Personal telecommunication device with target-based exposure control

Exemplary methods, systems and components enable detection and/or monitoring and/or control of electromagnetic radiation (EMR) exposure of target body-related portions of a user operating a telecommunication device. In some embodiments a risk-assessment output is provided based on a safety threshold or predetermined intrusion level of EMR exposure.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application is related to and claims the benefit of the earliest available effective filing date(s) from the following listed application(s) (the “Related Applications”) (e.g., claims earliest available priority dates for other than provisional patent applications or claims benefits under 35 USC §119(e) for provisional patent applications, for any and all parent, grandparent, great-grandparent, etc. applications of the Related Application(s)). All subject matter of the Related Applications and of any and all parent, grandparent, great-grandparent, etc. applications of the Related Applications is incorporated herein by reference to the extent such subject matter is not inconsistent herewith.

RELATED APPLICATIONS

For purposes of the USPTO extra-statutory requirements, the present application constitutes a continuation-in-part of U.S. patent application Ser. No. 12/803,143 entitled IRRADIATION SELF-PROTECTION FROM USER TELECOMMUNICATION DEVICE, naming Roderick A. Hyde, Muriel Y. Ishikawa, Jordin T. Kare, Thomas J. Nugent, Jr., Clarence T. Tegreene, Thomas A. Weaver, Lowell L. Wood, Jr., Victoria Y. H. Wood as inventors, filed on Jun. 18, 2010, which is currently co-pending, or is an application of which a currently co-pending application is entitled to the benefit of the filing date.

The United States Patent Office (USPTO) has published a notice to the effect that the USPTO's computer programs require that patent applicants reference both a serial number and indicate whether an application is a continuation or continuation-in-part. Stephen G. Kunin,Benefit of Prior-Filed Application, USPTO Official Gazette Mar. 18, 2003, available at http://www.uspto.gov/web/offices/com/sol/og/2003/week11/patbene.htm. The present Applicant Entity (hereinafter “Applicant”) has provided above a specific reference to the application(s) from which priority is being claimed as recited by statute. Applicant understands that the statute is unambiguous in its specific reference language and does not require either a serial number or any characterization, such as “continuation” or “continuation-in-part,” for claiming priority to U.S. patent applications. Notwithstanding the foregoing, Applicant understands that the USPTO's computer programs have certain data entry requirements, and hence Applicant is designating the present application as a continuation-in-part of its parent applications as set forth above, but expressly points out that such designations are not to be construed in any way as any type of commentary and/or admission as to whether or not the present application contains any new matter in addition to the matter of its parent application(s).

BACKGROUND

The present application relates to electromagnetic radiation monitoring and control devices and related methods, systems, components, computerized apparatus, software program products, and communication techniques.

SUMMARY

In one aspect, an exemplary method of facilitating irradiation protection for a specified target body region may include identifying the specified target body region of a user that is proximate to a particular communication device capable of generating electromagnetic emissions that subject the specified target body region to irradiation exposure; establishing whether such irradiation exposure does exceed or is predicted to exceed a safety threshold correlated with the specified target body region; and if such irradiation exposure has a dosage value above the safety threshold, providing a responsive output based on a possible risk relative to such irradiation exposure.

In another aspect, an exemplary system includes but is not limited to computerized components for managing electromagnetic irradiation from a telecommunication device, which system has the capability to implement the various process features disclosed herein. Various exemplary system aspects are described in the claims, drawings, and text forming a part of the present disclosure.

Some system embodiments for facilitating irradiation protection for a specified target body region may include means for identifying the specified target body region of a user that is proximate to a particular communication device capable of generating electromagnetic emissions that subject the specified target body region to irradiation exposure; means for establishing whether such irradiation exposure does exceed or is predicted to exceed a safety threshold correlated with the specified target body region; and means that is activated based on such established irradiation exposure having a dosage value above the safety threshold, wherein such activated means is configured to provide a responsive output based on a possible risk relative to such irradiation exposure.

Other system embodiments for facilitating irradiation protection for a specified target body region may include data record means for identifying the specified target body region of a user that is proximate to a particular communication device capable of generating electromagnetic emissions that subject the specified target body region to irradiation exposure; monitoring and/or detection means for establishing whether such irradiation exposure does exceed or is predicted to exceed a safety threshold correlated with the specified target body region; and control circuit means that is activated based on such established irradiation exposure having a dosage value above the safety threshold, wherein such control circuit means is configured to provide a responsive output based on a possible risk relative to such irradiation exposure.

In a further aspect, a computer program product may include computer-readable media having encoded instructions for executing a method of facilitating irradiation protection for a specified target body region, wherein an exemplary method may include identifying the specified target body region that is proximate to a particular communication device capable of generating electromagnetic emissions that subject the specified target body region to radiation exposure; establishing whether such radiation exposure does exceed or is predicted to exceed a safety threshold correlated with the specified target body region; and if such radiation exposure has a dosage value above the safety threshold, providing a responsive output based on a possible risk relative to such radiation exposure.

In addition to the foregoing, various other method and/or system and/or program product aspects are set forth and described in the teachings such as text (e.g., claims and/or detailed description) and/or drawings of the present disclosure.

DETAILED DESCRIPTION

Alternatively or additionally, implementations may include executing a special-purpose instruction sequence or invoking circuitry for enabling, triggering, coordinating, requesting, or otherwise causing one or more occurrences of virtually any functional operations described herein. In some variants, operational or other logical descriptions herein may be expressed as source code and compiled or otherwise invoked as an executable instruction sequence. In some contexts, for example, implementations may be provided, in whole or in part, by source code, such as C++, or other code sequences.

In other implementations, source or other code implementation, using commercially available and/or techniques in the art, may be compiled/implemented/translated/converted into a high-level descriptor language (e.g., initially implementing described technologies in C or C++ programming language and thereafter converting the programming language implementation into a logic-synthesizable language implementation, a hardware description language implementation, a hardware design simulation implementation, and/or other such similar mode(s) of expression). For example, some or all of a logical expression (e.g., computer programming language implementation) may be manifested as a Verilog-type hardware description (e.g., via Hardware Description Language (HDL) and/or Very High Speed Integrated Circuit Hardware Descriptor Language (VHDL)) or other circuitry model which may then be used to create a physical implementation having hardware (e.g., an Application Specific Integrated Circuit). Those skilled in the art will recognize how to obtain, configure, and optimize suitable transmission or computational elements, material supplies, actuators, or other structures in light of these teachings.

