Paper Title (use style: paper title)


International Journal of Analysis and Applications 

Volume 18, Number 1 (2020), 117-128 

URL: https://doi.org/10.28924/2291-8639 

DOI: 10.28924/2291-8639-18-2020-117 

 

 

Received 2019-05-01; accepted 2019-11-18; published 2020-01-02. 

2010 Mathematics Subject Classification. 82B31. 

Key words and phrases. solar energy; solar cells; SPS; sun; wireless power transmission. 

©2020 Authors retain the copyrights 

of their papers, and all open access articles are distributed under the terms of the Creative Commons Attribution License. 

117 

 

SOME ASPECTS OF FUTURE ENERGY GENERATION IN USING OF SOLAR POWER 

SATELLITES 

 

MUNCHO J. MBUNWE1, UDOCHUKWU B. AKURU1, HILARY U. EZEA2, OGBONNAYA I. 

OKORO3, M. AYAZ AHMAD4,* 

 

1Department of Electrical Engineering, University of Nigeria, Nsukka, Nsukka 410001, Nigeria 

2Department of Electrical and Electronics Engineering, Federal University, Oye-Ekiti, Ekiti , Nigeria 

3Department of Electrical and Electronic Engineering, Michael Okpara University of Agriculture, 

Umudike, Umuahia 440001, Nigeria 

4Physics Department, Faculty of Science, P.O. Box 741, University of Tabuk, 71491, Saudi Arabia 

*Corresponding author: mayaz.alig@gmail.com 

ABSTRACT. Energy, which is required to run space satellites, is as old as space technology itself. 

The location of these satellites has made it more applicable for unconventional means of energy 

generation to run them. The Sun being the universal and greatest source of all forms of energy, as 

well as the closest energy source to space satellites, has been so appropriately trapped using solar 

cells. Solar power satellites are designed to capture solar energy and transmit that energy to 

receiving stations using wireless power transmission mechanism. This paper is written to 

rehearse the immediate and associated usefulness of solar energy trapped from space as an 

alternative for electricity generation for the future; it is also an attempt to appraise the prospects 

of this scientific conviviality.   

 

 

 

 
 

https://doi.org/10.28924/2291-8639
https://doi.org/10.28924/2291-8639-18-2020-117


Int. J. Anal. Appl. 18 (1) (2020) 118 

 

I. INTRODUCTION 

Space satellites are generally regarded as spacecraft that receive signals and send them back 

to earth. However, they are extremely complex and expensive because they have to work and 

survive in space for specified time periods, usually up to 15 years. To make this possible, a 

satellite has to produce its own power by generating electricity from sunlight falling on 

photovoltaic cells or solar panels. Batteries are used to store the energy, so that the satellite can 

continue to work when the Sun is eclipsed or far away. 

Because space is not a friendly environment, space satellites have to survive temperature 

variations of more than 200°C in a situation described similarly to someone standing in front of 

a fireplace with a blazing fire while an air conditioner pumps freezing air onto his back. Outside 

the protection of the earth’s atmosphere, the level of radiation (UV, X-rays, gamma-rays and all 

sorts of energetic particles) is much higher and more destructive than on the ground. Before 

they can even begin to operate in space, satellites have to survive the bone-shaking launch. 

Then the solar panels have to be opened and antennas, which are often stowed to take less 

space in the launcher, deploys before the satellite enters its operational orbit. This is responsible 

for the high amount of time and the great number of professionals needed in designing, 

building and checking for the correct functioning of a satellite.  

Electrical power delivery to earth using space power satellites (SPS) has a lot of similarities 

with space satellite technology. Peter Glaser, an American aerospace engineer, first proposed 

SPS in the late 60s [1], [2]. During the energy crises in the 70s, the US government took a hard 

look at them. The studies generated by this inquiry essentially reported that SPS were 

technologically possible but their cost and launch requirements were not. Fifteen years later 

NASA conducted a study to determine if anything had changed [3]. The new study concluded 

that costs were still high but they were not as high as originally predicted and that there were 

no technological showstoppers. At present, utility companies and governments are taking a 

closer look at SPS [4], [5]. Not only are they looking at them as sources of power on earth but 

also, as sources of power for satellites to reduce their size and launch costs [6]. 

SPS systems collect solar energy in space and transmit it via a microwave energy beam to an 

earth-based rectenna which converts the beam into electricity for use on earth, essentially 

defining the three stages of its operation (Fig. 1). SPS is thought to have several advantages over 

other forms of alternative energy, particularly over terrestrial implementation of solar power. 



Int. J. Anal. Appl. 18 (1) (2020) 119 

 

For instance, power supply system based almost entirely on renewable energy source will have 

to deal with intrinsic variability of the resources [7]. Nevertheless, SPS is not affected by 

weather, seasons, or by the earth’s atmosphere, which can otherwise act as a filter. 

