"Track is nothing but numbers. A good mathematician probably could be a good track coach."
A quote from the head coach of the University of Oregon's track and field program. They've picked some metrics that aren't applicable to sport which force young women to endanger themselves mentally and physically. It turns out to be a way to turn a "fitness goal" into body shaming and performance on the field can suffer. Here's a good piece on the subject. Unfortunately Oregon isn't alone.
Just what needs to be measured and how is it analyzed and interpreted. In this case it's an outdated belief that thin people can run faster and jump higher. It may be true to a point, but going past that point can reduce performance and lead to Relative Energy Deficiency in Sport. Sadly RED-S is common among female athletes - often the result of the athletes and their coaches not being aware of the last few decades of health and fitness in sports research. They may be very good at measuring body fat percentages, but that's barking up the wrong tree.
People, it turns out, are complicated. Traditionally medicine has been based on a biomedical model. Simply speaking you measure something and react (treat medically or create a fitness goal in sports) based on the number and then repeat the steps. For many medical conditions measurements and treatments are coarse enough that it works well enough - it's often all there is.
In the past twenty years there's been a recognition that the mind is involved.The mind and body react together to what we forecast might happen in the near future.1 Sometimes the mental component is small but it's can very large - particularly in competition. To get a handle on the mental side athletes are often asked to keep detailed training diaries on how they feel at various times of the day . A coach looks for changes and tries to adjust the training accordingly. To go deeper here's been explosive growth in the use of sports psychologists in professional and D-I college sports.
There's also been an explosion in wearable fitness devices. They can be great when the simple biomedical model applies. Using them to improve fitness levels works for many people who aren't at peak performance levels. Many paths can result in improved fitness and motivation is extremely important. Professionals find them useful in some areas of training - checking heart rates during aerobics for example, but don't find them terribly useful outside training.
And back to the amateur. You may have the twin goals of weight management and improved fitness. Exercise is almost always great for health and probably worth the price of a wearable if you have motivation issues, but weight management is poorly dependent on exercise. A device may tell you how many Calories of kilojoules you've used during a session, but sadly it's incorrect to assume that's tied to how much you eat. Metabolism is very complex and the body and mind adjust it to match new conditions. So you lose weight at first, but then it comes back even though you're exercising and eating the same. There are good evolutionary reasons for this that we've abundanced our way out of.
Assume you have a device that can measure a few metrics that are well-understood. How the information is used can be tricky. We're seeing a lot of amateur mistakes with date analysis in the pandemic - and often by people who should know better. It's common in fitness training and undoubtedly in many fields. My friend Greg Blonder put together two pieces of information that presented together are misleading.
You plot the amount of ketchup on the horizontal axis, and Tastiness on the vertical.
A hamburger is very desirable with a little ketchup, ever more so slathered. Liver is highly detested, but LOTS of ketchup helps. So more ketchup is better for either meal, but worse overall. The undesirability of liver skews the results when you aggregate data.
__________
1 In the literature the mind-body models are sometimes called anticipatory regulation or predictive processing. Journalist Mike Finch and sports scientists Ross Tucker and John Kiely talk about this and a few other training issues associated with elite sport in episode 26 Tucker's The Real Science of Sport podcast. If you have any interest in sports science this is one of the best podcasts around.
Now it's posh, but London's Soho district was a rather unfortunate place in the mid 19th century. The region was experiencing dramatic growth, but it didn't connect to London's sewer system. Residences crammed in with slaughter houses and rendering plants overloaded a primitive sewer system that was unable to serve everyone. Cesspools ran over and untreated waste flowed directly into the Thames. This was taking place during a worldwide pandemic. London had seen outbreaks before, but the 1854 outbreak on Broad Street changed the course of history.
John Snow is famous for mapping out cholera deaths in the area and noting a cluster served by a water pump on Broad Street. The pump drew water from a well that was contaminated by human and animal sewage. The Broad Street pump was removed from service, but didn't make much of a dent in the three or four thousand cholera deaths in London. What made a difference was what he did next. - an analysis of deaths in regions served by water pumped from the Thames. He set up a double blind experiment and showed cholera was carried by an agent in the water rather than the dominate theory that it was "bad air" (miasma). It was the beginning of scientific epidemiology and modern public health.