Those skilled in the art will recognize that it is common within the art to implement devices and/or processes and/or systems, and thereafter use engineering and/or other practices to integrate such implemented devices and/or processes and/or systems into more comprehensive devices and/or processes and/or systems. That is, at least a portion of the devices and/or processes and/or systems described herein can be integrated into other devices and/or processes and/or systems via a reasonable amount of experimentation. Those having skill in the art will recognize that examples of such other devices and/or processes and/or systems might include—as appropriate to context and application—all or part of devices and/or processes and/or systems of (a) an air conveyance (e.g., an airplane, rocket, helicopter, etc.), (b) a ground conveyance (e.g., a car, truck, locomotive, tank, armored personnel carrier, etc.), (c) a building (e.g., a home, warehouse, office, etc.), (d) an appliance (e.g., a refrigerator, a washing machine, a dryer, etc.), (e) a communications system (e.g., a networked system, a telephone system, a Voice over IP system, etc.), (f) a business entity (e.g., an Internet Service Provider (ISP) entity such as Comcast Cable, Qwest, Southwestern Bell, etc.), or (g) a wired/wireless services entity (e.g., Sprint, Cingular, Nextel, etc.), etc.

In certain cases, use of a system or method may occur in a territory or location even if components are located outside the territory or location. For example, in a distributed computing context, use of a distributed computing system may occur in a territory or location even though parts of the system may be located outside of the territory or location (e.g., relay, server, processor, signal-bearing medium, transmitting computer, receiving computer, etc. located outside the territory or location).

A sale of a system or method may likewise occur in a territory even if components of the system or method are located and/or used outside the territory. Further, implementation of at least part of a system for performing a method in one territory does not preclude use of the system in another territory.

As used herein, the term “vehicle” encompasses devices for conveying persons or objects, including without limitation automobiles, trucks, motorcycles, buses, trains, and other land conveyances, boats, ferries, ships, and other watergoing vessels, and aircraft.

FIG. 1is a schematic block diagram illustrating exemplary embodiment features for an irradiation protection system regarding attenuated electromagnetic radation emissions90generated from a telecommunication unit50toward a target person100, a target body part102, and/or a target device104associated with the target person100. One or more user telecommunication units50,85may respectively include antennas75,84for data transmissions directly to or from antenna81of base station80. In some instances such data transmissions may be facilitated indirectly via a local relay or repeater or booster unit82.

The illustrated embodiment for telecommunication (telecom) unit50is configured to include various components that facilitate irradiation protection, include an electromagnetic radiation (EMR) calibration table52, operation mode monitor54, one or more application programs56, operation mode controller58, user-selective control62, radiation warning output64, memory66and processor68. Additional features may include user interface72and data/status display74.

Some system embodiments may provide a receptacle105(e.g., surface, bracket, holder, etc.) adapted to position the telecommunication unit50for functional availability to a user. It will be understood that an evaluation of irradiation risks regarding the target person100or target body part102or target device104may be at least partially dependent on determining an approximate location for the telecommunication unit50during an active operation mode. Accordingly a system feature may include a location determination module110for obtaining fixed telecom unit location coordinates relative to one or more target body regions106, as well as obtaining variable telecom location coordinates relative to one or more target body regions106. The location determination module may be incorporated with or otherwise linked with the telecom unit50for appropriate data processing regarding irradiation risks.

It will be understood that in some circumstances the telecom location coordinates may already be known or predetermined (e.g., mounted in an identifiable given location relative to a user's body). However in other circumstances variable telecom location coordinates may be obtained in real time (e.g., a hand-held mobile telecom unit) in order to evaluate an irradiation exposure risk for a target body region of a user.

It will be further understood that an evaluation of irradiation risks may be at least partially dependent on determining an approximate separation distance between the telecom unit50and the target person100or target body part102or target device104. Accordingly an exemplary system feature may include a proximity detection module115for detecting and/or monitoring such approximate separation distance. In some instances the separation distance may be determined relative to the antenna75(e.g., internal or external antenna) of the telecom unit50, or relative to the receptacle105for the telecom unit50, or relative to another identifiable aspect of the telecom unit50.

Additional possible system components for detection and/or monitoring of electromagnetic emissions generated from the telecom unit50may include an on-board sensor92incorporated with the telecom unit50as well as in some instances an off-board sensor94preferably located in close proximity to one or more targeted body regions100,102,104. Such sensors92,94may be desirable for some embodiments to transmit pertinent data via communication links to the telecom unit50as well as transmit pertinent data via communication links to a cumulative data record70for electromagnetic irradiation exposure to specified target areas. In some embodiments where a calibrated radiation value for the telecom unit50has already been determined (e.g., by the manufacturer or seller or user or third party, etc.), the sensors92,94may not be required to provide real-time irradiation data. In other embodiments a previously calibrated radiation value may provide a sufficient basis for suggesting or implementing remedial action that minimizes excessive irradiation exposure of a targeted body region of a user.

FIG. 2is a schematic block diagram depicting exemplary system components configured to provide electromagnetic radiation protection (e.g., risk assessment, output data, warning signal, remedial action, etc.) to a user120of a telecom unit115(e.g., mobile phone, etc.) that may be operated in various locations relative to the user120while sending and/or receiving communication signals directly with another communication transceiver or via a local network or via one or more transmission towers172,192. Typical locations for the telecom unit115may be handheld171(e.g., displaced body location170, adjacent head location171) as well as receptacle-type locations in an enclosed pants pocket175or partially exposed chest shirt pocket185or on a belt180. Another possible location may be head-mounted with an earpiece187and microphone188having wired189aor wireless189bconnections. In some instances the telecom unit115may be positioned at a location195separate and independent of the user120such as on a desk or table196. Of course other locations are possible, and the depicted locations are for purposes of illustration only.

An exemplary system embodiment for a telecommunication EMR protection unit125may include an operation mode monitor & controller140configured to monitor and/or control various operational modes130of the telecom unit115that are related to the generation of radiation emissions. Exemplary operational modes may include off-line131, on-line132, text send and/or receive133, voice mail store134, voice send and/or receive136, signal search137, and reduced power138. It will be understood that other operational modes could be related to radiation emissions, and the depicted examples are for purposes of illustration only.

