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Integration of Wireless Sensor Networks to the Internet of Things using a 6LoWPAN Gateway Integration of Wireless Sensor Networks to the Internet of Things.

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Presentation on theme: "Integration of Wireless Sensor Networks to the Internet of Things using a 6LoWPAN Gateway Integration of Wireless Sensor Networks to the Internet of Things."— Presentation transcript:

1 Integration of Wireless Sensor Networks to the Internet of Things using a 6LoWPAN Gateway Integration of Wireless Sensor Networks to the Internet of Things using a 6LoWPAN Gateway L.F. Schickte, C. Montez, R.de Oliveria and A.R. Pintoe Third Brazilian Symposium on Computing Systems Engineering December 2013 Presenter - Bob Kinicki Presenter - Bob Kinicki Internet of Things Internet of Things Fall 2015

2 Internet of Things 6LoWPAN Gateway 2 OutlineOutline  Introduction {similar to Culler slides}  6LoWPAN details {only top level}  Gateway Prototype  Experiments and Analysis  Conclusions and Critique

3 Internet of Things 6LoWPAN Gateway IntroductionIntroduction  This paper does actual experiments and NOT Cooja simulations.  Motivation for investigating 6LoWPAN with IEEE802.15.4 is these sensor nodes can be integrated with any IP network or the Internet.  Most of the results are essentially straightforward and provide little new insight. 3

4 Internet of Things 6LoWPAN Gateway IPv6 and 6LoWPAN Details  6LoWPAN must support IPv6 minimum MTU of 1280 bytes.  IEEE802.15.4 maximum frame size of 127 bytes  fragmentation.  IPv6 uses 128 bits. IEEE802.15.4 uses 64 bits (full) or 16 bits (short) address. 4

5 Internet of Things 6LoWPAN Gateway 6LoWPAN Adaptation Layer  Mechanisms included: –40 byte IP header compressed up to 2 bytes –Header compression of higher layers (TCP, UDP and ICMP) –IPv6 datagram fragmentation –Header and other information to optimize IEEE802.15.4 mesh and star topologies. 5

6 Internet of Things 6LoWPAN Gateway  LOWPAN_HC1 and LOWPAN_HC2 from RFC4944 replaced by LOWPAN_IPHC and LOWPAN_NHC from RFC6282.  These fields part of the modification in RFC6282. 6 Figure 1: IPv6 Header and 6LoWPAN Compression

7 Internet of Things 6LoWPAN Gateway 6LoWPAN Dispatch Byte 6LoWPAN Dispatch Byte  Identifies compression type in the IEEE802.15.4 frame: 7

8 Internet of Things 6LoWPAN Gateway Table I 8

9 Internet of Things 6LoWPAN Gateway Prototype Development  Authors implement prototype with IEEE802.15.4 nodes and a 6LoWPAN gateway that uses an Ethernet interface to connect the nodes to the Internet.  Atmel AVR-Atmega128RFA1 with 8-bit RISC microprocessor and 2.4GHz transceiver is base for 802.15.4 radio module (includes Contiki open source OS). 9

10 Internet of Things 6LoWPAN Gateway Gateway Prototype Gateway developed by connecting one IEEE802.15.4 node to an Ethernet enabled device. 10

11 Internet of Things 6LoWPAN Gateway Prototype Details  Contiki code was optimized for low-power devices which can use wireless TCP/IP. –Note: This implies using Contiki MAC layer (either Contiki-MAC or X-MAC).  TCP/IP Contiki stack uses µIP layer validated by Cisco.  WirelessHART and Zigbee are proprietary which hinders interoperability and connectivity to devices on Ethernet. 11

12 Internet of Things 6LoWPAN Gateway Prototype Details  WPAN device based on Border Router source code in Contiki.  Gateway needs to be powered to enable handling Ethernet interface and requirement for more RAM flash memory. 12

13 Internet of Things 6LoWPAN Gateway Experiments and Analysis  Authors focus on comparing pure IPv6 versus 6LoWPAN performance only with respect to compression and fragmentation.  First results involve UDP client/server with nodes 3 feet apart.  Client sends another UDP packet after it received response. Timeouts considered an error.  UDP packet size varied from 20 bytes to 520 bytes. 13

14 Internet of Things 6LoWPAN Gateway Experiments and Analysis  Graphs show measurements at multiple layers of µIP stack.  Results include fragmentation. Hence, compression effect is less as compression happens in only first fragment. 14 without

15 Internet of Things 6LoWPAN Gateway Figure 5: Gateway Transfer Rate 15 Details NOT sufficient to reproduce or analyze. How many sensors?

16 Internet of Things 6LoWPAN Gateway Figure 6: Compression Impact 16  Headers dominate small packets  compression gain higher for small packets!  Overhead reduced for larger packets.  Large page experiments impacted by available RAM. Very small web page  best results

17 Internet of Things 6LoWPAN Gateway Conclusions and Critique  Paper presents implementation of prototype with 6LoWPAN gateway.  Results show that compression can improve response time and data rate.  Not much here!!  Details missing in some cases. 17

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