There's a pub named in his honor near the location of the pump that started his line of reasoning.
Over the last year and a half we've been learning just how important public health is. It seems odd to unquestionaingly spend so much on a war industry when a pandemic mixed with politics and a fear of science has prove more lethal than war. That aside we're learning fresh air is critical with airborne spread diseases. During an outbreak that means masks universally worn as a first and final line of defense and frequent air changes. With the delta variant of SARS-CoV-2 it looks like you need at least fifteen air changes an hour to qualify as safe with minimal masking. Outside of clean rooms and operating theaters that's a tall order indoors. We can get part of the way there with in-room air cleaners, upgraded HVAC systems and opening windows when you can. I've been spending some time doing this to learn a bit and have come to the conclusion that, although effective, it's sort of a piano wire and chewing gum approach. Real fixes require an architectural design approach informed by science to create new spaces as well as retrofit existing ones. Very few people do the science and much needs to be done. New technologies probably need to be developed and there needs to be a better understanding of what can be done with what exists..
Creating clean spaces goes well beyond the current pandemic. Clean indoor rooms can have an impact on the flu plus there are a number of chemicals that outgas that we mostly ignore. And many of us have had to deal with PM 2.5 pollution from forest fires and combustion. The question is how do you make this desirable enough that we learn how to make and implement better designs than we have? How do you spark a revolution in public health that involves architecture design and retrofit on a massive scale?
Unfortunately successful public health measures are often seen as expensive overkill. Perhaps carbon dioxide concentration is the answer. Over the years studies have shown decreases in cognitive functions and alertness linked to higher CO2 concentrations.1 Generally 1000 parts per million is seen as a boundary, but some studies show decreased mental ability around 800 ppm. Many offices and schools regularly exceed 1000 when occupied. Your car is probably several thousand in a half hour if you aren't bringing in outside air. How much would a school spend to upgrade the mental ability of its students? Would a company pay extra for more alert workers who function at higher cognitive levels and get sick less often? And what about homes? Many homes are worse than offices - maybe working from home should be rethought or at least certified.
_________
1 A fairly recent study on cognitive function associated with CO2 and VOC exposure
Apple introduced two new laptops this week. Fourteen and sixteen inch versions of the MacBook Pro. On the surface they show a company responding to a certain class of users who value functionality over style. A serious reversal from the days when Jony Ive dictated a minimalist approach. Very nice laptops that happen to be extremely powerful. As fast as the most powerful Intel laptops with a much lower power consumption. It is likely these will run quietly most of the time - useful on video calls. And while Intel has been almost stalled on increasing performance, Apples M chip series is only beginning its ramp.
I'm not a historian, but here's a rough sketch.
The Motorola 6502 was simple chip that retailed for about $25 in the mid 1970s. The price made it popular with hobbyists. Steve Wozniak used it in the Apple I and the commercially successful Apple II. This started down on a long relationship with Motorola. Beginning in the 80s Intel supplied the x86 chips used in IBM compatible PCs. During the 80s Apple had moved to Motorola's 68x processors. By the late 80s Motorola was falling behind. Apple was in the unenviable position of being tied to a substandard processor. Some in the company wanted to design their own processor, but Apple lacked the necessary resources. Instead they turned to IBM which made fantastic silicon and was working on a reduced instruction set processor family (RISC) known as the PowerPC (PPC)
I won't go into the RISC vs CISC wars of the 80s and 90s (CISC is complex instruction set) other than mentioning there were two competing processor architectures. Intel's x86 and the Motorola 68x family were both CISC. Apple was internally interested in the higher compute power per watt performance with possible with RISC. Interested enough that they became part of a joint venture that changed the history of technology.
ARM was originally the Acorn RISC Machine - an English home computer the BBC was pushing. Apple was the majority holder of a joint venture between Acorn, Apple and a chip maker called VLSI technology. The company was headquartered in Cambridge, England and took the then novel approach of licensing their design rather than making chips. To say this was successful is understatement. Apple used ARM chips in the Apple Newton. It was a failure and taken off the market when Steve Jobs returned to Apple, but the desire to have their own processor was there and a few changes forced by the market made it possible in the longer term.
