#039 The Story behind the legendary BMW Art Cars | BMW Podcast
Play • 18 mins

They’re colorful, extravagant, and unique. No BMW Art Car is like any other. Not because they differ in age and model shape, but because they’re painted from the hood to the rear. But why did artists like Roy Lichtenstein and Andy Warhol stage BMW models as works of art in the first place? In this episode of "Changing Lanes", the official BMW podcast, we look back on 45 years of art history at BMW. Press play to learn all the facts about these colorful legends. 


03:11: Alexander Calder and the 3.0 CSL

04:29: Frank Stella, Roy Lichtenstein and Andy Warhol

06:43: Ernst Fuchs and the BMW 635 CS1

07:55: Robert Rauschenberg’s photographic techniques

08:45 A.R. Penck and the BMW Z1

10:00 Esther Mahlangu, the first woman in Art Car series

11:39: Jenny Holzer and her critical statements

13:00: Olafur Eliasson’s ice cocoon 

14:35: The augmented reality creation of Cao Fei  


And if you want to read more about BMW Art Cars, go to BMW.com: 

https://www.bmw.com/en/design/history-of-the-bmw-art-cars.html


“Changing Lanes” is the official podcast of BMW. Subscribe for new episodes each week, in which our hosts take you on an exciting journey and talk about innovative technologies, lifestyle, design and more.

