiation in visible range, demodulate it and extract the transmitted signal. Alternately, a photodetector capable of detecting ultraviolet radiation is used and the modulated ultraviolet radiation is detected, demodulated and the transmitted signal extracted and presented to the user. The ultraviolet light is also used for tanning the skin of the user. 
     EXAMPLE 26 
     Non-visible Radiation—Infrared 
     An infrared illuminator is used to provide illumination for a viewing device which can receive infrared radiation and present it to a user as a visible display. This infrared illuminator is modulated to carry an analog audio signal. A receptor of the type taught in the co-pending application above is provided to receive and process this analog audio signal. 
     EXAMPLE 27 
     Non-visible Radiation—MRI 
     A user is placed in an MRI device. The device is operated in the normal fashion, using electromagnetic radiation of the proper wavelength to create magnetic resonance. This electromagnetic radiation is also modulated to carry information to allow communication with the user. 
     EXAMPLE 28 
     Compressed Data 
     Data from the signal source  50  is compressed using a compression technique known in the art. Compressed data  104  is transmitted over the network. The data is decompressed after it is received and processed by the receiver  60 . The decompressed data is presented to the user  106 .

Technology Classification (CPC): 7