Thursday, September 30, 2021

The Dual Bumper System

Just some thoughts about automotive safety after seeing an accident. This is not entirely a new idea but it is something that we should be paying more attention to.

Road vehicles are designed with the possibility that a crash may occur. It is presumed that the area of impact will most likely be on the vehicle's bumper, either the front or rear bumper.

If the bumpers of all vehicles were at the same height this is how it would work. Unfortunately that is not the case. 

The height of the bumper varies widely among the vehicles that are on the road, which might be involved in collisions with each other. The vehicle with the lower bumper usually gets the worst of a head-on or rear end collision. 

To make matters worse heavier vehicles are the ones that tend to have higher bumpers. We can see the combined mismatch of both vehicle weight and bumper height when a van or pickup truck collides with a small car.

There would certainly be far fewer automotive fatalities if all bumpers were at the same height. This is because all vehicles are designed to take an impact at the bumper. But this is not really practical.

Why couldn't all vehicles have two bumpers, a high and a low bumper, with all highs and all lows being at the same height on every vehicle? The low bumper would be at the normal height of the bumper on a small car and the high bumper would be at the height of the bumper on a truck, SUV or, pickup.

The vehicle would be designed considering that the main point of impact could be at either the high or the low bumper. This would greatly reduce road fatalities and serious injuries since the worst accidents seem to occur when the bumpers are mismatched and we have never gotten around to establishing a standard height for bumpers.

Events To Come

Just a quick review of upcoming events concerning the fulfillment of Bible prophecies of the "Last Days" as described in the posting on this blog, "The End Of The World As We Know It".

The reign of the Antichrist must come before the War of Armageddon. The Antichrist will be allowed to have effective control over the world for seven years. He will seem to be a brilliant leader that has all of the answers to everything, and the first half of the seven year period will actually be the best time that the world has ever seen.

But it will all be a fantastic, satanic lie and things will begin to fall apart. The second half of the seven-year period will be the worst time that the world has ever seen, or ever will see. Jesus makes it clear in the Gospels that if He did not return to end the Tribulation Period, and establish His Kingdom on earth, that no one would be left alive.

After the Antichrist is unveiled there will be 3 1/2 years of wonderful times. The true Christians will have been taken out of the world, in the event known as the Rapture, and the Antichrist will no doubt have some fantastic explanation of what happened. But the peace and good times will be shattered by the invasion of Israel from the north. The world will have put it's faith in the Antichrist but he will be unable to prevent it. This will begin a time of horrors and the final series of wars of the world.

After the Antichrist has had a total reign of seven years Jesus will Return to end this Tribulation Period and rule over the earth Himself. He will bring with Him the saints that He took out of the world before the Tribulation Period began. The world will then be the godly paradise that it was always intended to be.

Human history, with all of it's tragedies and missteps, as well as this Tribulation Period must be allowed to happen to show that when humans do not follow God, they think they don't need Him but it does not work out very well.

Books To Read

Remember that, if you would like more reading, here are a couple of books.

This is about Investigations:

http://markmeeksideas.blogspot.com/2018/12/investigations.html?m=0 

This is "Thoughts And Observations", on a wide variety of topics:

markmeekeconomics.blogspot.com/2009/07/thoughts-and-observations.html?m=0

Thursday, September 23, 2021

The New Jersey Side Of New York City

Maybe a third of the New York City metropolitan area is actually in New Jersey, and a visit to New York wouldn't be complete without seeing it.

Staten Island looks very different from the rest of New York City. It is one of the five boroughs of New York City and is in New York State, not New Jersey. But in terms of physical geography it is closer to being part of New Jersey. I remember when it's name was Richmond, before the name was changed to Staten Island. This is really the suburbs of the city. It is connected to Brooklyn by the Verrazzano-Narrows Bridge. For visitors from the Buffalo area, Staten Island is like the Tonawanda of New York City.

