MENTZ | C++ Algorithm Engineer | ONSITE (Munich) | Full-Time

MENTZ builds software for public transit agencies and authorities. One big part of our portfolio is an intermodal journey planning system - think Google/Apple Maps, but with a strong focus on public transit.

We're looking for a C++ backend dev to join the team working on the public transit router. We are currently in an exciting phase where we're working on the current and next generation of that public transit router simultaneously, so this position combines the possibility of having an immediate impact on a widely used product and working on something brand new.

More details (and a way to apply) are available here: https://en.mentz.net/jobs/c-algorithm-engineer-for-public-tr...

If you have any questions, you can contact us at jobs@recruiting.mentz.net.

As far as I understood the U2F standard, the dongles need a FIDO-issued manufacturer key. Do sites accepting U2F just not check that the corresponding signature is present?

Addendum: See page 14 of the specs overview: https://fidoalliance.org/specs/fido-u2f-overview-v1.0-rd-201...

Any End-to-End encrypted software. Ensuring a self-destruction on the receiving side is impossible.

So now you can punish those annoying click-baits by clicking them and then returning to facebook as fast as possible? Nice. Also, this could be used to "punish" legit links someone does not like...

The better way to punish a link is to click the options drop down menu and select "I don't want to see this."

This is generally where big data helps. Your click is one signal among thousands of impressions / clicks. A single user's clicks shouldn't have a large impact in the aggregate.

I think the argument is that bot-nets can appear to be 1000s of legitimate users and you can use this to undermine competitors.

Encrypted E-Mail is not the problem, there already are packages that install gpg without any hassle. What must be solved is the problem of which keys to trust. The web of trust just doesn't work. Are there any concepts how to solve this with Bitmask?

The key distribution is the actual problem that bitmask try to address (https://leap.se/en/docs/tech/hard-problems), it tries to make transparent the key discovery but keeping it as secure as possible. But this is still a work in progress.

There are more points that are questionable in that article: http://bit.ly/fWCuAV

The counter points don't hold up.

1) The 'core catcher' is the bottom of the containment building. This reactor was built by GE.

There is a diagram of the reactor in Google Books: http://books.google.com/books?id=y20F8Yt6UcMC&pg=PA34...

Not sure if that will make it through the HN editor but its worth a look. Would love to get a scan of that diagram online. In 'flask type' reactors the re-inforced concrete pad under the reactor 'catches' the core (if necessary)

2) Its important to understand that since the reactor is shut down, its only source of heat is the decay products from when it was running, minus the heat they pulled off while running on battery power. Further the engineering design target (one assumes they test to that target) is that if you integrate over all the heat you generate from all the byproducts from a reactor that was running at 'full' and now has all of its control rods inserted, is less than the heat you would need to add to melt the containment vessel (the flask) You won't be able to restart it but you won't have the core melt through the vessel either.

His third point, he doesn't understand that long lived radionuclides aren't aerosols. Which is to say they stay in the containment vessel they don't exit with the steam. The impurities in the ocean water need understanding here but we're not talking a significant long term threat.

Number 4 he missed out on what radiation was measured, what the relative value of that radiation was and the how it won't persist. These are gamma rays that can make other things radioactive.

Anyway, if you have the book (I don't) it apparently describes the reactor in question in some detail.