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Everything posted by jimmymcgoochie
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Logspam when in VAB
jimmymcgoochie replied to infinite_monkey's topic in KSP1 Technical Support (PC, modded installs)
Post the full log files, something could be failing earlier to cause this exception spam. -
KSP2 AMA Series - Chris "Nertea" Adderley - Answers/Transcript
jimmymcgoochie replied to Dakota's topic in KSP2 Discussion
Ner-TAY-ah? -
Woomera is a bad place for rocketplane flights, the desert around it is relentlessly lumpy and impossible to land in. Water landings are much safer, and parachutes and ejector seats are a must in case you end up heading for a sand dune. You should also use fine control mode (caps lock) for high speed flight to avoid tearing the wings off. Funnily enough, data from the crew reports got transmitted back during the descent so there wasn’t any left by the time it landed. Heavy satellites is geared towards Soviet R-7 style rockets, they’re much more expensive in terms of LCs and production costs so the program pays more and gives a bit more time, I doubt it’ll work with only British engines.
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EuROSTAR: Europe's Space Program (RSS/RO/RP-1)
jimmymcgoochie replied to jimmymcgoochie's topic in KSP1 Mission Reports
An abnormally large group of journalists, reporters and photographers gathered in Woomera, braving the heat of the desert summer to watch history in motion. They were about to be treated by two rapid-fire launches: first, a Quasar tanker to top up the orbiting Blitzar's tanks. A short time later Rene Sørenson and Lynda Wilson sat in their Penguin Mk2 capsule as a sudden downpour pelted the windows in front of them, sending onlookers scurrying for cover. Just when it seemed the launch would have to be delayed until the next day, the rain stopped and the launch could proceed as planned, minus any photographs of the launch. One plucky photographer had driven to a point downrange of Woomera and managed to snap a picture of the rocket after booster separation; he was promptly arrested for breaching the safety cordon. Once in orbit, the lander's name was finally revealed: Europa. (How original...) It took just under a day for the Quasar tanker to rendezvous with the waiting Blitzar... ...with the "lunar stack" of Penguin Mk2 and Europa arriving a day later. Keeping track of four separate vessels all trying to manoeuvre around each other at the same time was a logistical headache for mission controllers on the ground, but with Lynda and Rene looking out the windows and some very careful movements all around, the docking was done and Moonflight 0 was ready to depart. The journey to the Moon was uneventful. Lynda and Rene spent some time running scientific experiments in deep space to compare the results with those from low orbit and snapping some photographs of the Earth growing ever smaller in the windows. The Blitzar booster expended the last of its propellant to begin the lunar capture burn, after which the Penguin Mk2's own engine took over. The mission plan required first a loose capture into an elliptical orbit, followed by a second burn to lower the orbit a few days later. This gave the crew ample time to run more experiments in lunar orbit and a photograph that was later published as "the first picture of everyone": Trying to take a picture with a free-floating camera in space wasn't easy, especially when your colleague keeps arguing about which way "up" is; however it also showed how terms like "up" have a very different meaning in space. The pair spent nearly a week in lunar orbit, taking the Europa lander on a series of manoeuvres to test the propulsion systems before returning for rendezvous and docking practice, after which the remaining supplies were transferred to the capsule and Europa was programmed to deorbit itself, meeting the Moon at last. With the lander gone, it was time to come home. Recovery crews were already racing towards them as Lynda and Rene touched down safely in the Australian desert, landing just as the sun came up and so avoiding the heat of the desert summer before being flown by helicopter to the quarantine site at Woomera. The success of Moonflight 0 brought significant rewards financially, scientifically and technically, but perhaps more importantly it showed that all the necessary components for a Moon landing were now in place and had been tested as far as they could be short of actually landing on the Moon. Closer to home and flying relatively under the radar, metaphorically speaking, Olga and Damien's mission aboard OrbLab 1 met its initial 30 day target duration and then another 30 days after that before the decision was made to bring them home. They returned to Earth a few days after Moonflight 0 and splashed down in the Southern Ocean to the south of Australia, ensuring that they'd be rested and recuperated in time to begin training for the Moon landing mission with Lynda and Rene. The success of OrbLab 1 didn't grab the headlines nearly as much as Moonflight 0, but it nevertheless demonstrated a lot of key technologies that would be required for longer-term crewed spaceflight and highlighted some areas where technology currently fell short- the prototype space toilet was on the receiving end of some scathing reports by