Consequently, there is bound to be more intense exposure to sunlight not hindered by weather; 

hence no need for expensive storage which would have been of use during periods of low 

supply.  Besides, it is harmless to the environment, and with less political interference, since it is 

environmental friendly, as there is no CO2 problem associated with it. Although, there have 

been contrary views that it is too early to implement this technology because of its huge 

investment requirement, safety concerns and an infantile technology, among others [8], [9]. As a 

result, this paper is another attempt at highlighting the feasibility and inevitability of the SPS 

technology for future electricity supply.  

This paper has been organized as follows. Section 2 is used to highlight the need for future 

energy sources. Section 3 is used to briefly describe the SPS technology as well as their 

challenges. Section 4 is used to provide the state-of-the-art technology, while Section 5 is used to 

give a conclusion. Further, energy and power as used in this paper mean the same thing. 

Similarly, solar power satellite (SPS), space-based solar power (SBSP) or space solar power (SSP) 

as used correspondingly within this paper is without prejudice.  

 

 

Fig. 1. Operational diagram of an SPS system 



Int. J. Anal. Appl. 18 (1) (2020) 120 

 

 

Fig. 2. Proposed change in supplies for fossil fuels 

 

II. THE NEED FOR FUTURE ENERGY SOURCES 

Currently, the world relies on fossil fuels to generate electrical power. The reality of a 

projected but certain fall of the world’s oil reserve is confirmed in studies, e.g., [10].  Coal, a 

major source of energy supply is faced with a similar threat.  Fig. 2 is meant to show the rate at 

which these energy sources are expected to decline in the coming years [11]. It is 

understandable that as the world population increases, the natural resources to produce energy 

decreases, and alternative methods to produce sustainable, environmentally friendly, and cost 

effective energy are required (Table 1). Meantime, fossil fuels are not only depleting, but 

altering local environment and the world climate [12]. In the same vein, all three factors – 

petroleum peaking and declining, growing concerns of fuel-derived GHGs, and growing global 

demand for energy – were supported as the driving force for recent advancements in SPS 

technology [13].  

Unlike nuclear energy which is equally clean and abundant but very risky, there is no doubt 

that renewable energy sources give a huge prospect for future energy sources because of its 

large reservoir and lowering cost of energy, even as it remains the world’s fastest-growing 

source of electric power in the midst of ever increasing demand by end users [14]. In an era 

when new energy options are urgently needed, space solar power is an inexhaustible solution – 



Int. J. Anal. Appl. 18 (1) (2020) 121 

 

SPS scores an edge over the ground-based (PV) solar power in three notable areas: increased 

availability, easy accessibility, higher efficiency [15] and the technologies to make it happen is 

now at an advanced stage [13]. 

In a paper, China Academy of Space Technology (CAST) grouped into three the major 

advantages of SPS to China’s energy development as sustainable development, disaster 

prevention and mitigation, and retaining and cultivating talent [16]. Stating the several 

advantages to SPS, it was reported in ref. [17] that solar radiation can be more efficiently 

collected in space, where it is roughly three times stronger than on the surface of the earth and it 

can be collected 24 hours per day (since there are no clouds or night in high earth orbit). Thus, 

ensuring SPS does not use up valuable surface area on the earth by beaming to areas with the 

highest demand at any particular time. At the same time, current space missions are narrowly 

constrained by a lack of energy for launch and use in space. Missions that are more ambitious 

will never be realized without new, reliable, and less-expensive sources of energy [18]. Other 

benefits such as clean and safe energy source, limitless reserves and employment/investment 

opportunities make SPS the future energy system to beat. However, like every new technology, 

the next section is used to highlight some major concerns being raised against space-based solar 

power technology.  

 

III. TECHNOLOGY DEVELOPMENT AND CHALLENGES OF SPS 

Space-based solar power is a system for the collection of solar power in space for use on 

earth. SPS differs from the usual method of solar energy collection in that the solar panels used 

to collect the energy would reside on a satellite in orbit, rather than on earth's surface. In space, 

collection of the Sun's energy is unaffected by the day/night cycle, weather, seasons, or the 

filtering effect of earth's atmospheric gases. The average solar energy per unit area in space, i.e., 

vicinity of the Earth is 1366 W/m2 as compared to less than an average of 250 W/m2 obtainable 

on the surface of the earth. This drastic reduction in energy being as a result of atmospheric 

absorption and scattering, seasonal variations and weather [19].  