IoT For All Podcast
IoT For All Podcast
IoT For All
Utilizing AI for Predictive Maintenance in Manufacturing | Augury’s Saar Yoskovitz
In episode 99 of the IoT For All Podcast, Augury Co-Founder and CEO Saar Yoskovitz joins us to share his experience founding and growing an AI-based Machine Health company. Saar talks about the challenges and benefits of building a full-stack IoT company, what he learned while raising $55m in D-series funding, and some of the greatest challenges involved in implementing AI in IoT solutions. Since co-founding Augury in 2011 Saar has been working with customers and partners to transform how they work to make products, deliver services and improve lives through real-time insight into the health and performance of industrial equipment and systems. Saar holds a dual bachelor's degree in electrical engineering and physics from the Technion, the Israel Institute of Technology. Before launching Augury, Saar worked at Intel as an Analog Architect. Interested in connecting with Saar? Reach out to him on Linkedin! About Augury: Augury works with the largest manufacturing companies, like Colgate, Essity, and Hersheys to make their production lines more reliable and productive. We offer Machine Health-as-a-Service - a full-stack solution from IIoT-enabled sensors to specific outcomes and actionable insights that predict and help prevent unplanned industrial equipment failures and downtime.Key Questions and Topics from this Episode: (00:57) Intro to Saar (03:33) Intro to Augury (05:28) What are some of the benefits and challenges with going full-stack as a solution provider? (12:51) Are there any use cases you can share? (16:34) What’s your view on the current state of the industrial and manufacturing IoT space? What has COVID’s influence been? (22:51) What’re the biggest challenges involved in implementing AI into your solutions for customers? (26:23) What was it like raising funding? What do you feel are the biggest challenges for IoT companies looking to raise funds? (30:27) What are the biggest challenges for companies looking to grow a global presence? Do you have any advice?
38 mins
The History of Computing
The History of Computing
Charles Edge
A Steampunk's Guide To Clockworks: From The Cradle Of Civilization To Electromechanical Computers
We mentioned John Locke in the episode on the Scientific Revolution. And Leibniz. They not only worked in the new branches of science, math, and philosophy, but they put many of their theories to use and were engineers. Computing at the time was mechanical, what we might now think of as clockwork. And clockwork was starting to get some innovative new thinking. As we’ve covered, clockworks go back thousands of years. But with a jump in more and more accurate machining and more science, advances in timekeeping were coming. Locke and Huygens worked on pendulum clocks and then moved to spring driven clocks. Both taught English patents and because they didn’t work that well, neither were granted. But more somethings needed to happen to improve the accuracy of time. Time was becoming increasingly important. Not only to show up to appointments and computing ever increasing math problems but also for navigation. Going back to the Greeks, we’d been estimating our position on the Earth relative to seconds and degrees. And a rapidly growing maritime power like England at the time needed to use clocks to guide ships. Why? The world is a sphere. A sphere has 360 degrees which multiplied by 60 minutes is 21,600. The North South circumference is 21603 nautical miles. Actually the world isn’t a perfect sphere so the circumference around the equator is 21,639 nautical miles. Each nautical mile is 6,076 feet. When traveling by sea, trying to do all that math in feet and inches is terribly difficult and so we came up with 180 lines each of latitude, running east-west and longitude running north-south. That’s 60 nautical miles in each line, or 60 minutes. The distance between each naturally goes down as one gets closer to the poles - and goes down a a percentage relative to the distance to those poles. Problem was that the most accurate time to check your position relative to the sun was at noon or to use the Polaris North Star at night. Much of this went back to the Greeks and further. The Sumerians developed the sexagesimal system, or base 60 and passed it down to the Babylonians in the 3rd millennium BCE and by 2000 BCE gave us the solar year and the sundial. As their empire grew rich with trade and growing cities by 1500 BCE the Egyptians had developed the first water clocks timers, proved by the Karnak water clock, beginning as a controlled amount of water filling up a vessel until it reached marks. Water could be moved - horizontal water wheels were developed as far back as the 4th millennium BCE. Both the sundial and the water clock became more precise in the ensuing centuries, taking location and the time of the year into account. Due to water reacting differently in various climates we also got the sandglass, now referred to as the hourglass. The sundial became common in Greece by the sixth century BCE, as did the water clock, which they called the clepsydra. By then it had a float that would tell the time. Plato even supposedly added a bowl full of balls to his inflow water clock that would dump them on a copper plate as an alarm during the day for his academy. We still use the base 60 scale and the rough solar years from even more ancient times. But every time sixty seconds ticks by something needs to happen to increment a minute and every 60 minutes needs to increment an hour. From the days of Thales in the 600s BCE and earlier, the Greeks had been documenting and studying math and engineering. And inventing. All that gathered knowledge was starting to come together. Ctesibius was potentially the first to head the Library of Alexandria and while there, developed the siphon, force pumps, compressed air, and so the earliest uses of pneumatics. He