both Olga and Damien for being uncomfortable, difficult to use and in full view of the entire station. And the smell... With those two successes and a huge influx of funding, EuROSTAR could begin a series of facility upgrades and constructions: an even larger Vehicle Assembly Building, so large that the current one could fit inside it, was constructed around the existing VAB to minimise disruption, giving it the appearance of a set of nesting dolls; the astronaut training and support facilities were upgraded with pioneering underwater EVA practice pools and artificial lunar surfaces; the tracking and communication systems at Woomera and the three DSN sites were all upgraded to yield greater bandwidth for broadcasting live audio and video from the lunar surface; the research and development facilities at Woomera were also upgraded with cutting edge equipment and state of the art computers, with significant funding invested in other sites across Europe to ensure that new technologies would continue to be developed and new discoveries made (and to appease a fair few politicians who weren't very impressed with the "European" space program spending nearly all of its time and money in Australia). While all that was going on, Canopus Mars had been waiting in orbit trying to charge its batteries enough to deploy its lander. Solar panel wear and the distance from the Sun had combined to make this a long and arduous process, but at last there was enough power stored up to deploy the lander without the orbiter dying in the dark Martian night. Mars' atmosphere is very different from Earth's and even more so Venus', with very low pressure expected making aerobraking and landing under a parachute much more challenging. Mars' smaller size and lower gravity meant that orbital velocity was less than half of Earth's so re-entry heating wouldn't be nearly so severe, but it remained to be seen if the atmosphere would be thick enough to slow the lander down enough before it crashed into the surface. The lander's sensors recorded as much as they could during the descent, beaming the data back to the orbiter above which then relayed the data through Algol Mars back to Earth. It soon became clear that despite the atmosphere's relative thinness, it was still slowing the lander more than initially expected and it would fall well short of the targeted landing site in Hellas Basin, instead coming down in the Martian night. The kevlar-weave parachute deployed while the probe was still supersonic and dragged it down to around 12m/s, faster than expected and potentially too fast for the probe to survive; worse still, the heatshield had been jettisoned and so couldn't be used to absorb the impact as it had on Venus. With several minutes of light speed delay, all mission controllers on Earth could do was watch the data and hope that the lander would survive its hard landing. The altitude ticked down as the velocity stayed stubbornly high, then all telemetry cut out. A few seconds later... The signal returned, now relaying directly via Algol Mars as the Canopus orbiter had gone below the horizon. The probe was on the ground, intact and with all its instruments still functioning. Its batteries lasted long enough to transmit the first images of a sunrise from another planet, revealing a barren desert of rusty dust and rocks, along with the first glimpse of Earth from the surface of another planet. The data would be reviewed and re-reviewed before being released to the world, simultaneously dashing hopes that Mars was secretly harbouring life and raising the prospects that it simply didn't harbour life at that one specific location or that the lander's relatively simple suite of instruments couldn't detect it. With the next Mars probes planned to be broadly similar to their predecessors with a few new or upgraded instruments, the question of whether Mars held alien life would remain unanswered for some time yet. With the USA pinning their hopes on Apollo and the Saturn V, both still in development, and the USSR's lunar ambitions seemingly stalled after the death of Sergei Korolev and perpetual underfunding, Europe enters the final stretch of the race to the Moon with a seemingly unassailable lead... -
The logs are saying there's a d3d11 error (error code 0x887a0005) just before the crash. I remember seeing something similar a while ago and I think the issue was caused by outdated GPU drivers, so try updating those? There are also some errors about non-ASCII characters, including in the Duna vessel that's being loaded just before the crash. It might just be coincidence, but try changing the name and see if that helps?
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KSP2 AMA Series - Chris "Nertea" Adderley - Answers/Transcript
jimmymcgoochie replied to Dakota's topic in KSP2 Discussion
Turns out I was saying it wrong this entire time! Sorry, Ner-tea. -
You don’t need to save up for building upgrades, they happen over time in PLC and you can trim their speed to balance the budget. Some newer versions of PLC also include tooling costs in the unlock subsidy. Running a surplus of over 100 funds/day is unnecessary, you could be hiring more engineers and researchers with that to get everything done sooner. You didn’t actually start the training for Clare Wood the first time as you didn’t select her name to add her to the course.