Apple introduced their first Power PC machine with an IBM processor in 1994. It was fine as long as it was running software designed for the chip. The problem was most software companies were more interested in supporting the fast growing Wintel platform. Attempted to keep some market, Apple created an emulator that made the PPC act like it was a 68x processor. It was a beautiful piece of software, but 68x programs ran slower on the PPC machines than on three year old 68x based machines. Apple stayed alive, but nearly went out of business. Then Steve Jobs returned with a much better operating system and - well - himself.
By the early 2000s Apple emerged with some great industrial design and a growing number of PPC native programs. Then came a tiny RISC machine called the iPod that only played music. It gave them experience with integrated hardware, software and a service. It may have also marked a point where Apple came out with something not only surprising, but cool. But IBM was failing to keep the PPC relevant. Apple needed to jump. This time the only choice was going back to the CISC x86 Intel processors. Mac OSX, Apple's Unix based operating system, had been running on Intel chips for several years. The software was improving quickly, but getting important developers write native applications was difficult. Once again Apple built an emulator. This time they had some internal experience with the process. It was called Rosetta. PPC instructions were converted to x86 instructions.. It wasn't perfect, but was efficient and good enough that the platform was growing again. Growing enough to convince developers to write native software. And Apple was giving them the software creation tools to do it.
The pain of two major shifts and some interesting new products on the drawing board. They needed their own silicon. They purchased a small silicon design company and built it in the US and Israel. It took years, but over time the results have been remarkable Systems on chips for the iPhone, iPad, AirPods, HomePods, the Apple Watch, and a variety of small support computers used in other devices like a pencil and a keyboard display. All of these run versions of MacOS, use the same development tools, and many are integrated into similar services.
About five years ago Intel began to run out of steam. Apple was working on its third huge transition for PC class machines. This time going from Intel x86 to their own M series ARM (RISC) based chips. The first laptop was introduced last year. The M1 was basically an iPad chip in a laptop. The operating system and a lot of Apple and third party software runs brilliantly on it. The emulator runs native x86 programs about as fast as they ran on Apple's x86 laptops.
That brings us to the announcement a few days ago - the M1 Max and M1 Max Pro. (scroll down a bit for the chips) Both use the same ARM based design The larger Pro chip and has 57 billion transistors while the original 1985 ARM1 chip had just 25,000 transistors. The ARM1 was made with 3 micron process (very roughly the distance between lines and spaces in the lithography) - that's 3,000 nanometers. The M1 Max Pro uses a 5 nanometer process.
Here's a relative size comparison. ARM1 in red M1 Max Pro in blue. (A real M1 is about 20mm wide and the ARM1 is about 7mm) Look closely between the two and you may see a red one pixel dot. That's how big the ARM1 would be if it was made with the same process used in the newer chip.
A feature of putting so much on a single chip is subcomponents can be directly connected on silicon. It offers greater performance and is more power efficient than putting data on a bus and shipping it around from chip to chip and then back again. Such integration is very difficult if you're selling a general purpose chip. Phone and PC makers need to differentiate their product and that usually means doing it with a mixture of chips and the software that binds them. Apple doesn't suffer that restriction. And, until Intel's architecture, there appears to be a lot of blue sky for performance improvement. The real competition will probably come from other ARM chips, but Apple has a lead. Here's some very early commentary from Anandtech.
While not many people will buy high-end laptops, they continue to buy the iPhone - arguably one of the most popular consumer products ever made - along with a large supporting infrastructure of apps and services. And they make smart wireless headphones, smart speakers, smart watches, smart pencils and more. All of this is based on the same core hardware and software architecture. As a friend pointed out it's like the same company makes Ferraris, ebikes and everything in between using the same fundamental design philosophy and somehow making it work. Not a perfect analogy as Apple has a much broader range.
A Moore's Law observation. In 1985 the transistor count for all of the computers Apple sold in 1985 was about 25 bilion - less than half the count on a single M1 Max Pro chip.
