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Table of Contents
Intro
Contents
1 Introduction
1.1 Overview of the Cordless Kitchen Concept
1.1.1 Benefits of Cordless Kitchen
1.1.2 Use-Cases
1.1.3 System Architecture
1.1.4 How Does it Work?
1.1.5 Internet Connectivity in the Cordless Kitchen
1.2 Challenges and Solutions
1.3 Takeaways
References
2 Ki-The Cordless Kitchen
2.1 Components of Cordless Kitchen
2.1.1 Power Transmitter
2.1.2 Cordless Appliance
2.1.3 NFC Communication Interface
2.2 System Parameters
2.3 Foreign Object Detection
2.4 Phases of Operation
2.4.1 Idle Phase
2.4.2 Configuration Phase
2.4.3 Connected Phase
2.4.4 Power Transfer Phase
2.5 NFC Protocol Extensions for the Cordless Kitchen
2.5.1 Dedicated Application States
2.5.2 Dedicated NFC Commands
References
3 Architectures for Internet Connectivity
3.1 Proxy Architecture
3.2 Bridge Architecture
3.3 Comparison of Transmission Latency
Reference
4 State of the Art
4.1 Tunneling Standard TCP/IP Protocol over NFC
4.2 6LoWPAN Adaptation for TCP/IP Protocol over NFC
4.3 TCP/IP Adaptation Mechanisms for High Delay Networks
References
5 Adapting TCP for the Bridge Architecture
5.1 Experimental Setup
5.2 Challenges in Adapting TCP
5.2.1 TCP Spurious Retransmissions
5.2.2 Packet Drops Due to Small Inter-Packet Delay
5.3 Addressing the Challenges
5.3.1 Avoiding Packet Drops Due to Small Inter-Packet Delay
5.3.2 Avoiding TCP Spurious Retransmissions
References
6 Evaluation of the Bridge Architecture
6.1 Implementation Recommendations
6.2 Results
6.2.1 Packet Retransmissions
6.2.2 Latency
6.2.3 Throughput and Goodput
6.2.4 Bandwidth Utilization
References
7 Parametric Analysis of the Bridge Architecture
7.1 Effect of TCP CWND Size and Slow Start Process on the System Latency
7.2 Effect of TCP MSS Size on the System Latency
7.3 Effect of NFC BER on the System Latency
7.3.1 Random Errors
7.3.2 Burst Errors
7.4 Effect of Varying the NFC Communication Time-Slot Duration on the System Latency
7.5 Considering Non-TCP/IP Messages over the NFC Channel
References
8 Conclusion
Reference
Contents
1 Introduction
1.1 Overview of the Cordless Kitchen Concept
1.1.1 Benefits of Cordless Kitchen
1.1.2 Use-Cases
1.1.3 System Architecture
1.1.4 How Does it Work?
1.1.5 Internet Connectivity in the Cordless Kitchen
1.2 Challenges and Solutions
1.3 Takeaways
References
2 Ki-The Cordless Kitchen
2.1 Components of Cordless Kitchen
2.1.1 Power Transmitter
2.1.2 Cordless Appliance
2.1.3 NFC Communication Interface
2.2 System Parameters
2.3 Foreign Object Detection
2.4 Phases of Operation
2.4.1 Idle Phase
2.4.2 Configuration Phase
2.4.3 Connected Phase
2.4.4 Power Transfer Phase
2.5 NFC Protocol Extensions for the Cordless Kitchen
2.5.1 Dedicated Application States
2.5.2 Dedicated NFC Commands
References
3 Architectures for Internet Connectivity
3.1 Proxy Architecture
3.2 Bridge Architecture
3.3 Comparison of Transmission Latency
Reference
4 State of the Art
4.1 Tunneling Standard TCP/IP Protocol over NFC
4.2 6LoWPAN Adaptation for TCP/IP Protocol over NFC
4.3 TCP/IP Adaptation Mechanisms for High Delay Networks
References
5 Adapting TCP for the Bridge Architecture
5.1 Experimental Setup
5.2 Challenges in Adapting TCP
5.2.1 TCP Spurious Retransmissions
5.2.2 Packet Drops Due to Small Inter-Packet Delay
5.3 Addressing the Challenges
5.3.1 Avoiding Packet Drops Due to Small Inter-Packet Delay
5.3.2 Avoiding TCP Spurious Retransmissions
References
6 Evaluation of the Bridge Architecture
6.1 Implementation Recommendations
6.2 Results
6.2.1 Packet Retransmissions
6.2.2 Latency
6.2.3 Throughput and Goodput
6.2.4 Bandwidth Utilization
References
7 Parametric Analysis of the Bridge Architecture
7.1 Effect of TCP CWND Size and Slow Start Process on the System Latency
7.2 Effect of TCP MSS Size on the System Latency
7.3 Effect of NFC BER on the System Latency
7.3.1 Random Errors
7.3.2 Burst Errors
7.4 Effect of Varying the NFC Communication Time-Slot Duration on the System Latency
7.5 Considering Non-TCP/IP Messages over the NFC Channel
References
8 Conclusion
Reference