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Embodiments of methods, devices and systems are presented for communicating information in an explosive environment. An explosion proof video and data communication module includes features that prevent the generation of a spark or other ignition sources that could ignite explosive dust, gas or vapo

Embodiments of methods, devices and systems are presented for communicating information in an explosive environment. An explosion proof video and data communication module includes features that prevent the generation of a spark or other ignition sources that could ignite explosive dust, gas or vapors in the air. The explosion proof video and communications relay modules may operate independently or as a group to provide real-time information, situation awareness, functionally and responsiveness for personnel that are in explosive environments.

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1. An explosion-proof communication device, comprising: a non-conductive housing;a first antenna;a second antenna;a radio receiver;a radio transmitter;a battery coupled to a fault tolerant circuit element; anda processor coupled to the first antenna, second antenna, radio receiver, radio transmitter

1. An explosion-proof communication device, comprising: a non-conductive housing;a first antenna;a second antenna;a radio receiver;a radio transmitter;a battery coupled to a fault tolerant circuit element; anda processor coupled to the first antenna, second antenna, radio receiver, radio transmitter, and battery, wherein the processor is configured with processor executable software instructions to perform operations comprising: receiving radio frequency signals from the first antenna at a first frequency via the radio receiver; andretransmitting the received frequency signals from the second antenna at a second frequency via the radio transmitter, wherein the first frequency is different from the second frequency, andwherein the processor, first antenna, second antenna, radio receiver, radio transmitter, battery, and fault tolerant circuit element are hermetically sealed inside the non-conductive housing. 2. The explosion-proof communication device of claim 1, wherein the battery is a rechargeable battery, the explosion-proof communication device further comprising: a rectifier coupled to the rechargeable battery; andan induction coil coupled to the rectifier, wherein the induction coil and rectifier are configured to generate a voltage operable to charge the rechargeable battery when an alternating magnetic field is applied to the induction coil. 3. The explosion-proof communication device of claim 2, further comprising a transistor coupled between the rectifier and the rechargeable battery with a control lead coupled to the processor, wherein the processor is configured with processor-executable software instructions to perform operations further comprising regulating the charging of the rechargeable battery when the voltage is generated by the induction coil and rectifier. 4. The explosion-proof communication device of claim 1, wherein the radio receiver and radio transmitter comprises a signal generator configured to generate a radio frequency signal having a third frequency. 5. The explosion-proof communication device of claim 4, wherein the processor is configured with processor-executable software instructions to perform operations further comprising adjusting the frequency of the radio frequency signal generated by the signal generator. 6. The explosion-proof communication device of claim 1, wherein the processor is configured with processor-executable software instructions to perform operations further comprising controlling an output power of the radio receiver and radio transmitter to maintain the output power at a minimum level consistent with a minimum quality of a service metric and below a maximum output power level. 7. The explosion-proof communication device of claim 1, wherein the processor is configured with processor-executable software instructions to perform operations further comprising grouping the explosion-proof communication device with a wireless transceiver in proximity to the explosion-proof communication device to form a communication group, wherein receiving radio frequency signals from the first antenna at a first frequency comprises receiving radio frequency signals from the wireless transceiver in the communication group. 8. The explosion-proof communication device of claim 1, further comprising a fastener attached to the non-conductive housing and configured to secure the explosion-proof communication device to a helmet. 9. The explosion-proof communication device of claim 8, wherein the fastener includes a strap. 10. The explosion-proof communication device of claim 8, wherein the fastener includes a fabric hook-and-loop fastening element. 11. The explosion-proof communication device of claim 1, further comprising a selector switch coupled to the non-conductive housing and arranged so that it may be actuated by a human user wearing gloves to cause the processor to perform one or more operations. 12. The explosion-proof communication device of claim 1, further comprising: a camera coupled to the processor; anda lens cover arranged to seal and isolate the camera from an exterior atmosphere. 13. The explosion-proof communication device of claim 12, further comprising an illumination source mounted behind a camera lens of the camera and arranged so that an illumination capability of the illumination source is not impeded. 14. The explosion-proof communication device of claim 12, wherein the processor is configured with processor-executable software instructions to perform operations further comprising: receiving instructions from a second explosion-proof communication relay device; andadjusting a resolution of video information collected by the camera based on the received instructions. 15. The explosion-proof communication device of claim 1, further comprising a sensor hermetically sealed inside the non-conductive housing and configured to monitor environmental conditions outside the non-conductive housing. 16. The explosion-proof communication device of claim 1, further comprising an audio circuit hermetically sealed inside the non-conductive housing and configured to be coupled to a microphone and a speaker outside of the non-conductive housing from within the hermetically sealed non-conductive housing. 17. A communication system for use in an explosive environment, comprising: a first explosion-proof communication relay device and a second explosion-proof communication relay device, wherein each of the first and second explosion-proof communication relay devices comprise: a non-conductive housing;a first antenna;a second antenna;a radio receiver;a radio transmitter;a battery coupled to a fault tolerant circuit element; anda processor coupled to the first antenna, second antenna, radio receiver, radio transmitter, and battery, wherein the processor is configured with processor executable software instructions to perform operations comprising: receiving radio frequency signals from the first antenna at a first frequency; andretransmitting the received frequency signals from the second antenna at a second frequency, wherein the first frequency is different from the second frequency,wherein the processor, first antenna, second antenna, radio receiver, radio transmitter, battery, and fault tolerant circuit element are hermetically sealed inside the non-conductive housing, andwherein the processor of the first explosion-proof communication relay device is configured with processor executable software instructions to perform operations further comprising establishing a communication link with the second explosion-proof communication relay device. 18. The communication system of claim 17, wherein the first explosion-proof communication relay device further comprises: a camera coupled to the processor of the first explosion-proof communication relay device; anda lens cover arranged to seal and isolate the camera from an exterior atmosphere, andwherein the processor of the first explosion-proof communication relay device is configured with processor-executable software instructions to perform operations further comprising: receiving instructions from the second explosion-proof communication relay device; andadjusting a resolution of video information collected by the camera based on the received instructions.