It's becoming clear that the SARS-CoV-2 virus will be around for a long time. We're probably much closer to the beginning than the end. Hotspots will shift and new variants arise so it makes sense to be ready to mitigate risks as much as possible. Vaccinating the world should be a high priority along with next generation vaccines, better treatments, testing, high quality masks when the risk is high, etc. etc.
Improving local air quality is low hanging fruit. To first order that means high quality masks in hotspots along with fresh air. Room air filtration and circulation can be a powerful tool. As living animals we exhale carbon dioxide. In pristine location, say a mountain top in Hawaii, you can measure the baseline concentration. Air is about 420 ppm (parts per million) carbon dioxide - a bit over 0.04%. Enclosed spaces with people have higher concentrations. You're breathing some of the air from other people. If people are the only source, you can calculate the percent of the total air in the room that's exhaled:
CO2 concentration (ppm) % of total air that is exhaled
420 0%
600 0.5%
800 1.0%
1000 1.5%
2400 5.0%
With these numbers it was believed the risk is low for up to an hour if everyone was wearing a simple cloth mask and one person was infected with the alpha variant with carbon dioxide concentrations as high as 800 ppm. The delta variant changes the threshold. Now the one hour number is about 600 ppm with everyone wearing a surgical mask.1 Of course the probability of an infected person being in the room is low if you're in an area where the infection rate is low.
It would be good to know the concentrations where ever you go: offices, classrooms, stores, theaters, taxis, airplanes etc.2 Consumer grade carbon dioxide meters can be purchased for $100 to $300. If you're really interested I can make a recommendation, but I've only used a few. We'll probably see a rapid improvement as these are going to be essential tools. Japan is requiring them in many public places and school rooms.3 It's important to have an NDIR sensor (basically it's doing spectroscopy with an infrared laser to measure concentration - there are many other techniques, but this is the cheapest with enough accuracy and repeatability). These are accurate to about 50 ppm, so ignore the more exact looking reading and just round up to the next multiple of 50 - if it reads 537 just call it 550. It takes about two minutes to get a stable reading and you'll want one that stores measurements. The model I like talks to an iPhone app which gives you a nice chart of the day. For businesses and schools it's a good way to check if the rooms are getting good airflow. I saw one schoolroom that exceeded 3000 ppm when students were present. It turned out an air return duct was blocked - a thirty minute fix gave the students clean air again.
High carbon dioxide concentrations make people drowsy and sap cognitive abilities. It hasn't been carefully studied, but readings over 1000 ppm can make you drowsy and perhaps a bit feeble minded. One Army study suggests 800 ppm should be a warning level. Half-jokingly I told a superintendent that he could justify the cost of measurement though improved test scores. It turned out that's what sold him. Maybe it's a way to upgrade the collective intellectual capacity of an office. Another benefit is a possible reduction in airborne diseases like the flu.
You can't always open windows and doors to get a solid draft, but HVAC systems can often have their fan settings increased and room vents adjusted. High quality filters can capture viruses along with other particulate like some from a fire. MERV-13 is a sweet spot for price, the ability to snare virus sized particles and not requiring more powerful fans. And you can buy or build portable air cleaners.
The hot ticket for rolling your own is a very simple design known as the Corsi-Rosenthal cube. Here's the public domain diagram we used to build 84 of them for about $5,000 (the cost shown in the drawing doesn't involve much shopping around). We used the cardboard from the shipping boxes the fans came in. The shroud is very important. Square corners disturb the airflow and can drop the unit's efficiency by about a third. A normal sized classroom for 30 to 40 students probably needs two units. Keep them away from walls, doors, and openable windows. The filters will probably last the school year if you turn them off when people aren't in the room. Most of the classrooms are showing readings under 600 ppm with these and the school's HVAC system fans all on high. The boxes make a big difference. Commercial air cleaners with good filters probably make more sense in offices and schools if they want to go long term, but 600 cfpm MERV-13 filters are about $500 and in short supply these days. Like carbon dioxide meters I suspect we'll see some movement on air filter and fan design.