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EuROSTAR: Europe's Space Program (RSS/RO/RP-1)
jimmymcgoochie replied to jimmymcgoochie's topic in KSP1 Mission Reports
There are still some tests to run on the Penguin capsule before it goes to the Moon and Penguin 4 will be completing those. Olga and Damien have been trying some more advanced re-entry simulations to try and improve their accuracy; nine days after launch, having pushed the capsule's life support systems to their limits, they put the training into practice. The previous record was just under 20km from Woomera... ...which was absolutely smashed as they touched down within the perimeter fence. With all key systems now certified, the Penguin Mk2 is greenlit for the initial test flight in low Earth orbit ahead of lunar missions. It'll use the same capsule (with improved heatshields) but a much larger propulsion module powered by an upgraded RZ.20 rather than a Larch-1 and is intended to brake itself and the lunar lander into orbit of the Moon with enough fuel left over to return to Earth after the landing is complete. Meanwhile, over at Mars... The capture stage had plenty of delta-V left after the capture burn, but was detached anyway to maximise solar panel exposure as panel wear was higher than anticipated and combined with the weaker sunlight this means the probe is struggling for power. Algol Mars is also approaching its destination, but before it gets there the first Penguin Mk2 is ready to fly. This mission will test its ability to fly with nearly ten tons of extra mass docked to the nose- for lunar missions this will be the lander, but for now it's a science module of similar size and mass with some pretty sophisticated equipment on board for Rene to play with- er, perform experiments with. The Penguin Mk2 is the first spacecraft ever to have a docking port on each end- this is to allow it to dock to the Blitzar lunar transfer stage and the lander at the same time for the TLI burn. This is also the first time a spacecraft has launched without a trained pilot at the controls, since Olga and Damien were still in their mandatory rest period after their last mission. The automated docking system did its job perfectly and the flight testing could begin, along with a sizeable number of science experiments and the first use of laboratory equipment aboard a spacecraft to process samples and generate data that could be transmitted back to Earth. In the future, such equipment could replace the need to transport physical samples back to Earth for analysis, but for now it's just a prototype and duplicate samples will be brought back at the end of the mission to compare with the transmitted data. Algol Mars then arrived at its destination and successfully captured into orbit. Algol Mars' orbit was deliberately left more eccentric to gather data from a wider range of altitudes. By coincidence, it's also going in the opposite direction to Canopus Mars, just like their siblings over at Venus, which might make things a bit more complicated when planning the lander deployment. Despite the additional space offered by the lab module, the fact that they had to put on their EVA suits and depressurise both sections before they could move between them was proving increasingly wearing on Lynda and Rene. Neither module was all that spacious either and after two weeks they were getting short-tempered and irritable with each other and controllers on the ground. The final test of the Penguin Mk2 was to boost itself and the lab module up to a very high apoapsis, simulating a lunar capture burn, before undocking from the lab and commanding it to deorbit itself with its RCS. With that done, Lynda had the chance to perform the first EVA in "deep space" at over 100Mm altitude. The new heatshields worked as expected* and after enduring a re-entry velocity of close to 10km/s the capsule splashed down safely in the Pacific to the east of Australia. Data comparison between the samples returned and the data generated by the science module's lab is ongoing and has resulted in some changes to the planned "space station" due to launch by the end of the year. With OrbLab 1 nearing completion, there was just time for a course correction by Algol Ceres to set up its encounter with the largest body in the asteroid belt, with enough propellant left over to capture into orbit- assuming the anti-degradation systems do their job for the remainder of the flight and the HTP doesn't decay. And now it's time to launch OrbLab 1. It was decided to launch it into a 55 degree inclination orbit to ensure regular flyovers of Europe, allowing all those who have funded EuROSTAR's successes (through their taxes or the various "your name on the rocket/lander/flag/etc." fundraisers over the last few years) to see the station fly overhead in the night sky The fact that this also means it'll fly over many major cities and interesting places in the USA and USSR is entirely coincidence, and the fact that it's carrying photographic equipment to take pictures of terrain and weather features on the surface below is entirely scientific. A short time later Olga and Damien launch aboard Penguin 5 to visit the station. The crew will still have to EVA to get over to the station, however it's much roomier than any previous spacecraft and even has wall-mounted sleeping bags and a