There are multiple scenes following. To see the scenes, after the first one, you must first click the up arrow, ^, before you can move on to the next scene by clicking the right or forward arrow, >, After clicking the up arrow, you can then hide the previews of successive scenes, if you wish.

https://www.google.com/maps/@40.6059611,-74.1276196,3a,75y,176.47h,90t/data=!3m7!1e1!3m5!1sff-L4OVoFD4E1cAQqa_1Fw!2e0!6s%2F%2Fgeo3.ggpht.com%2Fcbk%3Fpanoid%3Dff-L4OVoFD4E1cAQqa_1Fw%26output%3Dthumbnail%26cb_client%3Dmaps_sv.tactile.gps%26thumb%3D2%26w%3D203%26h%3D100%26yaw%3D176.468%26pitch%3D0%26thumbfov%3D100!7i13312!8i6656

If anything is considered as the symbol of America, it is surely the Statue of Liberty. It was a gift from France. Like Staten Island, the Statue of Liberty is considered as being in New York State, even though it is on an island closer to the shore of New Jersey. Some of the views are looking across at the tall buildings of Manhattan.

https://www.google.com/maps/@40.6898058,-74.0447559,2a,75y,168.83h,90t/data=!3m7!1e1!3m5!1sfKVpA5RlkzmUyHWPYhvfBA!2e0!6s%2F%2Fgeo1.ggpht.com%2Fcbk%3Fpanoid%3DfKVpA5RlkzmUyHWPYhvfBA%26output%3Dthumbnail%26cb_client%3Dmaps_sv.tactile.gps%26thumb%3D2%26w%3D203%26h%3D100%26yaw%3D171.48547%26pitch%3D0%26thumbfov%3D100!7i13312!8i6656

Another island, not far from the Statue of Liberty, is Ellis Island. This is where many millions of immigrants entered the United States, when ship was the primary means of transportation and most immigrants came from Europe. But unlike the Statue of Liberty, most of Ellis Island is in New Jersey. Today it is a museum. I came over by ship when I was a young boy but didn't land here, we landed in Montreal.

https://www.google.com/maps/@40.6991225,-74.0390952,3a,75y,210.1h,90t/data=!3m8!1e1!3m6!1sAF1QipOA8BeIswX4rThYAqqAeQQ7BRVEL62DdqHgq2Wy!2e10!3e11!6shttps:%2F%2Flh5.googleusercontent.com%2Fp%2FAF1QipOA8BeIswX4rThYAqqAeQQ7BRVEL62DdqHgq2Wy%3Dw203-h100-k-no-pi0-ya248.72244-ro-0-fo100!7i8704!8i4352

New Jersey's most concentrated urban area is actually part of the New York City metropolitan area. It was once America's industrial heartland. The following scenes are in the city of Elizabeth.

https://www.google.com/maps/@40.6653117,-74.2145219,3a,75y,173.5h,90t/data=!3m7!1e1!3m5!1sZl2ZOAbbpSCjLxi1TdiQFQ!2e0!6s%2F%2Fgeo3.ggpht.com%2Fcbk%3Fpanoid%3DZl2ZOAbbpSCjLxi1TdiQFQ%26output%3Dthumbnail%26cb_client%3Dmaps_sv.tactile.gps%26thumb%3D2%26w%3D203%26h%3D100%26yaw%3D175.06392%26pitch%3D0%26thumbfov%3D100!7i13312!8i6656

This is Newark, in New Jersey. This is one of the places that led the way in industrializing America. Newark Airport is considered as the third airport of the New York metropolitan area, along with JFK and LaGuardia.

https://www.google.com/maps/@40.7355298,-74.1720978,3a,75y,343.59h,90t/data=!3m5!1e1!3m3!1saQrk43mPnZV_QONNrgvDhQ!2e0!6s%2F%2Fgeo2.ggpht.com%2Fcbk%3Fpanoid%3DaQrk43mPnZV_QONNrgvDhQ%26output%3Dthumbnail%26cb_client%3Dmaps_sv.tactile.gps%26thumb%3D2%26w%3D203%26h%3D100%26yaw%3D347.42084%26pitch%3D0%26thumbfov%3D100

This is Sacred Heart Cathedral in Newark.

https://www.google.com/maps/@40.7556142,-74.1785375,3a,75y,65.95h,90t/data=!3m7!1e1!3m5!1sWsNZj4_Uqg9c5DEx5z68Qw!2e0!6s%2F%2Fgeo1.ggpht.com%2Fcbk%3Fpanoid%3DWsNZj4_Uqg9c5DEx5z68Qw%26output%3Dthumbnail%26cb_client%3Dmaps_sv.tactile.gps%26thumb%3D2%26w%3D203%26h%3D100%26yaw%3D59.4945%26pitch%3D0%26thumbfov%3D100!7i16384!8i8192