Some learnings:
Duct tape is frustrating!
Schools have mountains of duct tape.
Eighth graders are the perfect people to enlist if you want to build a lot of them. Eighth grade girls if you want them to be semi-presentable.
_________
1 These are rule of thumb numbers based on empirical evidence. But it's complex with many confounding factors.
2 A closed car can be spectacularly high. I sat in my car for fifteen minutes with one other person and recorded 3800 ppm! You can drop this by opening the windows. Opening them diagonally makes a lot of sense for creating airflow. Airliners have good general circulation, but a given row can be bad. A flight is probably much safer than a half hour Uber ride if the driver has the windows up.
3 People are already taking measurements in gyms, restaurants, etc and putting them online with locations and business names. It's ad hoc and not very standardized, but there are over 100 locations in NYC the last time I checked. It makes much more sense for a business to do their air handling homework and post numbers in their establishment as well as their website. Hopefully at some point a respectable aggregator will step in.
diverted imagineering
Sometimes when it was really dark - those clear moonless night where the Milky Way stood out - Brian and I would load the binoculars and telescope into my parent's station wagon and either go East on Highwood Road or North on the Bootlegger Trail past Benton Lake to get away from the town lights. It could be impressively dark. The kind of dark where the ground disappeared. We covered a low powered flashlight with red plastic. Dim red light didn't damage your night vision as much as white light did. But you could do a lot better.
When you're in a very dark place try using your rod-based vision. Give your eyes at least ten minutes to begin to adapt - twenty minutes will be even better. You won't see any colors, but your eyes will be somewhere between one thousand and ten thousands times more sensitive to light. You can navigate with just the light from the Milky Way.
People noted for artistic creativity often do it. Just change something to see what you're working on from a different perspective. Haruki Murakami wrote rough drafts in English and then translated back into his native Japanese. Margaret Atwood likes to change an opening sentence or paragraph to hunt for new perspectives. She uses the example of a change to Little Red Riding Hood where the first sentence becomes: "It was dark inside the wolf." Some writers pin segments of what they're working on to a wall and ponder how the flow changes if you move them around. Some film people use storyboarding in the same way. Artists play with negative space - the space between the physical subjects in their paintings and sculptures. A cute trick some musicians use is to invert music. There are even pianos where the keys are arranged backwards for this kind of play.
Awhile back I taught an intro physics course to non-STEM majors. Hoping to make it a bit more interesting I found examples in sports. I think all of us learned something. At one point we were playing with the idea of what a sport would be like on a different world. Different atmosphere and different gravity and more unusual possibilities like cartoon physics. We found many of our assumptions broke. We came to a more fundamental question - what makes a sport interesting on Earth. Then how could you modify existing sports or invent new ones. Why current rules of sports are what they are? How deeply are they based in physics? It even led to a guest lecture by a neurologist who seemed delighted by the play.
Trying to explain a central concept to someone with your background is both difficult and useful. Wired had a fascinating series of videos on the theme. My thesis advisor required his students to explain their work in a period to high school students. One of the most difficult things I've tried and it completely changed my thinking about teaching.
If you're stuck on a particular problem sometimes it's useful to try something else - perhaps something very different. Problem solving by singing in the shower, running, or doing something else physical is real for some people.
I usually find it's best to change one thing and think about what happens as a result. find it incredibly useful to talk with folks who do very different things - musicians, writers, filmmakers, artists, business people, athletes and so on. Sometimes you get involved in a project that leads to a bit of insight that may seem completely unrelated. Last year I found some thinking on the aerodynamics of spinning volleyballs led to thinking about something curious about neutron stars. Through that interaction I learned a bit about the "chess" of a sport with just two players on a side and that led to some questions for a neurologist.
Finally it's a fundamental part of humor.. So why not end with a bad joke?
A priest, a rabbit and a minister walk into a bar. The priest and minister both order a beer, but the rabbit looks confused. The bartender asks the rabbit "what'll ya have? "The rabbit says "I dunno. I'm only here because of autocorrect."
Posted at 08:57 AM in general comments, play | Permalink | Comments (0)
| Reblog (0)