The telecommunication EMR protection unit125and its operation mode monitor & controller140may be operably coupled to a lookup table that includes data for varied EMR intrusion levels150, wherein one or more such EMR intrusion level may be associated with different target body regions and/or different types of users. As illustrated inFIG. 2, exemplary target body regions may include a body implant device161, and may further include an electronic body unit162. Exemplary identifiable individual users of the telecom unit115having different irradiation risks as well as in some instance having different selective or consequential remedial actions may include Roger151, Bob152and Amy153. Exemplary categories of telecom users having different irradiation profiles (e.g. target body region, type of remedial action, cumulative irradiation limits, etc.) may include children under six years of age154youngsters in the age range six through sixteen156, adults over twenty years of age157, pregnant women158, and frequent telecom users159. Depending on the circumstances, some target body regions and some user types may not be applicable, and additional target body regions and other user types may be included in order to customize the irradiation protection.

The telecommunication EMR protection unit125and its operation mode monitor & controller140may also be operably coupled with a location determination module200configured for confirmation of a predetermined and/or real-time location for an EMR source (e.g., mobile telecom unit115). As illustrated inFIG. 2, such locations may include an enclosed pants pocket203, chest shirt pocket204, belt clip206, workdesk holder207and head set208. The location determination module200may be incorporated in the telecom unit115or located separately, and is configured to recognize and process a detectable parameter212that is associated with and identifies each location.

It will be understood that some system embodiments may include location coordinates for a known location (e.g., receptacle-type location), yet nevertheless require additional confirmation that a mobile version of the telecom unit115is currently positioned at such known location. In other system embodiments, a non-mobile version of the telecom unit115may always be fixedly attached at such known location (e.g., desktop transceiver, permanent vehicle transceiver, etc.)

For example, detection of minimal ambient light213could confirm the real-time location of a mobile version of telecom unit115in the enclosed pants pocket203; detection of a louder heartbeat214could confirm the real-time location of a mobile version of the telecom unit115in the chest shirt pocket204, and detection of a conductive junction could confirm the real-time location of a mobile version the telecom unit115attached to the belt clip206.

Other examples may include detection of an activated direct-line code signal217as confirmation of the real-time location of the telecom unit115in the workdesk holder, and may further include detection of a thermal output218as confirmation of the real-time location of the telecom unit115as part of the headset208. Depending on the circumstances, the workdesk holder for some users may constitute a permanent attachment for the telecom unit115, or may constitute for other users an optional location for a mobile version of the telecom unit115. Similarly in some circumstances the headset location may be an optional telecom unit location for some users (e.g., only used when driving a vehicle, etc.), or in other circumstances may be a virtually permanent telecom unit location (e.g., telemarketer employee continually making calls while keyboarding results, etc.).

Various technology techniques may be incorporated in the system components depicted inFIG. 2, including circuitry configured to ascertain a separation distance between the EMR source and a targeted body region by processing data obtained by one or more of the following types of proximity measurement and/or location detection techniques: ultrasound, infrared (IR), ultraviolet (UV), radio frequency (RF), radio frequency identification (RFID) tag, capacitive sensor, electromagnetic reflection, phase-change, charge-coupled device (CCD) light detection, thermal sensor, image recognition, and audio time of flight.

An EMR source located in the enclosed pants pocket203may provide increased irradiation risk to reproductive organs. An EMR source located in the chest shirt pocket204may provide increased irradiation risk to the cardiovascular region (e.g., heart, lungs, heart pacemaker, etc.). An EMR source located on the belt clip206may provide increased irradiation risks to the abdomen and to reproductive organs. An EMR source located on a workdesk holder207have provide increased cumulative irradiation risk to the entire body. An EMR source located in a headset208may provide increased irradiation risk to the cerebral area (e.g. eyes, ears, brain, etc.). It will be understood that in some system embodiments, various types of intrusions level or warnings or remedial action or the like may be customized to provide appropriate irradiation protection for a particular user of the telecommunication unit115.

Referring to exemplary features depicted in the schematic block diagram ofFIG. 3, a vehicle240may have a driver242and a passenger244who are each potential users of a transceiver245capable of sending and or receiving data signals246via wireless transmissions. During operational usage, the transceiver245may during certain time periods be held in a fixed position by a transceiver support holder275have predetermined location parameter276. The transceiver245may have a communication link directly or indirectly with an EMR control module250that could be incorporated as part of the transceiver245or situated in the vehicle240or located remotely from the vehicle240depending on the circumstances.

The EMR control module250may include a user interface252, processor254, data/status display256, as well as additional components including GPS unit262, proximity detection module263, remedial action selector266, and warning indicator267(e.g., visual, aural, musical, etc.). Further possible components may include one or more radiation monitors and/or sensors260for detection of radiation emissions generated by the transceiver245and/or for monitoring operational modes of transceiver245that generate radiation emissions above one or more predetermined intrusion levels. A further component may include a telecom operation mode controller270for implementing remedial action such as a modification and/or termination of a currently active operational mode.

Additional reference data features may be provided for different types of transceivers. For example, the EMR control module250may include an EMR calibration table for a telecom unit “B”273as well as a different EMR calibration table for a telecom unit “A”272. As a further example, the EMR control module250may include radiation profile data for different users, including one or more irradiation protection limits for a driver owner281, one or more irradiation protection limits for a driver teenager282, one or more irradiation protection limits for a passenger #1(see283), and one or more irradiation protection limits for a passenger #2(see284).

Some exemplary embodiments may further provide wired287and/or wireless288communication links between the EMR control module250and a cumulative radiation record290for maintaining updated irradiation exposure data applicable to driver owner297, driver teenager296, passenger #1(see292), and passenger #2(see291).

It will be understood that a transceiver245that is utilized in variable rather than fixed locations within vehicle240may also be subjected to the monitoring and/or control techniques disclosed herein to provide protection to a driver or passenger against excessive irradiation exposure.

FIG. 4is a schematic representation of exemplary data tables for varied emission & exposure values. It will be understood that some embodiments may provide emphasis on EMR emission values that are monitored or measured at or in close proximity to a radiation source (e.g., a user's telecom unit). Other embodiments may provide emphasis on irradiation dosage values that are monitored or measured at or in close proximity to, a body-related target region (e.g., head, medical appliance, reproductive organs, etc.) Other embodiments may provide current or cumulative irradiation protection information and/or remedial action based on processing EMR radiation and dosage values obtained from diverse sensors and/or monitors and/or data records.

A radiation emission priority table310may include data for multiple user IDs325associated with one or more particular telecommunication device models320. For purposes of illustration, reference is made to a commonly used power density measurement unit for characterizing an electromagnetic field. As used herein, power density measurements per unit area are expressed in terms of microwatts per square centimeter. Such measurements may provide reasonable accuracy when the point of measurement is a sufficient distance away from EMR emitter (e.g., more than several wavelengths distance from a typical EMR source).