prototype space toilet. The rendezvous was uneventful, with the exception of a nice sunrise as they were moving in to dock: The initial plan is for a 30 day stay, however OrbLab 1 is provisioned for up to 120 days of occupation by a crew of two and has a second docking port available to allow a supply craft to dock while the crew are present. The crew will be putting it through its paces for a few months, which means Lynda and Rene will be flying the first mission to the Moon. Beginning what's become known as Moonflight 0 is the launch of the Blitzar booster stage. The first launch just after the start of 1966 was scrubbed after a booster engine failed to ignite due to a sensor issue, forcing a rollback and some sensor replacement before launching on the second time of asking; the second launch also had engine trouble, this time on the second stage as one of the HM-7s failed to ignite, but the other four engines were able to burn for longer to make up for the failure and Blitzar 1 made it to its target orbit. Two more launches will be required: a Quasar tanker to fill up the Blitzar's fuel tanks, since it's too heavy to be launched fully fuelled, and the capsule and lander which will launch together. A second Quasar tanker will be on standby for the duration of the mission in case the Penguin Mk2's engine fails, at which point the Quasar tanker will fly itself out to the Moon and serve as a booster to push the crew back to Earth. Will 1966 be the year we see European boots on the Moon? -
A Very Basic Space Program | RSS/RO/RP-1
jimmymcgoochie replied to seyMonsters's topic in KSP Fan Works
Trying to balance on a hill by putting the magnetometer UP the hill will never work, the mass is all in the base and not the boom; put it DOWN the hill so it props it up. -
EuROSTAR: Europe's Space Program (RSS/RO/RP-1)
jimmymcgoochie replied to jimmymcgoochie's topic in KSP1 Mission Reports
It's time for Canopus Venus to deploy its atmosphere probe. Venus will still get in the way so the Canopus orbiter won't be able to relay the signal from the atmo-probe/lander, but adjusting Algol Venus' orbit using most of its remaining propellant would allow it to act as a relay instead. The timing had to be just right so Algol Venus was in position overhead. This proved trickier than initially thought as the two spacecraft were actually orbiting in a roughly similar plane but in opposite directions. The probe hurtled into the atmosphere at just under 8km/s, racing across the terminator which bathed the clouds in eerie blue light. Venus' atmosphere is a lot harsher than Earth's: at 100km Earth's atmosphere is barely noticeable, but at the same altitude on Venus the probe was pulling over 10 gees as it decelerated hard, coming to a near halt horizontally while it was still above 65km altitude and beginning a long, slow fall to the clouds below. The parachute was designed to be resilient to both temperature and aerodynamic forces, but the magnitude of both was too much for it to bear and it was torn to shreds when it deployed. The heatshield then crumpled on impact which cushioned the probe itself from what would have been terminal damage. The science experiments had been recording everything they could from the moment the probe separated from its orbiter and they painted a vivid picture of the conditions under the clouds of Earth's nearest neighbour. Hopes of finding a lush jungle planet, already shaken by the orbital data, were dashed for good: Venus was no tropical paradise, but a horrid nightmare of blistering heat, immense pressure and at least one layer of cloud that seemed to be made of pure sulphuric acid. The probe survived for just over two hours before succumbing to the inevitable, well before its batteries ran out but just long enough to transmit the critical data. It was, however, the first probe to enter another planet's atmosphere and land intact on its surface, yet again cementing Europe's lead in the Space Race. Somewhat less impressive was the discovery that a mistake in the blueprints for the Rigel lunar lander had resulted in the magnetometer being attached incorrectly. Instead of being bolted to the base of the lander, the magnetometer was instead bolted to the top of the decoupler underneath it and so was detached with the upper stage instead of staying with the lander down to the surface. An internal investigation has been opened to find out a) who's responsible for this blunder and b) why nobody spotted the mistake before two Rigels flew with their magnetometers incorrectly attached. In the meantime, Rigel 3 performed its descent and landed near the lunar north pole on the near side. The return stage had been redesigned slightly from previous Rigel missions, using smaller and lighter thrusters in an attempt to improve the tight delta-V margins. This ended up backfiring completely as the new thrusters were less powerful than the previous design and also had no gimbals or thrust vanes for steering and the use of near-constant RCS thrust to maintain control combined with the less efficient ascent trajectory caused by a lack of thrust more than made up for any small gains from the lighter thrusters. Rigel 3's return stage was running on fumes by the time its return trajectory was finalised, even more so than Rigel 1, but it still managed to return the capsule and its precious sample to splash down in the Pacific where a Royal Navy destroyer was waiting to collect it. Preparations are now well underway ahead of the planned missions that will lead up to a crewed Moon landing: a test of the new Penguin Mk2 in low Earth orbit, then a full dress rehearsal of the landing using the Penguin Mk2, the Europa lander, the Blitzar TLI booster and a Quasar-based refuel tanker, and finally the landing itself. -
