A New Opportuniy In Satellite Industry...IoT

The Internet of Things (IoT), also known as Machine-to-Machine (M2M), is hardly a new market for satellite Industry.

M2M has been around for years in the form of SCADA (Supervisory Control and Data Aquisition), an industrial control system for remote monitoring and control. The M2M protocol is designed to be quite compact and data rates are low which have long made this technology cost effective over satellite.

Where IoT differs is in volume. A typical SCADA system might involve a few hundred sensors across a pipeline network. Today's IoT system are scaled for thousands of endpoints, and are designed for flexibility in terms of bandwidth. For example, an IoT system may transmit low-resolution video but automatically switch to high-resolution video on a single camera when triggered by a motion sensor.

Growth in IoT is projected to be astronomical : anything from 25 billion to 50 billion connected devices by 202, depending on which survey you read, far exceeding the number of broadband connections between human beings. The vast majority of these devises will be connect over terrestrial network, but a meaningful percentage will do it over satellite. The research firm NSR estimates a global market of 5.3 million units by 2024, which will bring in revenue if US$ 2.3 bn for satellite industry

The oil and gas business has always been a major market segment for SCADA, so there should be no surprice that this is one of the first industrial segment to adopt IoT via satellite. Despite the current slump in oil prices, interest from this sector remains strong.

Companies are looking for the increased of efficiency, cost reduction, and safety improvement that can be derived from strategically located sensors.

Other IoT growth sectors for satellite industry include utilities, maritime, aeronautical, mining, and land transportation; essentially anything that is beyond the reach of good terrestrial coverage.

This points toward markets in the developing world, but operators also have networks in the rural regions of the developed world, from environmental monitoring to digital signage at bus stops indicating when the next bus will arrive.

A totally new market that may emerge is updating the software systems on modern cars. This is an application that is ideally suited to the broadcast capability of satellites. It does however depend on the commercial production on flat panel antennas.

The Internet of Things Ecosystem

The full ecosystem is a complex network of sensor, actuators, communication carriers, applications, analytics, security, data storage, and system integrator. No teleport operator. satellite operator, or technology provider has the capability to deliver all of this.

Some operators are better placed than others, by virtue of natural affiliations (ownership or a common parent company) with telcos and other companies operate in IoT. For those teleport and satellite operators without a telco parent, there is a great variation in the approach being taken to finding and aligning with other players in the value chain.  

Clearly, the best course for teleport and satellite operators is to try talking to everyone; the systems integrators and terrestrial carriers which already doing the business with as well as new connections with mobile and wireless technology companies that manufacture devices and integrate them into IoT solutions.

High Throughput Satellites

High Throughput Satellites (HTS) push more bits through the transponder, and this is driving the cost of bandwidth down by a factor of ten in some cases. IoT applications are generally low bandwidth, however. it is not obvious that lower bandwidth cost would be a major attraction.

As the number of sensors grows, demand for bandwidth and the associated costs will also grow. Not only is the number of sensors increasing, so are the bandwidth demands per sensor.

Some applications are expected to transmit more frequent that in the past and some will use higher data rates, for example, to switch on a surveillance camera automatically when a motion detector is activated. Add all this together and suddenly the cost of bandwidth begins to matter.

Cheaper HTS bandwidth is already starting to open up new markets, particularly in maritime where L-band has dominated for so long. Gathering data from an entire fleet of ships and combining it with meteorological forecasts, for example, make it possible to optimize shipping routes, saving fuel and time.

IPSTAR HTS Coverage

High Throughput Satellites are designed to deal with a high number of remote terminals, something that is ideal for IoT systems. The focused power of HTS Spot Beams make possible smaller antennas and lower power terminals, which reduce remote terminal cost. Though IoT applications do not really need high throughput, the lower capital cost of remote terminals will tend to make HTS dominate over time.

Satellite-based IoT work in progress. Revenue from IoT applications, if it is measurable at all, makes up only a small proportion of revenue. One tech executive noted that "Cisco has a patent on a sensor that can be sprayed into fields to monitor moisture, sunlight, and other factors. That's the kind of application that would be ideal for satellite."

Another technologist attributed the increase in applications to the increase in bandwidth: "Data analytics, machine learning - they will just become a standard part of the business, an expected capability. This will open up new opportunities for us all.