As a first example, a cell phone “AA” (see321) for a user identified as “Amy pregnant” (see326) may include a searching331operation mode having a pre-calibrated radiation emissions range cap335with a value or “#qq microwatts/square cm” (see337). Amy may have a user intrusion level345that applies to her individually (see346). In addition, actual radiation values340for Amy may be obtained by detection or monitoring (see342) during the searching331. With respect to a target region350for Amy that includes her torso & reproductive organs (see351), a correlated real-time radiation limit355may be selected or automatically determined (see356), and a correlated cumulative radiation limit360may be selected or automatically determined (see361).

As another example for Amy, a transmit/receive332operation mode may have a pre-calibrated radiation emissions range cap335with a value or “#zz microwatts/square cm” (see338). In addition, actual radiation values340for Amy may be obtained by detection or monitoring (see343) during the transmit/receive333. With respect to a same target region350for Amy that includes her torso & reproductive organs (see351), a same correlated real-time radiation limit355may be selected or automatically determined (see356), and a same correlated cumulative radiation limit360may be selected or automatically determined (see361).

As a second example, a mobile unit “BB” (see323) for a user identified as “Bob age 65” (see328) may include a searching334operation mode having a pre-calibrated radiation emissions range cap335with a value or “#xx microwatts/square cm” (see339). Bob may have a user intrusion level345that applies to him individually (see347). In addition, actual radiation values340for Bob may be obtained by detection or monitoring (see344) during the searching mode334. With respect to a target region350for Bob that includes his heart/lungs (see354), a correlated real-time radiation limit355may be selected or automatically determined (see358), and a correlated cumulative radiation limit360may be selected or automatically determined (see363).

As another example for Bob, a transmit/receive333operation mode may have a pre-calibrated radiation emissions range cap335with a value or “#yy microwatts/square cm” (see338). In addition, actual radiation values340for Bob may be obtained by detection or monitoring (see343) during the transmit/receive mode333. With respect to a target region350for Bob that includes his hearing aid (see353), a correlated real-time radiation limit355may be selected or automatically determined (see357), and a correlated cumulative radiation limit360may be selected or automatically determined (see362).

Further exemplary system embodiments shown inFIG. 4include an irradiation exposure priority table365for various user-related target regions370associated with one or more particular telecommunication devices375. For purposes of illustration, reference is made to an irradiation exposure standard adopted by the FCC (Federal Communications Commission), which standard is based on a specific absorption rate (SAR) measured by the amount of a telecom unit's radiation energy in watts absorbed per kilogram of tissue.

As a first example, an applicable user-related target region370may includes any body surface (see371) of the user. An applicable user telecom device375may include a fixed location mobile unit “CC” with an onboard radiation sensor (see376) having a real-time exposure threshold limit380based on user-choice in a range of SAR 1.6-4.0 watts per kilogram (see381). A related cumulative exposure threshold limit385that is selected or otherwise determined may have a particular dosage exposure value (see386). In a situation wherein one or the other of the predetermined threshold limits381,386is exceeded, an appropriate responsive action390may cause a selective or consequential remedial action such as “modify telecom unit power mode” (see391).

As another example, an applicable user-related target region370may include a heart appliance such as a pacemaker (see372) of the user. An applicable user telecom device375may include a variable location cell phone “DD” with an offboard chest sensor (see377) having a real-time exposure threshold limit380based on the heart appliance device safety specification (see382). A related cumulative exposure threshold limit385that is selected or otherwise determined may have a particular dosage exposure value (see387). In a situation wherein one or the other of the predetermined threshold limits381,386is exceeded, an appropriate responsive action390may cause a selective or consequential remedial action such as “turn off cell phone” (see392).

As an additional example, an applicable user-related target region370may include the head, eyes and/or ears (see373) of the user. An applicable user telecom device375may include a fixed and variable location portable landline phone “EE” (see3778) having a real-time exposure threshold limit380that is selected or otherwise determined to be SAR 1.6 watts per kilogram (see383). A related cumulative exposure threshold limit385that is selected or otherwise determined may have a particular dosage exposure value (see388). In a situation wherein one or the other of the predetermined threshold limits383,388is exceeded, an appropriate responsive action390may cause a selective or consequential remedial action such as “activate warning alarm” (see393).

It will be understood that the specific types of radiation protection information depicted in the exemplary data tables ofFIG. 4are for purposes of illustration and are not intended to be limiting. Additional categories and applicable data values and remedial actions may be provided in accordance with a user's preference or to a third party's decision or a product manufacturer's specification or other entity which may be responsible for administering the various irradiation protection schemes disclosed herein.

It will be understood that the exemplary system embodiments disclosed herein facilitate managing electromagnetic irradiation from a telecommunication device, and may include proximity determination means for acquiring estimated location parameters for a particular telecommunication device relative to a target body region of a user, as well as monitoring means for determining whether the particular telecommunication device is in an active operation mode that generates or is predicted to generate electromagnetic irradiation above a predetermined intrusion level. Additional system components may include control module means configured to be responsive to confirmation of the determined active operation mode in order to implement consequential or selective remedial action with respect to exposure of the target body region to attenuated electromagnetic emissions received from the particular telecommunication device.

Referring to the high level flow chart ofFIG. 5, an exemplary process embodiment500provides a method of managing electromagnetic irradiation from a telecommunication device (block502) that may include acquiring estimated location parameters for a particular telecommunication device relative to a target body region of a user (block503), determining whether the particular telecommunication device is in an active operation mode that generates or is predicted to generate electromagnetic irradiation above a predetermined intrusion level (block504); and responsive to confirmation of the determined active operation mode, implementing consequential or selective remedial action with respect to exposure of the target body region to attenuated electromagnetic emissions received from the particular telecommunication device (block506).

Other possible process components may include obtaining an approximate radiation value for electromagnetic emissions generated from the particular telecommunication device during the active operation mode (block508), and obtaining the approximate radiation value from a calibration table or sensor incorporated with the particular telecommunication device (block509). Additional process aspects may include processing the approximate radiation value in combination with the estimated location parameters to provide a risk assessment arising from such exposure of the target body region (block511). Further related risk assessment aspects may include providing the risk assessment based on a currently generated radiation value for the electromagnetic emissions of the particular telecommunication device (block512), providing the risk assessment based on a cumulative record of electromagnetic emissions of the particular telecommunication device during a given time period (block513), and providing the risk assessment based on user-specified criteria (block514.