I started a new RP-1 run, got a year in on the first day and the very next day a big update changed the starting conditions so I started again,
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EuROSTAR: Europe's Space Program (RSS/RO/RP-1)
jimmymcgoochie replied to jimmymcgoochie's topic in KSP1 Mission Reports
Time to plan some lunar missions, starting with the lander. It will need to pack a sizeable fuel reserve to land and return to orbit plus any orbital manoeuvring, yet have enough finesse to make a controlled landing. The best engine for the job is the RZ.20 with its high ISP and ability to repeatedly relight, however it lacks the fine control necessary for a gentle touchdown; that problem could be solved by adding some partially throttleable hypergolic thrusters similar to those used on the Rigel landers, which have the versatility for a landing but not the efficiency for the descent and ascent. A mockup was created and tested mathematically using data from previous missions including Rigels and Quasars. The results were promising- healthy delta-V margins were predicted, while a heavy reliance on tried and tested hardware (the lander's fuel tanks and engine were heavily based on the Quasar) should mean relatively few complications will arise during the final design and construction phases. Now that engineers have a good idea of what the lander will look like, they can focus on getting it to the Moon along with the capsule that will transport the crew there and back again. A single launch mission was ruled out due to the time and cost required to build a huge new launchpad and associated infrastructure for the huge rocket it would require, while lunar orbit rendezvous would require two Constellation launches with at least a two week delay between them, making the rendezvous more difficult. Ultimately the mission planners settled on an Earth orbit rendezvous mission in three launches: first a large trans-lunar booster would launch into LEO on a Constellation- only partly fuelled due to mass constraints- followed by a top-up tanker based on the Quasar and launched on a Kronos to fill up the tanks, and then the combined Penguin-based capsule and lander would launch together on a second Constellation and join with the booster to be flung at the Moon. Re-using existing rockets and designs as much as possible and performing critical rendezvouses while still in low Earth orbit would minimise risk and allow an abort at more stages of the mission, while the Quasar tanker would also have the delta-V to launch itself to lunar orbit as a backup Earth return stage in case of engine failure on the capsule. While the lunar plans were taking shape, back on Earth it was time for science specialist Rene Sørenson to have his first orbital flight with veteran pilot Damien O'Reilly commanding Penguin 3's mission. The crew had a series of experiments to run for their week-long mission and there was even time to give Rene a taste of EVA action. The re-entry was targeted for Woomera and ended up less than twenty kilometres away, not a bad result after re-entering from an apoapsis of almost 1000km! The next mission to launch was Algol Ceres, intended to make the first visit to the largest body in the asteroid belt a permanent one by capturing into orbit and studying it in great detail. Everything was going so well... ...until it wasn't: Double engine failures on the HM-7 and Larch-1 killed the mission completely, leaving it drifting aimlessly out of Earth's gravity well. A hasty meeting was convened to make a decision: Algol Vesta was already built and the Vesta window was two months away, but if launched as soon as possible it might be able to visit Ceres instead, with a replacement able to be built just in time for the Vesta window. The next transfer windows for Ceres and Vesta are quite different- the Ceres window is a lot less favourable while the next Vesta window will be a lot better, so the decision was made to launch Algol Vesta to Ceres instead. A quick bit of spray-painting later... No engine failures this time! A course correction will be required in solar orbit but the mission is looking good so far. Lunar mission plans are almost finalised and key technologies are being prepared- improved MLI to further reduce hydrogen boiloff and an upgrade to the RZ.20 with an increased expansion ration to increase vacuum ISP- with an initial Earth orbit test flight of the Penguin Mk2 capsule planned with a science module of a similar mass to the lander. -
Yes. When exactly, I can't say, but it's a when rather than an if.
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I don’t see any need to show every repeated sounding rocket launch, at least not at normal speed with commentary- a short speedy-uppy montage would suffice. Completely disagree on the bio/film capsule thing though, getting maximum science from each launch should be the top priority regardless of contracts.
