03296nas a2200421   4500000000100000000000100001008004100002260000800043653003400051653001500085653002100100653002100121653003700142653002000179653003100199653002800230653002800258653003200286653001700318653002200335653002100357653003800378653002700416653002600443653002900469653002700498100001300525700001700538700001800555700001500573700001600588700002000604245013700624856014700761490000900908520193700917022002002854       2021                            d  cjul10aIntangible cultural heritages10aMonitoring10aTourism industry10aQuery processing10aResponse time (computer systems)10aSoftware design10aCommunication capabilities10aCommunication interface10aData exchange protocols10aElectronic data interchange10aGraph theory10aHypertext systems10aLeisure industry10aMonitoring and management systems10aMultisensor technology10aReal-time information10aShortest path algorithms10aStructured programming1 aEnhou Zu1 aMingHung Shu1 aJuiChan Huang1 aTzuJung Wu1 aChihWei Hsu1 aYuanChieh Chang00aDevelopment of a Monitoring and Management System for Nonheritage Tourist Attractions Based on Mobile GIS and Multisensor Technology  uhttps://www.scopus.com/inward/record.uri?eid=2-s2.0-85112049326&doi=10.1155%2f2021%2f9130244&partnerID=40&md5=448a671db2e6d885c1137f1d73bc93910 v20213 aWith the rapid development of the tourism industry, how to monitor scenic spots and tourists in real time has become an issue. This paper mainly describes the development of a monitoring and management system for scenic spots of intangible cultural heritage based on Mobile GIS and multisensor technology. The monitoring system adopts the idea of structured programming, which reduces the coupling degree of various components and promotes the expansion of system functions. The shortest path module uses the scenic spot management subsystem on the PC. The scenic spot manager enters the distance between adjacent scenic spots that can be directly reached into the system database and then uses the shortest path algorithm, Dijkstra algorithm, to calculate. Asynchronous Socket programming mechanisms are used to implement communication capabilities, the XML markup language is selected as the system s data exchange protocol, and the DHT11 digital temperature and humidity sensor is used to obtain humidity information around ancient buildings. A Mobile GIS reader of an ancient building in a scenic spot sends a request to connect to a server. The listener is the communication interface between the server software and the reader. It is responsible for parsing the transmitted data and storing it in the database. The CC2430 chip is used to wear on tourists. When tourist nodes and guide nodes enter the scenic spot, they join the network to query the density of the entire scenic spot and upload real-time information. In terminal query, the average response time of real-time location query is 2S. The average initial response time for historical location queries is about 3S. The results show that the visualization services provided by software development can intuitively and accurately display the flow and density of scenic spots, providing a scientific reference for carrying capacity and flow management of scenic spots.  a1574017X (ISSN)