is accredited for adding a scale and float thus mechanics. And expanding the use to include water powered gearing that produced sound and moved dials with wheels. The Greek engineer Philo of Byzantium in the 240s BCE, if not further back, added an escapement to the water clock. He started by simply applying a counterweight to the end of a spoon and as the spoon filled, a ball was released. He also described a robotic maid who, when Greeks put a cup in her hand, poured wine. Archimedes added the idea that objects displaced water based on their volume but also mathematical understanding of the six simple machines. He then gets credited for being the first to add a gear to a water clock. We now have gears and escapements. Here’s a thought, given their lifetimes overlapping, Philo, Archimedes, and Ctesibius could have all been studying together at the library. Archimedes certainly continued on with earlier designs, adding a chime to the early water clocks. And Archimedes is often credited for providing us with the first transmission gears. The Antikythera device proves the greeks also made use of complex gearing. Transferring energy in more complex gearing patterns. It is hand cranked but shows mathematical and gearing mastery by choosing a day and year and seeing when the next eclipse and olympiad would be. And the Greeks were all to happy to use gearing for other devices, such as an odometer in the first century BCE and to build the Tower of the Winds, an entire building that acted as a detailed and geared water clock as well as perhaps a model of the universe. And we got the astrolabe at the same time, from Apollonius or Hipparchus. But a new empire had risen. The astrolabe was a circle of metal with an arm called an alidade that users sighted to the altitude of a star and based on that, you could get your location. The gearing was simple but the math required to get accurate readings was not. These were analog computers of a sort - you gave them an input and they produced an output. At this point they were mostly used by astronomers and continued to be used by Western philosophers at least until the Byzantines. The sundial, water clocks, and many of these engineering concepts were brought to Rome as the empire expanded, many from Greece. The Roman Vitruvius is credited with taking that horizontal water wheel and flipping it vertical in 14 CE. Around the same time, Augustus Caesar built a large sundial in Campus Martius. The Romans also added a rod to cranks giving us sawmills in the third century. The larger the empire the more time people spent in appointments and the more important time became - but also the more people could notice the impact that automata had. Granted much of it was large, like a windmill at the time, but most technology starts huge and miniaturizes as more precision tooling becomes available to increasingly talented craftspeople and engineers. Marcus Vitruvius Pollio was an architect who wrote 10 books in the 20s BCE about technology. His works link aqueducts to water-driven machinations that could raise water from mines, driven by a man walking on a wheel above ground like a hamster does today but with more meaning. They took works from the Hellenistic era and put them in use on an industrial scale. This allowed them to terraform lands and spring new cities into existence. Sawing timber with mills using water to move saws allowed them to build faster. And grinding flour with mills allowed them to feed more people. Heron of Alexandria would study and invent at the Library of Alexandria, amongst scrolls piled to the ceilings in halls with philosophers and mechanics. The inheritor of so much learning, he developed vending machines, statues that moved, and even a steam engine. If the Greeks and early Roman conquered of Alexandria could figure out how a thing work, they could automate it. Many automations were to prove the divine. Such as water powered counterweights to open doors when priests summoned a god, and blew compressed air through trumpets. He also used a wind mill to power an organ and a programmable cart using a weight to turn a drive axle. He also developed an omen machine, with ropes and pulleys on a gear that caused a bird to sing, the song driven by a sim…
41 mins
David Bombal
David Bombal
David Bombal
#247: David Bombal: Am I too old to get into Cybersecurity?
Apologies for the audio on this video. Neal had a technical issue with his audio, so we had to use a backup. Menu: Am I too old to get into cybersecurity? 0:00 There are 3.5 million jobs: 1:17 Resume review: 2:36 There is a wide range of jobs: 3:41 Examples of jobs in Cybersecurity: 5:30 Change your perspective: 8:48 Take your other skills to your future learning: 10:20 When are you too old? 11:32 Give me the path: 12:45 It's a journey and paths: 16:07 Baseline skills: 19:38 Four domains: 20:44 Mr Robot vs Real World: 24:07 I don't feel worthy: 27:55 I'm too young. I'm too old. 35:58 I walked in the snow barefoot: 37:55 How to keep balance: 40:15 Let me Google that for you: 43:28 Put in the work: 44:49 Take responsibility: 49:00 Neal helps someone who DM'd him: 50:04 Neal's shirt: 51:57 Haters: 52:57 Neal's shirt: www.zerodayclothing.com/ ================ Connect with Neal: ================ LinkedIn: www.linkedin.com/in/nealbridges/ Twitter: twitter.com/ITJunkie Twitch: www.twitch.tv/cyber_insecurity YouTube: www.youtube.com/channel/UCL4J... ================ Connect with me: ================ Discord: discord.com/invite/usKSyzb Twitter: www.twitter.com/davidbombal Instagram: www.instagram.com/davidbombal LinkedIn: www.linkedin.com/in/davidbombal Facebook: www.facebook.com/davidbombal.co TikTok: tiktok.com/@davidbombal YouTube: www.youtube.com/davidbombal ================ Support me: ================ DavidBombal.com: CCNA ($10): bit.ly/yt999ccna Udemy CCNA Course: bit.ly/ccnafor10dollars GNS3 CCNA Course: CCNA ($10): bit.ly/gns3ccna10
55 mins
More episodes
Search
Clear search
Close search
Google apps
Main menu