A high-throughput satellite is typically any satellite with three to four times the capacity of a regular fixed-services satellite in the same geostationary orbit. This extra bandwidth is achieved in two ways, primarily by utilising proprietary “frequency reuse” methods with a single reflector on the satellite, but also by concentrating the same amount of energy as a typical Ku-band beam on smaller geographical areas in order to increase the received signal level on the ground and therefore the amount of data that can be transmitted (more on that later).
How does it work?
Traditionally a single Ku-Band beam over Europe would cover a whole country or multiple countries. For instance, a beam might just cover the UK for DTTH TV services to that country, which is great for broadcast and multicast traffic. However, in the age of unicast IP traffic, one signal covering such a large geographical area only provides benefits to the teleport (hub side) for ease of aggregating all the remote sites, wherever they are, because the internet traffic from one site in Norway (for example) would be different to internet traffic from another site in Spain (for example). So, if there was a way for the teleport to reside on a larger beam just as before, but the signals transmitted and received at said teleport to then be relayed to smaller beams for the remote sites, we would then be able to get more bandwidth to the remote sites.
By using smaller spot beams, it is possible to re-use the same frequencies in different countries using the same reflector on the satellite, each smaller beam would then have about the same bandwidth as a traditional beam that would use the whole reflector on the satellite. This permits the practical use of 32APSK modulation to further increase the bandwidth available compared to the traditional maximum 16APSK.
Typical spot beam size (in red) for Ku and Ka Band:
Where is it available?
The first commercially available HTS service was “KA-SAT” by Eutelsat in 2009, covering Europe with high power Ka-Band spot beams. This became very popular for the “too-way” domestic internet service in Europe. Due to the highly-focused uplink beams and the smaller wavelength of Ka-band, relatively small “2Watt/1Metre” terminals are able to reach broadband speeds on their upstream as well.
Newer services like Telesat Vantage and Intelsat Epic continue this trend towards HTS becoming mainstream as they take advantage of the same technology for the Ku-Band spectrum. Additional costs for the proprietary “frequency reuse” payload systems can be offset against the flexibility of where services can be delivered (specific in-country services for example), higher availability and increased capacity that can be delivered (more customers, more revenue, higher data-rates, all in one rocket mission). It’s important to note that HTS does not necessarily mean Ka-Band. With sophisticated channelisation on the satellite transponder, Ku-Band frequencies can be re-used as well. For example, Intelsat EPIC covers the Atlantic Ocean from Europe to the Americans with a series of smaller Ku-Band spot beams each with 62.5-250MHz available (compared to 500Mhz total for a traditional non-HTS satellite). HTS channelisation also offers additional flexibility when delivering multiple services on the same transponder by allowing various different carrier levels and gain settings for each channel that shares the same transponder and in most cases the up/down spot beam routing can be adjusted as per customer requirements.
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