802.11ad clients

Qualcomm have announced the Asus ZenFone 4 Pro will be the world’s first commercial smartphone to have 802.11ad. Asus also mention the 802.11ad capability.

There have been a few 802.11ad capable ‘prosumer routers’ available for a while, by Asus Netgear and TP-Link, so their makers must be pleased that finally users might seek them out based on that capability.

The high speed of 802.11ad makes it spectrum and time efficient, because to move an amount of data the radio can be off more of the time than a slower radio. Firstly, this means it will not occupy the spectrum (a finite resource) as much of the time. Secondly, it could potentially consume less power – always a good thing, especially for battery powered devices like smartphones.

Perhaps more interestingly, 802.11ad has an inherently short range. For a wireless personal area network (WPAN) this is a good thing. Obviously a WPAN only needs a short range, and if signals travel further than required they again reduce spectrum efficiency, because they occupy spectrum in areas where other WPANs could use it.

Fog computing

Cisco says its vision for fog computing is to enable its devices to do non-network specific data processing using their new IOx capability. They describe this processing as “at the network edge”. They argue that a shorter distance travelled over the network by data should reduce total network load, latency, and so ultimately the cost of transporting increasing amounts of data arising at the network edge from developments like the internet of things (IoT).

Development of Cisco’s scheme is very involved for the benefits it can deliver. Much data processing involves fetching data from network distributed sources such as databases, file servers, and the Internet. So for some data processing tasks network edge processing may even make the situation worse. Consequently while their scheme can do what they say, it is by no means a general purpose solution.

If Cisco’s concern is reducing network load, latency, and so data transport costs; then it is worth pointing out that much more capable network equipment than is typically being used has been available for many years. The problem with it is affordability. No doubt innovation to enable processing in network equipment will find uses, but for handling increasing network load and providing acceptable latency it is simpler, cheaper, and more generally applicable to innovate around making better performing network equipment more affordable.

Of more concern is that Cisco’s approach introduces the potential for rogue and badly written software to negatively impact on network infrastructure. Also it will probably lead to a fragmented market in programming for network equipment. Even if all vendors agree to support at least one particular programming language and runtime environment, vendors will inevitably provide APIs that make use of their specific equipment features. Once these are used this will tend to lead to vendor lock-in.

Enabling general data processing in network equipment is unnecessary, a suboptimal interpretation of the otherwise good vision of fog computing, and likely to create more problems than it solves.

Processing in fog computing could be handled by many specialised processing assets managed by policy and running a single standardised runtime environment with the ability to move running processes between assets on demand and as directed by automated policy based controllers. With this approach processes are not managed as associated with a device, but with a policy. Each policy selects appropriate devices from those available in the pool of assets. Such a network would significantly simplify managing processing and processing assets in complex and dynamic systems. It is important that these assets exist at a broad range of price points, particularly low prices, as they allow processing to be scaled in fine grained increments. The need for a specialised class of device is concomitant with the general trend in IT in which functionality has been progressively devolved to more specialised devices; something Cisco’s proposition goes against. For example, we are now at the beginning of a boom in wearable processing where specialised devices aggregate into wireless personal area networks (WPANs), and intra-body processing where specialised devices aggregate into body area networks (BANs). These kinds of devices are not just networked sensors; they do specialised data processing but are still networked. Obviously this proposition is not without concerns, but its processing mobility would address some of the aims that fog computing is proposed to address. Intel’s next unit of computing could be seen as a forerunner of this kind of asset, but the ideal class of device needs more directed development into the specialised roles rather than selling as low power versions of existing classes of devices like desktop computers.

Press release by Cisco on their vision for fog computing