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A Very Basic Space Program | RSS/RO/RP-1
jimmymcgoochie replied to seyMonsters's topic in KSP Fan Works
Fun fact, the signal strength meter shows data speed in bits per second (bps), but Kerbalism shows data speed in bytes per second (B/s) and since there are 8 bits in a byte your 80kbps signal to the lunar relay would be at best 10kB/s, nowhere near the ~30kB/s required for that orbital imaging experiment. What you’re seeing is a relatively low-speed S-band signal bouncing off the lunar relay which isn’t going to have the bandwidth to send all that data. Dedicated S-, X- or K/Ka-band relays in medium Earth orbit are required to get the data transmitted. That rover was never going to land like that- maybe if you had deployed the ramps to act as airbrakes and tried to use a lifting re-entry to slow down more before you got too low it might have worked, or if you had drogue chutes to slow it subsonic before the main chutes deployed. -
EuROSTAR: Europe's Space Program (RSS/RO/RP-1)
jimmymcgoochie replied to jimmymcgoochie's topic in KSP1 Mission Reports
Rigel 2's landing had a couple of complications. One, it was supposed to be landing on one of the lunar Mare but instead found itself flying towards a series of hills. And two, the magnetometer fell off. The landing systems managed to compensate for these problems and a safe landing ensued on the far side of the Moon. The lander spent about an hour on the surface gathering data and that all-important surface sample before the return stage launched. A slightly more favourable landing site latitude meant a slightly more favourable return window, leaving a bit of extra fuel to fine-tune where the return capsule would re-enter the atmosphere. (It helped a lot that the return trajectory was going to be close to Australia anyway.) The next launch sent rookie astronaut Lynda Wilson into space for the first time, along with veteran Olga Martín. Penguin 2 has a series of longer-duration experiments for the crew, including some tests for engineer Lynda to perform using power tools to evaluate their utility in microgravity. After a week in orbit running experiments, Penguin 2 headed over to the docking target probe launched earlier and completed a textbook docking. As in, this docking will become the textbook example for all future flights since nobody has ever docked a crewed spacecraft to anything before. They remained in orbit for a few more days, beating duration and altitude records, before returning. They were supposed to perform EVAs, but Lynda suffered several bouts of spacesickness that put that plan on hold until her next flight on Penguin 4. (The orbital flight contract got confused by the docking and didn't complete because it insisted the vessel wasn't crewed when it clearly was.) And another Quasar launch to GEO for commercial profit. In a somewhat unusual development, a team had been looking at the feasibility of recovering used boosters for re-use, potentially reducing the cost of each launch by a sizeable margin. The best option they could think of involved adding wings and jet engines to the Kronos' first stage to allow it to fly back to Woomera after separation, however they couldn't quite get it to work as well as they'd hoped: the wings, jets and fuel added too much weight and adversely affected its performance as a rocket, while the heavy engines at the rear and unaerodynamic nose made its predicted flight performance marginal at best. Still, it looked pretty good in the sketches! They went as far as building a scale model and dropping it from a plane, but it flew just as badly as expected and crashed in the desert. The Constellation's twin side-mounted boosters preclude the addition of wings, since there would be too much risk of them colliding during separation, and smaller rockets just don't have the mass budget to add wings and jets and are both cheap enough and used rarely enough for it not to matter, so this idea will be put on hold for now. It's now February 1965, half way into the "five years to the Moon" period. On one hand, things are going well: multi-crew missions are ongoing, orbital rendezvous and docking have been demonstrated and the Rigel missions have shown that landing on the Moon and coming back is possible and that the heatshields can take the heat; but on the other, there's still no concrete plan for how to get the crew out to the Moon, to the surface, or back to Earth again. -
Sorry to burst your bubble so early, but you can only do one early satellites program, they’re mutually exclusive. You should be launching film cameras and biological samples on the same rockets, regardless of contracts!
