For a recent assignment on #spacedebris, I asked undergraduate & postgraduate students to evaluate the benefits & risks of a LEO (NGSO) constellation & to say whether approving a license application was merited. Here's a thread about what they said:
Of the 38 students participating, 58% thought that approving such a licence application was merited, 24% thought more analysis was needed & 18% thought that denying the license application was the correct action.
Some of the positive points identified wrt NGSO proposals were: 1. Providing internet access to remote regions & those lacking terrestrial infrastructure. 2. Meeting or exceeding expectations wrt #spacedebris mitigation guidelines.
...
3. Avoiding RF interference with other providers. 4. Advocating for #SpaceSustainability. 5. Innovative solutions for managing conjunctions with other orbiting objects. 6. Proactive & early disposal of satellites with faults. 7. Designed for demise.
Some of the negative points identified were: 1. Reliability of satellites (& that so much depends on this). 2. High manoeuvre burden for the operator & operators of other spacecraft traversing the constellation. 3. Optical & RF brightness of the satellites.
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4. Economic stability/resilience of the operator. 5. Inconsistent approaches to regulation globally. 6. Accuracy/trustworthiness of models used to evaluate #spacedebris risks. 7. High consumer costs. 8. De facto ownership of key orbital altitudes. 9. Conflicts of interest.
It was also interesting to see some biases in the student responses that can also be found in published studies (some I admit to) & in stories in the media:
1. Basing estimates of satellite reliability or likely success of #spacedebris countermeasures on different & sometimes decades-old space systems.
If you wanted to purchase a new phone, would a poor experience with an old [brand X] model mean that you would avoid a new [brand Y] model?
2. Confusing "lower" or "less" with "low". Some NGSO systems are aiming for LEO altitudes where the spatial density is "lower" than the current peak spatial density at 800 km. Nonetheless, the spatial density is not necessarily "low".
3. The implications for long-term #SpaceSustainability are all that matters. At some of the proposed altitudes, these new NGSO systems will not pose a long-term hazard but there will still be implications for #SpaceTrafficManagement.
4. Adding a "mega-constellation" will trigger the Kessler Syndrome. I have written about this one already. The sad reality is that current space activities are already taking place in the context of a #spacedebris population that is growing uncontrollably (perhaps for now)...
...so the Kessler Syndrome ship has sailed. Several mega-constellation operators have recognised a way to limit the long-term impacts of their activities is to aim for altitudes below about 600 km. This will be effective (as long as the atmosphere continues to help us)...
...but it still requires careful analysis & work to reduce the #SpaceTrafficManagement burden.
Overall, I am really proud of my students. Collectively, they identified the key issues being driven by, and facing, mega-constellations. They understood the potential benefits but saw the compromises needed to make them a reality.
I also learned a lot by reading what my students had to say. They will soon be young professionals in the space industry with ambitions & talents to match. But they will also have an awareness of the #spacedebris challenges that lie ahead if we are to succeed in space.
It's also been good to gain insights into the challenges faced by the operators & the regulators. There is no easy way through. Until we have a "vaccine" for #spacedebris, we are going to have to learn to live with it for some time.
End.
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Welcome to this month's look at #Starlink conjunction risk mitigation manoeuvres. Through 30 April 2023, I estimate that Starlink satellites have made a total of > 45,000 manoeuvres to mitigate the risk of colliding with other space objects [1/n]
A better relationship to consider is the one between the (cumulative) number of manoeuvres and the (cumulative) number of Starlink satellites launched. The growth is a non-linear function of the number of Starlink satellites [2/n]
Here, I looked at the manoeuvre estimates/reports in 6-monthly intervals, corresponding to the reporting periods used by SpaceX. Additionally, I added a prediction to the end of 2024 based on an exponential fit through 30 April 2023. [3/n]
I've been thinking about the new proposed @FCC "five-year rule" for #SpaceDebris mitigation & wanted to share some analysis & thoughts. Whilst I think the intentions are good I believe the implications of the change are poorly understood. Let me explain... [1/n]
As @brianweeden's excellent thread explains, "The new proposed ruling would require all FCC licensed satellites that end their life in LEO to re-enter the atmosphere within 5 years, and ideally ASAP." [2/n]
Latest analysis for #Starlink & #OneWeb shows these two constellations accounted for 42% of all close approaches within 5 km predicted by #SOCRATES at the end of August, with Starlink alone accounting for 29%. [1/n]
On average, #SOCRATES predicts that each #Starlink satellite will now experience 1 close approach within 5 km with a non-Starlink object every day, and each #OneWeb satellite will experience 3.4 close approaches with a non-OneWeb object every day. These rates are increasing [2/n]
Here's the same data from [2/n] plotted with respect to the number of satellites in each constellation in orbit, clearly showing #SOCRATES predicts that #OneWeb satellites experience more close approaches (within 5 km) per satellite than the #Starlink satellites [3/n]
A follow-on from yesterday's thread with a note about averages. In a #SOCRATES report from 30 June 2022 the average collision probability for each #Starlink conjunction was 3.7E-6 but the range of values can be broad (chart shows data since 2019) [1/n]
#SOCRATES predicted some events with a collision probability > 1E-2 (1-in-100) & some with a probability < 1E-7 (1-in-10,000,000). The average value might seem to be almost negligible & you might think all conjunctions would be similar, but that's not the case [2/n]
In addition, some #Starlink & #OneWeb satellites experience more conjunctions than others. Most satellites experience relatively few encounters but a few satellites are involved in a relatively large number (charts shows data for 7 days from 30 June 2022) [3/n]
Welcome to my (delayed) monthly analysis of @CelesTrak#SOCRATES conjunctions. Since 1 March 2019, SOCRATES has predicted about 9 million unique conjunctions within 5 km involving active or derelict payloads. This is a thread focused on those involving #OneWeb & #Starlink [1/n]
#OneWeb payloads have accounted for ~500,000 unique conjunction predictions since 1 March 2019 (5.5% of all predictions made), while #Starlink payloads have accounted for ~1.1 million (12.5%) [2/n]
On 1 March 2019 #SOCRATES predicted ~3860 unique conjunctions within 5 km. On 30 June 2022 the corresponding number was ~10,160, an increase of ~160%. #Starlink accounted for ~2570 (25%) & #OneWeb accounted for ~1250 (12%) [3/n]
In advance of my monthly analysis of #Starlink conjunction data I wanted to share some additional analysis undertaken over the last few days. It's a work in progress but here's a thread looking a little deeper at the #SpaceX approach to #Starlink orbital space safety [1/n]
My focus has mostly been on understanding the implications relating to the choice of the probability threshold for collision avoidance manoeuvres. With the #SOCRATES#Starlink data now running across nearly 3 years we can gain some insights that may be useful [3/n]