 

 

 

 



Int. J. Anal. Appl. 18 (1) (2020) 122 

 

TABLE 1.  EXPECTED GROWTH RATE OF SUPPLY AND DEMAND OF ENERGY SOURCES [20] 

Average projected 

energy demand 

growth 

Absolute change (as 

percent of current 

supply) by 2025 

Necessary growth in 

renewables + nuclear (percent 

of current supply) by 2025 

Necessary annual 

growth in renewables 

+ nuclear 

1% 15% 22% 9.3% 

2% 32% 39% 12% 

3% 51% 58% 15.6% 

4% 73% 80% 18.5% 

5% 98% 105% 20% 

A. Overview of SPS Technology 

Space based solar power is comprised of two major technologies which have been studied in 

some form since the 1980s [21], these are: architecture of the satellite and receiver module; and, 

the means to beam energy back to earth. Both possess challenges, with that of transmission 

technology being direr. To this, wireless power transmission has been identified as key to the 

development of SPS [22]. These two main technologies are further processed as: 

1) Means of collecting solar power in space: Solar power collection in space can be achieved 

using planar photovoltaic cells or thermal turbines which convert the solar energy into dc 

electricity. [15]. The energy collector could be a single crystal silicon which receives direct 

sunlight and is readily available. However, silicon cells are vulnerable to radiation. The 

collector could as well be gallium arsenide photovoltaic cells which exhibit a level of 

resistance to both thermal and radiation degradation but is not readily available.  

2) Means of transmitting power to earth: Due to long distances involved, wired 

transmission is impractical. Consequently, wireless power transmission is adopted. 

Usually, lower radio frequency transmission in the microwave spectrum (2.45 GHz) or 

high frequencies within the optical and infrared range are required. 

3) Means of receiving power on earth: The means of receiving the transmitted power 

depends on the transmission mode adopted during the transmission phase [17]. A 

rectenna (microwave-to-dc converter), which consists of a rectifying circuit and a 

receiving antenna most suitable for radio frequencies [23], while an array of photovoltaic 

cells are used for visible and infrared frequency ranges.  

The SPS concept is very involved, and several integrated studies have been undertaken over 

the years to design produce an optimum template for its operation [6], [13], [19], [24]. The good 



Int. J. Anal. Appl. 18 (1) (2020) 123 

 

news is that the basic physics of solar power satellites was resolved in the 1960s and 1970s, 

while the challenges over the years are, basically, engineering and economics [18]. The basic 

description of SPS, earlier shown in Fig. 1, can be adapted to two different architectures [19]: 

1) GEO-based Solar Power Architecture: The satellite can be placed within the Geostationary 

orbit (GEO), medium-earth orbit (MEO) or low-earth orbit (LEO). In GEO, the satellite 

appears to be stationary because the speed of Earth’s rotation corresponds to the orbital 

period of the satellite round the earth. Then due to its position, less than 1% of its total 

time is spent in shadow. If the satellite is placed in the LEO, this minimizes the range and 

brings about reduction in size and weight of the transmitting antenna. However, satellites 

in LEO have a reduced productivity owing to the fact that much of their time is spent in 

shadow as they orbit the earth.   

2) Lunar Solar Power Architecture: Here, power collector and beam forming equipment are 

mounted on the moon surface. This architecture, however, is affected by the 14-day lunar 

night and as such, constant power is not ordinarily provided. 

 In general, three principal GEO-based SPS concepts (Fig. 3) which have been identified and 

characterized for technical and commercial applications are [13]: 

1) Microwave Wireless Power Transmission (WPT)/Classic Power Management 

Architecture, involving large discrete structures (e.g., solar array, transmitter, etc.) 

assembled by a separate facility in space; this concept involves sun-pointed solar energy 

collection system, a wireless power transmission system which makes use for 

microwave radio frequency, and  ground based rectennas which receive the transmitted 

power. 

2) Modular Electric/Diode Array Laser WPT/Sandwich Power Management Architecture, 

involving self-assembling solar power-laser-thermal modules of intermediate scale; this 

can either be electric-laser or solar-pumped laser. The wireless power transmission here 

involves laser beam generation at the near visible part of the spectrum 

3) Modular Microwave WPT/Sandwich Power Management Architecture, involving a 

large number of very small solar power-microwave-thermal modules that would 

robotically assemble in orbit. This is a highly modularized architecture which involves 

light-redirection based energy distribution approach and depends on an integration of 



Int. J. Anal. Appl. 18 (1) (2020) 124 

 

solar generation, power management and distribution, as well as wireless power 

transmission subsystems on individual modules 

So far, the highly modular microwave WPT sandwich SPS appears to be the more suitable, 

offering clear advantages particularly for large-scale commercial base-load power, with 

fabrication and prototype testing recently performed [25].  

 The generic functional architecture which can be used to describe any of the SPS concepts is 

as shown in Fig. 3, where other systems integral to the SPS concepts have been identified such 

as [12], [15]: 1) earth-to-orbit (ETO) transportation; 2) affordable in-space transportation; 3) 

space assembly, maintenance and servicing; and, 4) ground energy and interface systems; as 

well as, 5) in-space resources and manufacturing. It is believed that all of these technologies are 

reasonably near-term and have multiple attractive approaches. However, a great deal of work is 

needed to bring them to practical fruition. 