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EuROSTAR: Europe's Space Program (RSS/RO/RP-1)
jimmymcgoochie replied to jimmymcgoochie's topic in KSP1 Mission Reports
Obligatory Quasar GEO commercial sat launch to start, it's the same old same old so I'll skip to the contracts completing from now on. A few weeks of timewarping later and I remembered that the Moon is tidally locked so Rigel 1 will never be in a good position to launch. No time like the present, then: (It only occurred to me much later on that while the launch could be whenever, the resulting orbit would probably produce a more favourable return opportunity if I waited long enough.) The orbital misalignment resulted in a more difficult return burn which meant there was no fuel left to try and fine-tune where the return capsule would land when it got back to Earth- hopefully it'll land somewhere that the CIA or KGB can't get their hands on it! The capsule touched down in western Mexico and the recovery team had already flown in to be ready to move in as soon as its parachute opened. It took less than an hour for the capsule to be located and loaded onto a truck to be driven to the nearest airfield to be flown back to Australia and the team left Mexico with a token fine for littering, since the capsule had landed in a nature reserve. Once returned to Woomera, the capsule was carefully opened and its payload extracted and divided up to be sent out to all the various universities etc. who had managed to secure a precious gram or two of genuine Moon dust. EuROSTAR's on-site research facilities kept some for themselves, of course, but they were more interested in studying the capsule and its heatshield to find out how they had fared during the month-long mission. Demand for lunar samples vastly outstripped the supply, but those who hadn't been picked in the first lottery selection (chosen to avoid any accusations of favouritism) would automatically be entered into the next one when the next Rigel mission was launched. With the proof of concept completed, minor upgrades were made to the design- additional science instruments on the lander and directional solar panels to replace the side-mounted ones on the return stage, which proved to be only marginally able to keep the batteries charged. A month later the Mars transfer window was open and, just like the Venus window before it, a Canopus orbiter/lander and an Algol orbiter were ready to depart. Canopus Mars launched first, mostly because it took longer to prepare it for launch and so Algol Mars could follow it more quickly in the limited time before the transfer window became much less friendly. One of the four Vega-3 engines on the second stage failed to ignite, however the other three were able to compensate for the imbalanced thrust and burned for longer to make up the delta-V and the mission wasn't compromised. The probe departed for Mars and settled in for the long trip to the Red Planet. Algol Mars followed suit less than two weeks later with no engine problems but a slightly less favourable transfer that will result in a slightly longer trip to Mars because that's just how the transfer window lined up. Rocket watchers were then treated to something unexpected: the first, and possibly only, launch of a Goliath Mk5- RZ.3 first stage, Larch-2 second stage- carrying a small docking target probe for the upcoming Penguin 2 mission. The Nova Docker probe was positioned in a 250km circular orbit to await the crew's launch in a couple of months. Next to launch was Rigel 2, now with more science! The twin objectives are to land on the far side and return a sample to Earth, but the far side is mostly in darkness right now so it'll have to wait a while before landing. Unlike Rigel 1, Rigel 2 is in a prograde orbit aligned with the Moon's orbital plane and so shouldn't encounter the same alignment problems that Rigel 1 had when it's time to come home. Another launch of a Quasar to geostationary orbit, but this is no ordinary Quasar: Quasar Quad-Net is carrying four smaller relay satellites to form a geostationary network that will help to cover some signal gaps in low Earth orbit, with some additional profit from selling access to commercial operators and other space agencies. The Quasar stage boosted the four relays into a 3:4 resonant orbit so each satellite could circularise into a geostationary orbit on subsequent orbits. Once in position, the orbital periods of the satellites were carefully adjusted so that they would stay in place with minimal additional effort. A few days of calibration later and the network was officially switched on. As part of the big push to the Moon, longer duration missions will be required to find out if a crew can actually function in space for long enough to perform a lunar landing, and if they'll be healthy enough to come back again without their bones turning to jelly on re-entry. To that end, EuROSTAR has committed to launching a vessel into Earth orbit that can be visited by Penguin crews for longer periods of time- first one month, then two or three- although there's a fairly big argument going on about what exactly to call this vessel: space station, orbital harbour, astronaut hotel? -
Why not make the tanks on the Atlatl bio return 1m wide? That would make the toolings much cheaper since there’s significant shared cost between normal and HP tanks of the same type (e.g. steel fuselage) if you tool similar sizes. And why not put bio sample capsules on those Dart return rockets to get a bit of free science? You could be building twice as many Darts and alternating between bio samples and sounding payload for contracts to get double the data units on the engines and extra science, and still timing the contracts nicely. (Update- and put a mass spectrometer on it too to get flying high and space low science from that.) The pink engine symbol at the 25 minute mark is because it has no ignitions left.
