A New Generation Of Spacecraft Head To The ISS

While many in the industry were at first skeptical of NASA’s goal to put resupply flights to the International Space Station in the hands of commercial operators, the results speak for themselves. Since 2012, the SpaceX Dragon family of spacecraft has been transporting crew and cargo from American soil to the orbiting laboratory, a capability that the space agency had lost with the retirement of the Space Shuttle. Putting these relatively routine missions in the hands of a commercial provider like SpaceX takes some of the logistical and financial burden off of NASA, allowing them to focus on more forward-looking projects.

SpaceX Dragon arriving at the ISS for the first time in 2012.

But as the saying goes, you should never put all of your eggs in one basket. As successful as SpaceX has been, there’s always a chance that some issue could temporarily ground either the Falcon 9 or the Dragon.

While Russia’s Progress and Soyuz vehicles would still be available in an emergency situation, it’s in everyone’s best interest that there be multiple backup vehicles that can bring critical supplies to the Station.

Which is precisely why several new or upgraded spacecraft, designed specifically for performing resupply missions to the ISS and any potential commercial successor, are coming online over the next few years.

In fact, one of them is already flying its first mission, and will likely have arrived at the International Space Station by the time you read this article.

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The Wow! signal represented as "6EQUJ5" with Jerry R. Ehman's handwritten comment.

Listening For The Next Wow! Signal With Low-Cost SDR

As you might expect, the University of Puerto Rico at Arecibo has a fascination with radio signals from space. While doing research into the legendary “Wow! Signal” detected back in 1977, they realized that the burst was so strong that a small DIY radio telescope would be able to pick it up using modern software-defined radio (SDR) technology.

This realization gave birth to the Wow@Home project, an effort to document both the hardware and software necessary to pick up a Wow! class signal from your own backyard. The University reasons that if they can get a bunch of volunteers to build and operate these radio telescopes, the resulting data could help identify the source of the Wow! Signal — which they believe could be the result of some rare astrophysical event and not the product of Little Green Men.

Ultimately, this isn’t much different from many of the SDR-based homebrew radio telescopes we’ve covered over the years — get a dish, hook your RTL-SDR up to it, add in the appropriate filters and amplifiers, and point it to the sky. Technically, you’re now a radio astronomer. Congratulations. In this case, you don’t even have to figure out how to motorize your dish, as they recommend just pointing the antenna at a fixed position and let the rotation of the Earth to the work — a similar trick to how the legendary Arecibo Observatory itself worked.

The tricky part is collecting and analyzing what’s coming out of the receiver, and that’s where the team at Arecibo hope to make the most headway with their Wow@Home software. It also sounds like that’s where the work still needs to be done. The goal is to have a finished product in Python that can be deployed on the Raspberry Pi, which as an added bonus will “generate a live preview of the data in the style of the original Ohio State SETI project printouts.” Sounds cool to us.

If you’re interested in lending a hand, the team says they’re open to contributions from the community — specifically from those with experience RFI shielding, software GUIs, and general software development. We love seeing citizen science, so hopefully this project finds the assistance and the community it needs to flourish.

Thanks to [Mark Stevens] for the tip.

Give Your Band The Music Of The Bands

The way to get into radio, and thence electronics, in the middle years of the last century, was to fire up a shortwave receiver and tune across the bands. In the days when every country worth its salt had a shortwave station, Cold War adversaries boomed propaganda across the airwaves, and even radio amateurs used AM that could be listened to on a consumer radio, a session in front of the dial was sure to turn up a few surprises. It’s a lost world in the 21st century, as the Internet has provided an easier worldwide medium and switch-mode power supplies have created a blanket of noise. The sounds of shortwave are thus no longer well known to anyone but a few enthusiasts, but that hasn’t stopped [gnd buzz] investigating their potential in electronic music.

There’s very little on the air which couldn’t be used in some form by the musician, but the samples are best used as the base for further processing. One example takes a “buzzer” signal and turns it into a bass instrument. The page introduces the different types of things which can be found on the bands, for which with the prevalence of WebSDRs there has never been a lower barrier to entry.

If you’re too young to have scanned the bands, a capable receiver can now be had for surprisingly little.

Radio dial header: Maximilian Schönherr, CC BY-SA 3.0.