Nigeria’s LEO Satellite Licensing: A Signal for Africa’s Broadband Ambition
In early 2025 the Nigerian Communications Commission (NCC) granted Amazon’s Project Kuiper – now trading as Amazon LEO – a seven‑year licence to operate a constellation of more than 3,000 low‑Earth‑orbit (LEO) satellites over the country. The decision follows the commercial launch of SpaceX’s Starlink service in Nigeria, which has already begun serving households, schools and small businesses. With two global LEO networks now licensed in Africa’s largest market, regulators are signalling confidence that satellite constellations can help close the continent’s stubborn connectivity gap.
The Persistent Connectivity Gap
Africa’s digital divide is well documented, yet the numbers remain stark. According to the International Telecommunication Union (ITU), only 36 % of Africans were online in 2025, compared with a global average of 74 % [1]. While fourth‑generation (4G) mobile networks reach roughly 70 % of the population, actual internet usage hovers around 40 % [2]. The infrastructure exists in many places, but affordable, usable connectivity does not.
Where Infrastructure Exists but Adoption Lags
Fixed‑line broadband is almost negligible: fewer than 1 % of Africans have a landline connection, versus about 18 % worldwide [3]. Fibre‑optic deployment, the backbone of high‑speed services in Europe and Asia, extends to only 30 % of the African population within a 10‑kilometre radius of a node [4]. Consequently, the business case for laying fibre or erecting new cell towers in the remaining rural and remote zones remains weak under current market economics.
The Rural Challenge
Several factors keep the final 30 % of the continent offline:
- Low average incomes that make monthly data plans prohibitively expensive.
- Limited electricity access, which hampers both end‑user devices and network equipment.
- Geographic barriers such as dense forests, mountains and dispersed settlements that raise deployment costs.
- Regulatory uncertainty around spectrum allocation and licensing timelines.
These realities have kept broadband penetration flat for the past two decades, despite numerous pilot projects and public‑private initiatives.
Why Low‑Earth Orbit Satellites Matter
LEO constellations orbit at altitudes of 500–1 200 km, delivering latency in the range of 20–40 milliseconds – comparable to terrestrial fibre and far superior to the 600 ms typical of legacy geostationary (GEO) satellites [5]. This performance makes LEO links viable for latency‑sensitive applications such as online education, tele‑medicine, real‑time trading and cloud‑based enterprise services.
Market analysts estimate the African LEO broadband market was worth roughly US$5.9 billion in 2024 and project it to reach US$11.4 billion by 2032 [6]. The NCC’s licence for Amazon LEO is a concrete validation of those forecasts, confirming that investors see a sustainable revenue stream in serving Africa’s underserved populations.
The Overlooked Rule: EPFD Limits in Article 22
Despite the promise of LEO technology, a decades‑old regulatory provision could still cap how much of that potential reaches end users. Article 22 of the ITU Radio Regulations contains the “Equivalent Power Flux Density Limits” (EPFD) – upper bounds on the power a non‑geostationary (NGSO) system may emit in frequency bands shared with geostationary (GSO) satellites [7]. The limits were negotiated in the early 1990s, when satellite constellations were modest and interference mitigation techniques were rudimentary.
How EPFD Works
EPFD sets a maximum power flux density that an NGSO satellite may produce at the Earth’s surface within a given bandwidth. The intention is to protect GSO services – such as broadcast television and weather satellites – from harmful interference. Because the limits are expressed as absolute power levels, they do not scale with the number of satellites in a constellation or with advanced beam‑forming and interference‑cancellation technologies that modern LEO operators employ.
Impact on Service Quality
When EPFD caps are reached, operators must either:
- Reduce transmit power, which lowers the signal‑to‑noise ratio and can shrink coverage cells.
- Limit the number of simultaneous users per beam, decreasing overall network capacity.
- Shift to less‑optimal frequency bands, potentially increasing latency or requiring larger user terminals.
In markets where every megabit per second counts – such as rural clinics relying on tele‑consultations or farmers accessing market prices – these constraints translate into fewer online schools, fewer tele‑health appointments and fewer small businesses able to participate in the digital economy.
What This Means for Nigeria and the Continent
The simultaneous licensing of Starlink and Amazon LEO creates a competitive environment that could drive down prices and spur innovation. However, the full societal benefit will only be realized if regulators revisit the EPFD framework to reflect today’s technical capabilities. Adjusting the limits – or allowing dynamic power‑control mechanisms that respect GSO protections while unlocking NGSO potential – could markedly improve service quality without compromising existing satellite operations.
Policymakers across Africa have an opportunity to harmonise national spectrum rules with updated ITU guidance, invest in ground‑station infrastructure that supports gateway diversity, and foster local content ecosystems that make broadband adoption attractive and affordable.
Looking Ahead: Policy, Investment, and Innovation