Other risk assessment features may include making an accessible data record indicating the risk assessment arising from such exposure of the target body region (block516), providing to the user or to a third party an indication of the risk assessment (block517), and providing to the user a visual or audio or haptic indicator of the risk assessment (block518). Another possible risk assessment feature may include advising one or more current conversation recipients of the risk assessment (block519).

The process embodiment features530illustrated in the detailed flow chart ofFIG. 6may include previously described features503,504,506along with implementing various types of consequential or selective remedial action regarding irradiation risks. For example, such remedial action may include causing the particular telecommunication device to change to a reduced power mode or dormant operation mode (block531), and in some instances may include causing the particular telecommunication device to change to a different operation mode configured to generate radiation emissions at or below the predetermined intrusion level (block532).

Other possible remedial actions may include changing a transmission pattern of the particular telecommunication device for sending and/or receiving messages (block533), providing a time limit for the user and a recipient to finish a conversation (block534), and switching to a different communication relay or cell tower or network carrier or retransmitter or satellite (block536). Some exemplary embodiments may further provide for increasing an audio volume or voice sensitivity of the particular telecommunication device to facilitate greater separation between the particular telecommunication device and a user's head (block537).

FIG. 6also depicts additional exemplary types of remedial action such as causing the particular telecommunication device to operate intermittently or temporarily in the active operation mode that generates radiation emissions above the predetermined intrusion level (block538), as well as causing the particular telecommunication device to change one or more of the following operation parameters to achieve a reduced intrusion level: frequency, polarity, voltage, current, intensity, orientation, emission mode, transmission pattern, audio volume, voice sensitivity (block539).

Referring to the various embodiment features545illustrated inFIG. 7, a possible process implementation may include previously described operations503,504,506as well as implementing consequential or selective remedial action such as increasing an audio volume during listening mode and/or increasing a voice sensitivity during speaking mode, for the particular telecommunication device (block547). Other types of remedial action may include suggesting to a user an orientation change (block548) or suggesting to a user a location change (block549) of the particular telecommunication device, relative to the target body region. A further remedial action aspect may include causing a change in location and/or orientation of the particular telecommunication device (block551).

Some exemplary embodiments may further include obtaining a radiation dosage value associated with electromagnetic emissions received at the target body region (block556), and obtaining the radiation dosage value from a sensor proximate to the target body region (block557). Another possible aspect may include based on the obtained radiation dosage, providing to the user and/or to a third party a risk assessment of irradiation exposure of one or more of the following types of target body-related regions: head, eye, ear, heart, chest, stomach, torso, abdomen, groin, reproductive organ, proximate body surface, vulnerable organ, sensitive body part, cerebral portion, cardio-vascular portion, bionic repair, bionic replacement, implanted medical appliance, therapeutic device, health monitoring apparatus, testing unit, diagnostic component, body accessory (block558).

Various exemplary process embodiment features560disclosed in the flow chart ofFIG. 8may include previously described components503,504,506in combination with communicating an output identifier indicative of currently and/or cumulatively generated radiation emissions above the predetermined intrusion level (block561). A related process aspect may provide to the user the output identifier that includes a recognizable textual and/or visual and/or audio and/or sensory output indicative of currently and/or cumulatively generated radiation emissions above the predetermined intrusion level (block562). A further related possible aspect may include implementing user-selected remedial action to minimize exposure of the target body region to excessive electromagnetic emissions received from the particular telecommunication device (block563).

In some instance an exemplary embodiment may include transmitting to a control module a recognizable output signal indicative of currently and/or cumulatively generated radiation emissions above the predetermined intrusion level (block566), and may further include responsive to said transmitted recognizable output signal, implementing automatic or programmed consequential action by the control module operable to minimize exposure of the target body region to excessive electromagnetic emissions received from the particular telecommunication device (block567).

Referring to the detailed flow chart ofFIG. 9, exemplary process features570may include previously described aspects503,504along with ascertaining a separation distance between the particular telecommunication device and the target body region (block571). A related aspect may include processing an obtained radiation value for electromagnetic emissions generated from the particular telecommunication device in combination with the separation distance between the particular telecommunication device and the target body region to provide a risk assessment arising from such exposure of the target body region (block572).

Another possible process feature may include confirming an orientation factor for separation between the particular telecommunication device and the target body region, which orientation factor is determined relative to a transmission pattern of the particular telecommunication device (block573). A related aspect may include processing an obtained radiation value for electromagnetic emissions generated from the particular telecommunication device in combination with the orientation factor to provide a risk assessment arising from such exposure of the target body region (block574).

Additional possible risk assessment factors may include indicating a first risk assessment if the orientation factor is deemed relatively insignificant due to a uniform transmission pattern of the particular telecommunication device (block576), and indicating a second risk assessment at least partially based on a significant orientation factor due to a non-uniform and/or directional transmission pattern of the particular telecommunication device (block577).

The detailed flow chart ofFIG. 10depicts various exemplary process features580including previously described components503,504,506,571,572in combination with various aspects related to the ascertained distance between the particular telecommunication device and the target body region. For example, some possible aspects may include ascertaining the separation distance by one or more of the following types of proximity measurement techniques: ultrasound, infrared (IR), ultraviolet (UV), radio frequency (RF), radio frequency identification (RFID) tag, capacitive sensor, electromagnetic reflection, phase-change, charge-coupled device (CCD) light detection, thermal sensor, image recognition, audio time of flight (block583).

Additional exemplary embodiments may include ascertaining the separation distance between an omni-directional or internal antenna of the particular telecommunication device and the target body region (block581). A further possible embodiment feature may include ascertaining the separation distance between a directional or external antenna of the particular telecommunication device and the target body region (block582).

The exemplary process embodiment features590ofFIG. 11include previously described operations503,504,506along with establishing location parameters for an identifiable receptacle holding the particular telecommunication device proximate to the target body region (block591). Related possible process features may include establishing location parameters for the identifiable receptacle attached directly or indirectly to a known bodily location of the user (block592), and establishing location parameters for the identifiable receptacle attached or supported or held at a known location in a vehicle of the user (block593). Additional possible aspects may include establishing location parameters for the identifiable receptacle attached or supported or held at a known location in a workspace or bailiwick of the user (block594).