B. Challenges associated with SPS 

Key areas of concern in the SPS concept are in terms of emerging technology, international 

policy and regulations, health and safety, terrorism, as well as high costs. The aspect of 

terrorism comes in since high power microwave source with high gain antenna is usually 

employed in delivering intense burst of energy which can be used as a weapon [26]. The other 

problems associated with SPS find their roots among any of these main areas. For instance, 

considering how to transmit the energy from the collection point in space to the place where the 

energy would be used on earth, technology, cost and health factors become critical.  

 

Fig. 3. Generic SPS functional architecture  



Int. J. Anal. Appl. 18 (1) (2020) 125 

 

 

 

Fig. 4. Conceptualized GEO-based SPS: (a): Microwave Classic (b): Modular Electric Laser (c): 

Modular Sandwich Microwave Generic SPS functional architecture  

 

The greatest barrier to the development of SPS has been identified as its high launch 

costs. As a result, a major spacecraft development project can cost many tens, if not 

hundreds, of millions of dollars, and over a lengthy period of time [27]. Such technical 

challenges greatly influence the economic feasibility of SPS. Yet, there are other myths 

bothering on safety for man, animals, high interference, space materials and orbit, machines 

and the environment [10]. 

However, in an attempt to delineate the advantages of SPS, it is implied that most of the 

observed challenges can be abated when the promise of bulk clean energy source of future 

growing energy demand, high transmission and conversion efficiency, ease of transmission, 

and non-hazardous radiation are factored [28].   

 

IV. RECENT DEVELOPMENTS IN SPS TECHNOLOGY 

In recent times, more world governments have concentrated time and money to study 

and develop the SPS technology. Intense efforts, spanning a 40 years period, have been 

made in the US, Canada and Europe [28]. China and India both started recent activities, 

while Japan has been undertaking steady technological strides in harnessing the technology 

up to developmental stage. In the wake of the disaster at the Fukushima Daiichi nuclear 

power plant, Japan Aerospace Exploration Agency (JAXA), a world-leader in SPS systems, 

now has a technology roadmap that proposes a 1 GW commercial system by 2030 [27].  

Elsewhere, international conferences, workshops and committees of experts have been 

sprawling the SPS concept in recent times in order to promote international dialogue and 

coordinate SPS efforts. The on-going Power Symposium of the International Astronomical 

Congress (IAC), as well as periodic conferences dedicated to SPS and WPT have been 

reported, and also hosted on a dedicated online Space Solar Power Library [13], [29]. 

(a) (b) (c) 



Int. J. Anal. Appl. 18 (1) (2020) 126 

 

Another plus is the recent international assessment developed by the International 

Academy of Astronautics (IAA) Study [13], which has been serially referenced in this paper. 

Its key findings were: 1) need for new energy technologies such as SPS; 2) SPS is feasible; 3) 

SPS will soon be economically viable; 4) more research is needed to fine-tune all parts of the 

technology; 5) low-cost ETO transportation will make SPS commercially viable; 6) prototype 

testing-of-concept need to be initiated to boost technology confidence; 7) technological 

development is currently transient; 8) existing power networks for transmission; and, 9) 

need for regulatory and policy frameworks. 

 

V. CONCLUSION 

So far, SPS technology – not new at all – appears to be receiving wider attention from 

governments and key stakeholders. To this end, the satellite-based technology is gradually 

converging most of its trajectories for the development and production of a prototype. 

Besides, the impetus for SPS appears to be an underlying drive to address concurrent global 

challenges of energy demand for a growing world population, in the midst of increasing 

environmental pollution and certain oil depletion. Though bearing in mind the present huge 

cost of production and other critical factors, SPS technology invariably offers great promise 

to tap directly into the Sun’s abundant solar energy for zero-carbon cum sustainable 

electricity production, and at a significantly greater efficiency than the current earth-based 

PV systems. The challenge however is that much work still needs to be done in terms of 

plugging together the technical and economic holes of the SPS technology, apparently 

making it a future source of power generation.     

 

ACKNOWLEDGMENT 

Authors Muncho J. Mbunwe & Udochukwu B. Akuru from University of Nigeria, 

Nsukka, Nigeria  and M. Ayaz Ahmad from University of Tabuk, Saudi Arabia have been 

working since a long time in personal joint collaboration. We would like to acknowledge the 

keen support in financial assistance for this research work to their respective Institutes / 

Universities [30-32]. 

 

Conflicts of Interest: The author(s) declare that there are no conflicts of interest regarding 

the publication of this paper. 

 

 



Int. J. Anal. Appl. 18 (1) (2020) 127 

 

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