Pastor Greg Locke, a prominent pastor who is considered one of the top internet pastors, is facing an investigation by the Southern Poverty Law Center for allegedly creating an "unwelcome environment" for LGBT people.As the New York Post reports, Pastor Locke is accused of "unintentionally fostering hatred, distrust, and discrimination against LGBT people," after a group of Christians gathered in ...
I’ve always wondered about the mortise and lock.
How did they become the standard in lock systems?
How did we make a lock that can’t be easily cracked or removed from a door?
Today, thanks to an unexpected collaborator, we finally have an answer.
In this episode, I’m joined by Matt McDonough, the director of the MIT Lincoln Lab’s new lock, the Mortise.
It’s a machine that’s capable of detecting and recovering keypads, lockpicks, and other keys, and it’s going to be on display at MIT’s Lincoln Lab, which is opening on October 1.
MIT is one of a handful of universities that have built the Mortises.
They’re a completely new kind of lock—not the old, traditional, or complex kind, but one that’s based on a combination of biology and chemistry and physics and computer science.
MIT’s mortise is based on the simplest and most straightforward mechanism ever found, and the lock is the result of years of research, design, and development.
It was created in partnership with MIT’s graduate students and graduate students’ assistants, and by combining the best aspects of both.
The mortise itself consists of a metal plate that holds the key, which has a hinge that allows it to rotate in order to open and close, and an inner ring that allows the lock to rotate around a key.
It also has a spring that can be turned to open the lock, and a slot in the middle that lets it slide in and out of the keypad.
And when the lock’s turned, the plate moves, and when it’s turned it opens the door.
This is a keypunch-and-release mechanism.
MIT has made a lock capable of recovering and unlocking locks, and in the past year or so, it has found many applications for this sort of lock.
We’ll explore these applications in this episode.
For example, MIT has recently developed an app that’s supposed to be used to unlock a lock from the inside.
The lock has a magnetic field that attracts the keypicker and the locksmiths inside it.
MIT and the makers of the lock have developed an algorithm to detect when a key is pressed, and can open the door or close it.
In some cases, the researchers have also created software that detects when the key is released and opens the lock.
This sort of thing can be quite expensive, and some people have said that it can take hours to develop and test.
MIT wants to get this right, so it’s working with a hardware company to create an even simpler and more energy efficient method.
MIT researchers have developed a way to make a new kind and more efficient mechanism to lock a door.
The keypickers themselves are made of aluminum foil, and they’re all made from materials that absorb radiation from the sun.
This prevents the key from being damaged or lost.
MIT hopes to build a magnetic hinge, a magnetically conductive material that will also be able to resist the sun’s radiation.
The hinge will be designed to be very thin and extremely strong, so that it won’t bend or break under sunlight or pressure, and its thickness will make it impervious to the sun, heat, and even rain.
The hinges can also be easily reprogrammed to open or close a door when it detects an intruder.
MIT believes that the hinge will open and lock the door even in cases where the door is not locked, so this hinge will also provide a much simpler and safer way to lock doors than a conventional keypad lock.
MIT also hopes to make this hinge useful for people who want to use the lock without having to change their locks often, and for those who want their lock to be unlocked only when they need it.
The Mortises have been tested in the laboratory at MIT, and I was able to test the hinge with MIT students.
MIT students said that the hinges worked well, but that they were concerned that they might break over time.
MIT, however, says that the engineers have found a way around that problem, and that the team has also designed an alternative hinge that can lock doors more securely.
MIT said that they will also make this hinges for commercial applications.
The MIT researchers are working on a number of other applications for the Mortis, including lockpicking and unlocking doors from outside a building, and building an automatic door opener system.
These hinges are already being tested at MIT.
What’s interesting about the Mortizes is that MIT is using the same kind of magnetic hinge that it used for the locks.
MIT made the hinges in partnership in 2016 with MIT and a company called Avantech, and this is the first time MIT has collaborated on a new hinge.
The other companies that MIT has partnered with on this project are based in China and the Netherlands.
They have different approaches to making the hinges, and MIT has a lot of experience working with them.
I’m not sure if the Mortys will make as many people happy as MIT, but