Some exemplary embodiment may include establishing location parameters for an identifiable clothing section or apparel accessory attaching or supporting or holding the particular telecommunication device proximate to the target body region (block596). Other possible features may include establishing location parameters for the particular telecommunication device attached or supported or held at a known location relative to the user (block597. Further possible enhancements may include establishing location coordinates for the particular telecommunication device relative to a medical or health related body accessory device subject to irradiation exposure (block598).

Referring to the detailed flow chart ofFIG. 12, variously illustrated embodiment features600include previously described process aspects503,504,506in combination with establishing location parameters for one or more of the following types of telecommunication device: mobile, hand-held, vehicle-mounted, desktop, head-attached, wrist-attached, hands-free, cell phone, transceiver, transmitter, receiver (block602). Other possible process aspects may include implementing the remedial action to minimize exposure of one or more of the following types of target body-related regions to excessive electromagnetic emissions: head, eye, ear, heart, chest, stomach, torso, abdomen, groin, reproductive organ, proximate body surface, vulnerable organ, sensitive body part, cerebral portion, cardio-vascular portion, bionic repair, bionic replacement, implanted medical appliance, therapeutic device, health monitoring apparatus, testing unit, diagnostic component, body accessory (block603).

Additional possible process features depicted inFIG. 12may include providing one or more different predetermined intrusion levels respectively applicable to various types of implanted or attached or user-related body accessory devices to be protected from excessive electromagnetic emissions (block604). Other exemplary embodiment features may include providing one or more different predetermined intrusion levels respectively applicable to various types of target body regions to be protected from excessive electromagnetic emissions (block606), and providing one or more different predetermined intrusion levels respectively applicable to various types or categories of users to be protected from excessive electromagnetic emissions (block607).

FIG. 13is a diagrammatic flow chart for an exemplary computer program product620that provides computer readable media having encoded instructions for executing a method (block621), wherein the method may include acquiring estimated location parameters for a particular telecommunication device relative to a target body region of a user (block622); determining whether the particular telecommunication device is in an active operation mode that generates or is predicted to generate electromagnetic irradiation above a predetermined intrusion level (block623); and responsive to confirmation of the determined active operation mode, implementing remedial action to minimize the electromagnetic irradiation of the target body region (block624).

Further possible method features to minimize electromagnetic irradiation may include implementing automatic or programmed consequential remedial action with respect to exposure of the target body region to attenuated electromagnetic emissions received from the particular telecommunication device (block626), and implementing user-selective remedial action with respect to exposure of the target body region to attenuated electromagnetic emissions received from the particular telecommunication device (block628).

Other exemplary aspects may include communicating an output identifier indicative of currently and/or cumulatively generated radiation emissions above the predetermined intrusion level (block627). Further possible process features may include establishing the predetermined intrusion level based on a type of target body region to be protected from excessive electromagnetic emissions (block631). In some instances an exemplary process feature may include establishing the predetermined intrusion level based on a type of implanted or attached or user-related body accessory device to be protected from excessive electromagnetic emissions (block632). A further possible aspect may include establishing the predetermined intrusion level based on a type or category of user to be protected from excessive electromagnetic emissions (block633).

Referring to the schematic block diagram ofFIG. 14, an exemplary system embodiment for irradiation protection may include communication unit650having processor652, memory654, one or more program applications656, and controller658. The communication unit650may be a separate unit or may be incorporated as part of a user's telecom device that generates EMR. Various types of user interfaces may be incorporated in or operably coupled with the communication unit650including but not limited to keyboard671, mouse672, touch screen673, voice receiver674, data/status display676, messaging display677, GPS device678, and speaker779to facilitate interactive communications by one or more users associated with the communication module650.

Various types of updated informational data may be maintained to be accessible to the communication unit650including telecom unit(s) identifier data680, target region identifier data690, and remedial action lookup table700. Exemplary telecom unit identifier data680may include fixed location coordinates682, variable location coordinates683, calibrated radiation684, orientation axis686, and transmission pattern(s)687. Exemplary target region identifier data690may include a body organ691, body section692, body-related device693, and one or more radio frequency identification (RFID) tags694. The exemplary remedial action lookup table may include current exposure level702, cumulative exposure level703, first user ID706, and second user ID707.

An integral or remote detection module695may be operably connected with the target region identifier module690and with the telecom location module680to enable determination of a separation distance between a particular telecommunication unit and a target body region.

Some exemplary embodiment features may provide a transmission link between the communication unit650and as least one radiation detection sensor (see740) adapted to detect attenuated radiation emissions generated from a telecom unit. Other exemplary embodiment features may provide a transmission link between the communication unit650and at least one exposure monitoring device (see740) adapted to monitor irradiation exposure of a targeted body region.

As illustrated inFIG. 14, the communication unit650in some system embodiments may be operably connected with a risk assessment data matrix for target regions710wherein some types of bodily-related target regions are deemed to be more vulnerable to electromagnetic irradiation than others. For example, hands and feet may be designated as “nil” risk712; arms and legs may be designated as “low” risk713; and torso and chest may be designated as “medium” risk714. In contrast, sections of the head (e.g., eye, ear, brain) may be designated as “high” risk716; and reproductive organs may be designated as “high” risk717. As a further example, a target body region that includes an implanted medical device may be designated as “high” risk718.

The communication unit650in other system embodiments may be operably connected with a risk assessment data matrix for user types720wherein some types or categories of people are deemed to be more vulnerable to electromagnetic irradiation than others. For example, different levels of risk assessment may be assigned to a person classified as a hospital patient721, or a person with a particular health status722(e.g., temporary illness or chronic disease723). As a further example, different levels of risk assessment may be assigned based on one or more age groups726or a person's gender727.

In some situations a different level of risk assessment may be assigned to a person living or working in a place subject to multiple EMR radiation sources731. Whether the radiation generating device is either mobile or fixed732may be a factor in determining an EMR risk assessment. A person in a category of “frequent telecom usage”733may be assessed at a higher risk for excessive irradiation exposure than a person in a category of “seldom/moderate telecom usage”734.

Depending on the circumstances, the various system components including communication unit650, telecom unit identifier data680, target region identifier data690, proximity detection device695, remedial action lookup table700, risk assessment data matrices710,720and radiation detection sensors & exposure monitoring devices740may be incorporated as part of a user's telecommunication device and/or located externally (e.g., remotely) from such telecommunication device. In some instances certain components may be located at a facility associated with providing irradiation protection services, and/or located in a vehicle or residence or building or workplace of the user. Other locations are possible, and various types of communication links may be provided including but not limited to wireless, cable, satellite, Internet, public networks, private networks, and the like.

