Last week, the official launch of the Wi-Fi CERTIFIED Passpoint™ Release 2 interoperability program from Wi-Fi Alliance (WFA) revealed the next chapter in enabling mobile client devices to easily connect to a secure (i.e., strong encryption and authentication) Wi-Fi network. And once again, Cisco is at the forefront of furthering the proliferation of new and improved Wi-Fi capabilities by having participated in and contributed to the successful launch of Passpoint Release 2.
With 1.1 million units in the marketplace, Cisco is far and away the market’s #1 provider of 802.11ac wireless infrastructure with the industry’s broadest and most powerful product offerings for the Enterprise, Service Providers, Small Medium Business and exploding Cloud market spaces.
Providing up to 3 times the performance of legacy 802.11n deployments, 802.11ac provides the performance and scale foundation for companies as they move to an all-wireless and -mobile working culture in their day-to-day business operations.
Ever since the much anticipated 802.11ac standard was ratified and supported by Enterprise class access points (AP), I’ve asked myself the question that perhaps other network and Radio-Frequency (RF) engineers have: how much of the theoretical 1.3Gbps 802.11ac data-rate can I really deliver to my users and what is the overall throughput experience when I deploy at scale or in high-density (HD) scenario? On the surface, it may seem intuitive that I should allocate 80MHz to my 802.11ac radios to achieve the best throughput BUT as it turns out, this approach has limited scale and may lead to less total throughput than a smaller 40Mhz channel -- so in this case; less may be more!
This is due to the fact that while in a single-cell (AP) scenario (say 5000 sq. ft) it is realistic to expect most capable devices can reach 1.3Gbps (1Mbps of throughput) with 3 spatial stream (SS) & 80MHz (e.g. MacBook Pro) and 433Mbps (300Mb/s of throughput) with 1 SS & 80MHz (e.g. iPhone 6) BUT this throughput degrades quickly in a multi-cell environment where co-channel-interference (CCI) from neighboring APs can dominate. So we need to look at the primary CCI contributors, which are: Read More »
Location-based applications have endless use cases—simply tapping into the users’ whereabouts can provide useful information such as movies playing, surrounding restaurants, friends’ favorite spots, etc. Still untapped, however, is the many potential uses of a location-based service, because while the apps may get the user to a location and allow them the opportunity to “check-in,” these apps do little else to engage the user while they’re within the physical venue they’ve been directed to.
Retailers, grocery markets, car shops, hospitals, museums, hotels, basically any physical venue, could leverage location-based services to engage their patrons through mobile devices. Rather than having a store full of texters, Facebookers, Tweeters, etc. a retail store has the potential of actually getting in front of and engaging the actual shoppers by providing them with wifi, special deals, style suggestions, in-store directions, etc. Exploring this largely uncharted world of location-based engagement can be made possible through our Cisco Mobility Experiences (CMX) SDK.
Rijksmuseum in the Netherlands is one of the top 10 art and history museums in the world.
We live in an era where information is available in the palm of our hands and traditional institutions such as museums are inevitably facing the consequences of this. Even though the museum dates back to the 1800′s with artifacts from the middle ages, they have embraced modern technology to adapt to the changing landscape. This was as a matter of survival considering the competition from other institutions.