Abstract
In this paper, we describe a LoRa (from “Long Range”)-based, linear sensor network we have developed for transmitting location information of personnel and equipment in an underground mine. The system is intended to be used during emergencies when existing communications infrastructure has failed. Linear networks comprise a sequence of relays that forward data to a common destination, the headend. Relays forward location information transmitted from tags carried by personnel or equipment. Relays will usually be put in place as investigators or rescuers enter the mine. LoRa is used both by the tags to communicate to the relays and by the relays to forward messages to the headend. We have implemented and tested this system, and have carried out simulations and analyses to determine its scalability, reliability and fairness. The need for robustness and reliability has led us to use flooding rather than unicast communication. We also use message sequence numbers and time-to-live fields to prevent broadcast storms. Contention is managed using a simplified Carrier Sense Multiple Access (CSMA) scheme. We also address fairness. When the network is under load messages may be dropped by relays making messages generated more hops from the headend more likely to be dropped than messages nearer the headend. We explore the relationship between unfairness, traffic load and number of relays. We also observe that a network of larger numbers of lightly loaded relays performs more effectively than smaller numbers of heavily loaded relays.
Highlights
This paper describes our work in designing, implementing and analysing an emergency network for transmitting location data within an underground mine
Rescuers or repairers place wireless relays as they advance into the mine
Personnel and equipment carry tags that generate location information which is transmitted via the relays to a headend connected to surviving infrastructure
Summary
This paper describes our work in designing, implementing and analysing an emergency network for transmitting location data within an underground mine. We consider the situation where existing mining communications infrastructure, typically wireless communications based on IEEE 802.11 with optic fiber backhaul, is severely damaged and temporary communications infrastructure must be installed rapidly while the main infrastructure is repaired. This temporary infrastructure’s primary purpose is to support the transmission of low bit-rate location data of people and equipment carrying out repairs or rescue and act as a backhaul. Rescuers or repairers place wireless relays as they advance into the mine. This sequence of wireless relays will form a linear network. Personnel and equipment carry tags that generate location information which is transmitted via the relays to a headend connected to surviving infrastructure
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