Attributes | Description |
Type | New |
Industry Sector | IoT |
Business driver | There is currently no global specification for broad IoT interoperability, independent of the physical radio. DQ is a universal lower MAC , therefore which can allow synchronous and asynchronous can flows to share the channel, hence a seamless migration path to near-perfect packet efficiency. Moving the buffer to the Edge will allow stable QoS under any condition. |
Business use cases | 1. Automotive 2. Industrial IoT 3. Smart City |
Business Cost - Initial Build Cost Target Objective | There is no additional cost for utilizing a Distributed Queue (DQ) collision detection scheme, as it is a direct replacement or swap with Aloha-based technologies, requiring no change at OSI layers 2.5 or above and 50% energy saved in the PHY. Experimental Zigbee and LoRa base stations with with a RasPi and a radio hat have been achieved were built for $85 at Bucknell for crowdsourced regional mesh networks. |
Business Cost – Target Operational Objective | The target operational objective is to achieve >95% throughput at all times, or Near-Perfect packet efficiency in a star network. Some efficiency will be lost in the hybrid DQ model to afford a commercial migration path for legacy devices which have no knowledge of the novel MAC but this will still shatter the Aloha-based 50% maximum. |
Security need | Security is a function of packet efficiency and needs a broadcast architecture for ensemble computing ensembles to open the IoT metaverse. DQ also allows us to encrypt the whole packet at the MAC/Data Link layer including the packet header. See security discussion in the attached SAE Journal article. |
Regulations | CPNI law is a better part of the Telecommunications Act of '96 which can now be upheld in shared-packet networks, along with other privacy laws started at the US Postal Service before converting into it became telecom privacy law. |
Other restrictions | Licensed RF is restricted. WiFi, and other unlicensed RF for the IoT including long range TVWS airwaves are not. |
Additional details | The hexadecimal address list from the DQWA Appendix can be made available. It At 60 pages, it was only left out to make the specification document more manageable. |
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Case Attributes | Description |
Type | New |
Blueprint Family - Proposed Name | Buffer at the Edge |
Use Case | IoT |
Blueprint proposed Name | Buffer at the Edge Blueprint Family: Swapping out Aloha-based MACs |
Initial POD Cost (capex) | N/A |
Scale & Type | Theoretically infinite |
Applications | Massive IoT with stable QoS |
Power Restrictions | Reduced by half bit for bit since payload data never suffers collisions. |
Infrastructure orchestration | Host: •Any fine grain network hardware |
SDN | N/A |
Workload Type | N/A |
Additional Details | N/A |
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Committer | Committer Company | Committer Contact Info | Committer Bio | Committer Picture | Self Nominate for PTL (Y/N) |
Jonathan Gael | M2M Bell | jonathan@m2mbell.com | Gael looks forward to contributing the fully drawn specification for any engineer to build an interoperable DQ system. | N | |
| Houda Chihi | Tunisie Telecom | houda.chihi@supcom.tn | Y | ||
| Inam Ullah Khan | Communications Technologies Lab | inamullahkhan05@gmail.com | N |
Attributes | Description |
Type | |
Industry Sector | |
Business driver | |
Business use cases | |
Business Cost - Initial Build Cost Target Objective | |
Business Cost – Target Operational Objective | |
Security need | |
Other restrictions | |
Additional details |
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