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A Very Basic Space Program | RSS/RO/RP-1
jimmymcgoochie replied to seyMonsters's topic in KSP Fan Works
That was a completely legitimate cheat-complete, those contracts are pretty glitchy- I once had a Moon base contract fail because it decided my Moon station was the “base” and wanted me to land that instead- and you did everything it asked you to do. Scatterer/EVE disappearing isn’t uncommon either, I’ve had it happen lots of times but a quick save/reload often fixes it. -
EuROSTAR: Europe's Space Program (RSS/RO/RP-1)
jimmymcgoochie replied to jimmymcgoochie's topic in KSP1 Mission Reports
The Princess might be quite old and largely superseded by the Empress, but there are still some missions where it's the best rocket for the job. One of these missions is the new SuperAster, intended as both a test of a new heatshield designed to survive a re-entry from a direct lunar return and to see what effects said return would have on a large mammal ahead of sending humans out there. The launch sent the capsule and Nigel the macaque on a two day long trip once around the Earth, reaching over 120,000km altitude yet with its periapsis firmly inside the atmosphere so it would return to the ground and land close to Woomera again. The mission was a complete success: the heatshield handled the heat without any problems and Nigel suffered no ill effects of his trip to deep space or the rather harsh re-entry conditions- he was trained to sit in a little padded chair which ensured he wasn't harmed by the G-forces. With the heatshield now flight-proven as much as it can be without actually going to the Moon and back, the next launch was a big one: the first Rigel lunar lander was designed to land on the Moon, scrape up a sample of the surface material and then bring it back to Earth in a small return capsule. The first launch attempt was scrubbed after a booster engine failed to start due to parameters that were ever so slightly outside the maximum tolerances. (0.03% above failure, TestFlight? Not cool!) The rocket was rolled back for a full engine inspection, during which time Canopus Venus arrived and prepared for its capture burn. The mitigation systems had done their jobs and the HTP decomposition rate was negligible, an encouraging sign for future missions to other planets that could also use Larch-powered capture stages. The initial capture burn produced a fairly loose orbit, with ample fuel reserves to bring the apoapsis lower ahead of lander deployment. Confirmation of the orbit made news headlines around the world- the first time that a manmade object had orbited another planet. Barely a week later, Rigel 1 grabbed more headlines when it landed on the far side of the Moon after a flawless launch and transfer. A problem with the guidance system on the lander nearly spelt disaster late in the descent, causing the lander to start flying back the way it had come before the fault- caused by flying low over a hilltop and then towards lower lying terrain- was corrected by Mission Control via the Solaris relay network, working exactly as designed. The announcement of the far side landing also came with the revelation that Rigel 1 intended to return to Earth with a small amount of lunar material- only a few tens of grams from the top layers of the surface, maybe, but the EuROSTAR switchboards were soon jammed with calls from thousands of universities and research institutes all clamouring for even the tiniest sliver of Moon to study. The lander's two-part design also meant that the base would remain on the surface with its own scientific equipment, transmitter and solar panels to continue studying the landing site after the return stage had been deployed, though some damage due to engine exhaust was expected and would provide some valuable data of its own on solar panel damage and degradation by rocket exhaust and lunar dust. The furore was still going on as Algol Venus arrived, braking into orbit a month after Canopus Venus and positioning itself to gather as much scientific data as possible and to act as a backup relay for the atmospheric probe/lander when it was deployed. The positions of the planets and the spacecrafts' orbits weren't particularly conducive for that though, with Venus getting in the way of a signal in the projected landing zone. A more favourable alignment should occur in a few months, though with the caveat that the planets will be further apart by then and so the signal strength would probably be weaker and data transfer rates correspondingly slower. Rigel 1's guidance issue has resulted in a landing site that's further south than initially planned, meaning it'll launch into an inclined orbit that doesn't align with the Moon's orbit of Earth and increasing the delta-V cost of returning it- potentially beyond the delta-V it actually has. Even as the phones are ringing off their hooks from people wanting some of that lunar sample, mission planners and engineers are working feverishly to try and find a way to get the sample back to Earth at all. -
Best way to look for Colony Locations in KSP1
jimmymcgoochie replied to stephensmat's topic in KSP1 Discussion
It depends what the base is for: a science base to serve as a hub for surface exploration would be best placed with easy access to as many different biomes as possible, while a mining base needs the maximum abundance of ore you can find. Both will benefit from having flat land around both to serve as a landing site and to enable the base to be assembled more easily on the ground, however some good sites might be more awkward to get to/from due to their location e.g. near the poles, or have terrain around them that limits solar panel exposure- I once put a base on Minmus’ south(?) pole but had to move it because the pole is surrounded by low hills that block the sunlight for much of the time. If you’re using life support mods or mods with more detailed resource chains and mining systems (Kerbalism ticks both boxes) then there are more things to consider- it’s rare to find a good site that has ore and water in the same place and even rarer to get one with metal ore for something like Extraplanetary Launchpads in the same place too. SCANsat is a good mod for scouting base locations, you can get detailed terrain, biome and resource maps all in one place to find the best sites for a base and it can also detect anomalies to investigate- who wouldn’t want a mysterious alien monolith as the centrepiece of their base?