It will be further understood from the various embodiment features disclosed herein that certain exemplary data processing functions may be provided by a unitary communication unit650, and other specified exemplary processing functions may be carried out by separate computerized processing modules.

It will also be understood that the exemplary system embodiments disclosed herein for facilitating irradiation protection for a specified target body region may include data record means (e.g., priority tables310,365, identifier data690, risk assessment data matrix710) for identifying the specified target body region of a user that is proximate to a particular communication device capable of generating electromagnetic emissions that subject the specified target body region to irradiation exposure; monitoring and/or detection means (e.g., radiation monitors and/or sensors260, sensors and/or devices740) for establishing whether such irradiation exposure does exceed or is predicted to exceed a safety threshold correlated with the specified target body region; and control circuit means (e.g., EMR control module250, communication unit650) that is activated based on such established irradiation exposure having a dosage value above the safety threshold, wherein such control circuit means is configured to provide a responsive output based on a possible risk relative to such irradiation exposure.

The high level flow chart ofFIG. 15depicts exemplary embodiment features800regarding a method of facilitating irradiation protection for a specified target body region (block801), wherein the method may include identifying the specified target body region of a user that is proximate to a particular communication device capable of generating electromagnetic emissions that subject the specified target body region to irradiation exposure (block802); establishing whether such irradiation exposure does exceed or is predicted to exceed a safety threshold correlated with the specified target body region (block803); and if such irradiation exposure has a dosage value above the safety threshold, providing a responsive output based on a possible risk relative to such irradiation exposure (block804). Another possible feature may include enabling a user to choose the safety threshold correlated with the specified target body region (block806).

Additional possible process features may include establishing an automatic or programmed safety threshold that is correlated with the specified target body region (block807), and enabling a user to choose the specified target body region correlated with the safety threshold (block808). In some instance exemplary embodiment features may include sending the responsive output to a base station or cell tower or service provider or network node or other off-device destination (block811). Other possible features may include sending the responsive output to a third party for monitoring, and/or record keeping, and/or decision making regarding possible remedial action (block812).

Also depicted inFIG. 15are exemplary aspects that include sending the responsive output to one or more of the following types of third party: parent, family member, friend, insurance entity, physician, nurse, health care entity (block813). Further possible aspects may include sending the responsive output to the particular communication device, wherein the particular device suggests to the user a time limit for a call and/or a change in body location relative to the particular communication device and/or a change in orientation of the particular communication device (block814).

Referring to the flow chart ofFIG. 16, various exemplary embodiment features820are depicted including previous described aspects802,803,804along with sending the responsive output to a recipient entity and/or other destination for a message or transmission from the particular communication device (block816). Additional exemplary features may include sending the responsive output to an accessible record that maintains current and/or cumulative irradiation exposure data (block821). Other possible process aspects may include sending the responsive output to the user, wherein the responsive output includes a recognizable textual and/or visual and/or audio and/or sensory output indicative of a current and/or cumulative dosage value that exceeds the safety threshold (block822).

Additional exemplary aspects may include implementing user-selected remedial action to reduce irradiation exposure to a dosage value at or below the safety threshold (block824), and in some instances may provide for implementing user-selected remedial action to minimize exposure of the specified target body region to excessive irradiation (block823). Other process aspects may include causing the particular communication device to implement one or more of the following: reduced power mode, dormant operation mode, intermittent active mode, temporary alternate mode, power off mode, conversation time limit, different cell tower, optional network carrier, alternate relay/retransmitter, new satellite link, different transmission destination (block826). Further exemplary features may include causing the particular communication device to change one or more of the following operation parameters to achieve a reduced level of irradiation exposure: frequency, polarity, voltage, current, intensity, orientation, emission mode, transmission pattern, audio volume, voice sensitivity (block827).

Various exemplary process features830are illustrated in the flow chart ofFIG. 17including previous described features802,803,804in combination with transmitting the responsive output to a local or remote control module, wherein the responsive output includes a recognizable output signal indicative of a current and/or cumulative dosage value that exceeds the safety threshold (block832). Additional aspects may include implementing automatic or programmed remedial action to reduce the irradiation exposure to a dosage value at or below the safety threshold (block834). A further possibility may provide for implementing automatic or programmed remedial action to minimize exposure of the specified target body portion to excessive irradiation (block833).

Some embodiments may include causing the particular communication device to implement one or more of the following: reduced power mode, dormant operation mode, intermittent active mode, temporary alternate mode, power off mode, conversation time limit, different cell tower, optional network carrier, alternate relay/retransmitter, new satellite link, different transmission destination (block836). Other embodiments may include causing the particular communication device to change one or more of the following operation parameters to achieve a reduced level of irradiation exposure: frequency, polarity, voltage, current, intensity, orientation, emission mode, transmission pattern, pulse format, control channel, voice channel, audio volume, voice sensitivity (block837).

The flow chart ofFIG. 18depicts various exemplary features840including previously described features802,803,804along with making an accessible record indicating a risk assessment arising from such irradiation exposure that exceeds the safety threshold (block841). Related possibilities may include making the accessible record that includes the risk assessment arising from current irradiation exposure of the specified target body region, and/or cumulative irradiation exposure of the specified target body region during a given period of time (block842). Further aspects may include establishing whether such irradiation exposure has a dosage value greater than a real-time safety threshold (block843), and in some instance may further include establishing whether such irradiation exposure has a dosage value greater than a cumulative safety threshold for a given period of time (block844).

Additional exemplary aspects may include comparing a transmission pattern of the particular communication device relative to a separation orientation between the particular communication device and the specified target region (block846). Related possible aspects may include determining whether a directional and/or non-uniform transmission pattern causes an increased or decreased irradiation exposure relative to the separation orientation between the particular communication device and the specified target region (block848).

Referring to the exemplary process features850shown in the flow chart ofFIG. 19, some embodiments may include previously describe aspects802,803,804in combination with ascertaining an approximate distance between the particular communication device and the specified target body region (block851). Related process features may include ascertaining the approximate distance by one or more of the following types of proximity measurement techniques: ultrasound, infrared (IR), ultraviolet (UV), radio frequency (RF), radio frequency identification (RFID) tag, capacitive sensor, electromagnetic reflection, phase-change, charge-coupled device (CCD) light detection, thermal sensor, image recognition, audio time of flight (block852).

Further related process aspects may include processing the approximate distance in combination with a calibrated or detected radiation value of the generated electromagnetic emissions to provide a risk assessment for the specified target body region (block853). Some embodiments may include confirming an estimated distance between an antenna of the particular communication device and the specified target body region (block854).

In some instances an exemplary embodiment may include confirming location parameters for an identifiable receptacle holding or supporting or attaching the particular communication device at one or more of the following user-related sites: vehicle, workspace, bailiwick, clothing section, apparel accessory, bodily part (block856). Further exemplary features may include processing the location parameters for the identifiable receptacle in combination with a calibrated or detected radiation value of the generated electromagnetic emissions to provide a risk assessment for the specified target body region (block858).

Referring to the flow chart ofFIG. 20, possible process features860may include previously described aspects802,803,804,851as well as determining a current and/or cumulative irradiation dosage value at least partially based on an approximate ascertained distance between the particular communication device and the specified target body region (block866). In some instances exemplary process features may include determining a current and/or cumulative irradiation dosage value at least partially based on an approximate ascertained distance between an antenna for the particular communication device and the specified target body region (block867).

Further possible aspects regarding appropriate irradiation exposure dosage values may include measuring a current irradiation dosage value with a sensor located at or near the specified target body region (block861). Other possible process features may include determining a current and/or cumulative irradiation dosage value based on data from a sensor proximate to the particular communication device or proximate to the specified target body region (block862).

Some embodiments may include determining a current and/or cumulative irradiation dosage value at least partially based on calibrated or detected radiation emissions associated with the particular communication device (block863). Other possible embodiment features may include determining a current and/or cumulative irradiation dosage value at least partially based on variable or fixed location coordinates for the particular communication device (block864). Further related process features (seeFIG. 21) may include determining a current and/or cumulative irradiation dosage value at least partially based on an approximate orientation of a transmission pattern of the particular communication device relative to the specified target body region (block869).

The flow chart ofFIG. 21illustrates additional possible process features870including previously described aspects802,803,804in combination with implementing a type of remedial action accordance with a priority scheme (block871). Various exemplary priority schemes may be implemented in software and/or circuitry configurations. For example, an exemplary priority scheme may be configured to be implementing a type of remedial action in accordance with a priority scheme configured to be at least partially dependent upon a type of specified target body region (block872). A related aspect may include implementing the type of remedial action in accordance with the priority scheme configured to be at least partially dependent upon the type of specified target body region that includes a medical related or health related body accessory device (block873).

Additional embodiment features may include implementing a type of remedial action in accordance with a priority scheme configured to be at least partially dependent upon a cumulative irradiation exposure of the target body region during a given period of time (block874). In some instances a type of remedial action may be implemented in accordance with a priority scheme configured to be at least partially dependent upon how much a currently determined irradiation dosage value and/or a cumulatively determined irradiation dosage value exceeds the safety threshold correlated with the specified target body region (block876).

Other possible process aspects may include implementing a type of remedial action accordance with a priority scheme configured to be at least partially dependent upon a type of person having the specified target body region (block878). For example, an exemplary embodiment may include implementing the type of remedial action respectively dependent upon one or more of the following types of person having the specified target body region: baby, child, teenager, adult, pregnant woman, hospital patient, senior citizen, organ transplant patient (block879).

Further exemplary aspects880are illustrated inFIG. 22, including previously described aspects802,803,804as well as processing known location coordinates for the particular communication device in combination with a calibrated or detected radiation value of the generated electromagnetic emissions to provide a risk assessment for the specified target body region that includes an implanted or attached or user-related body accessory device (block882). In some instances, exemplary aspects may include confirming fixed or variable location coordinates for one or more of the following types of particular communication device: mobile, hand-held, vehicle-mounted, desktop, head-attached, wrist-attached, hands-free, cell phone, transceiver, transmitter, receiver (block884).

Exemplary computer program product features885depicted inFIG. 23may include providing computer-readable media having encoded instructions for executing a method of facilitating irradiation protection for a specified target body region (block886), wherein a possible method may include identifying the specified target body region that is proximate to a particular communication device capable of generating electromagnetic emissions that subject the specified target body region to radiation exposure (block887), and establishing whether such radiation exposure does exceed or is predicted to exceed a safety threshold correlated with the specified target body region (block888). Some exemplary embodiments may further include if such radiation exposure has a dosage value above the safety threshold, providing a responsive output based on a possible risk relative to such radiation exposure (block889).

Other exemplary programmed process features regarding remedial action may include causing the particular communication device to implement one or more of the following: reduced power mode, dormant operation mode, intermittent active mode, temporary alternate mode, power off mode, conversation time limit, different cell tower, optional network carrier, alternate relay/retransmitter, new satellite link, different transmission destination (block891). Further possible programmed process features regarding remedial action may include causing the particular communication device to change one or more of the following operation parameters to achieve a reduced level of radiation: frequency, polarity, voltage, current, intensity, orientation, emission mode, transmission pattern, audio volume, voice sensitivity (block892).

Some embodiments may include programmed process features that include confirming location parameters for an identifiable receptacle holding or supporting or attaching the particular communication device at one or more of the following user-related sites: vehicle, workspace, bailiwick, clothing section, apparel accessory, bodily part (block894). Additional possible programmed process features may include measuring a current irradiation dosage value with a sensor located at or near the specified target body region (block896). Other exemplary programmed process aspects may include determining a current and/or cumulative irradiation dosage value at least partially based on an approximate orientation of a transmission pattern of the particular communication device relative to the specified target body region (block897).

It will be understood by those skilled in the art that the various components and elements disclosed in the system and schematic diagrams herein as well as the various steps and sub-steps disclosed in the flow charts herein may be incorporated together in different claimed combinations in order to enhance possible benefits and advantages.

The exemplary system, apparatus, and computer program product embodiments disclosed herein includingFIGS. 1-4,FIGS. 13-14andFIG. 23along with other components, devices, know-how, skill and techniques known in the art have the capability of implementing and practicing the methods and processes that are depicted inFIGS. 5-12and15-22. However it is to be further understood by those skilled in the art that other systems, apparatus and technology may be used to implement and practice such methods and processes.

Exemplary methods, systems and components disclosed herein enable detection and/or monitoring and/or control of electromagnetic radiation (EMR) exposure of target body-related portions of a user operating a telecommunication device. It is understood that some embodiments may include a risk-assessment output that is provided based on a safety threshold or predetermined intrusion level of EMR exposure.