Just opposite Lower Manhattan on the New Jersey side is Jersey City. This is it's Historic Downtown. Remember that the very tall buildings are looking across the Hudson River at Manhattan.

https://www.google.com/maps/@40.7242138,-74.0470344,3a,75y,247.41h,90t/data=!3m7!1e1!3m5!1szdvw-0BJnfUOp_PQsZQRiQ!2e0!6s%2F%2Fgeo2.ggpht.com%2Fcbk%3Fpanoid%3Dzdvw-0BJnfUOp_PQsZQRiQ%26output%3Dthumbnail%26cb_client%3Dmaps_sv.tactile.gps%26thumb%3D2%26w%3D203%26h%3D100%26yaw%3D241.23668%26pitch%3D0%26thumbfov%3D100!7i13312!8i6656

Further north, this is West New York, but is on the New Jersey Side.

https://www.google.com/maps/@40.7909111,-74.0069001,3a,75y,234.66h,90t/data=!3m5!1e1!3m3!1s4T7pgh7FrJAryCYqBxhGhw!2e0!6s%2F%2Fgeo3.ggpht.com%2Fcbk%3Fpanoid%3D4T7pgh7FrJAryCYqBxhGhw%26output%3Dthumbnail%26cb_client%3Dmaps_sv.tactile.gps%26thumb%3D2%26w%3D203%26h%3D100%26yaw%3D226.87392%26pitch%3D0%26thumbfov%3D100

Paterson was also one of the most important cities in America's early industrial days.

https://www.google.com/maps/@40.9188039,-74.1704311,3a,75y,86.71h,90t/data=!3m7!1e1!3m5!1sQxJ8PsGjVOwv10_wsu0M6Q!2e0!6s%2F%2Fgeo2.ggpht.com%2Fcbk%3Fpanoid%3DQxJ8PsGjVOwv10_wsu0M6Q%26output%3Dthumbnail%26cb_client%3Dmaps_sv.tactile.gps%26thumb%3D2%26w%3D203%26h%3D100%26yaw%3D85.65239%26pitch%3D0%26thumbfov%3D100!7i16384!8i8192

This suburban neighborhood is in West Orange, New Jersey. The main street, as seen in the first image, is Pleasant Valley Way. This was what the 1967 hit song by the Monkees, "Pleasant Valley Sunday" was about. The song was named for the road through this neighborhood.

https://www.google.com/maps/@40.8052981,-74.262667,3a,75y,118.58h,90t/data=!3m7!1e1!3m5!1seo2QPTWmv6MOok_28ssOqQ!2e0!6s%2F%2Fgeo2.ggpht.com%2Fcbk%3Fpanoid%3Deo2QPTWmv6MOok_28ssOqQ%26output%3Dthumbnail%26cb_client%3Dmaps_sv.tactile.gps%26thumb%3D2%26w%3D203%26h%3D100%26yaw%3D120.13724%26pitch%3D0%26thumbfov%3D100!7i13312!8i6656

The Mark Of Ontario

 It was on this blog that the idea of the fabled "Mark of the Beast", in Bible Prophecy, actually being a phone. See "The End Of The World As We Know It", June 2021.

The Book of Revelation tells us that, in the Last Days of the world, " no one will be able to buy or sell" without it. Now without what we could call the "Mark of Ontario", no one will be able to enter a business establishment. There are vaccine passports in other places too.

The "Mark of Ontario" is not yet the same thing as the "Mark of the Beast", but it is a major step toward it.

The Scale Of Gem Formation

What I want to convey to readers is that there are so many things that no one has ever pointed out. An ideal example is the scale of gem formation. Gems that refract light, such as diamonds and rubies, are found only up to a very limited size.

But why is this so? Why can't there be brilliant diamonds as big as a car? The answer is actually simple, but I couldn't find it anywhere.

Refraction or transparency comes from the atoms being lined up in rows, so that light can pass between the atoms. We know that these gems are formed by geological processes, and that gives us our answer.

The scale of natural gems that refract light must be closer in scale to atoms than to the earth. The upper limit of these gems is halfway between the scale of atoms and the scale of the earth.

Remember that all around you, every day, are relatively simple things that have never been pointed out.

Here is a link to the original posting:

https://www.markmeekearth.blogspot.com/2014/09/the-scale-of-gem-formation.html?m=0

Thursday, September 16, 2021

Brooklyn, Queens And The Bronx

There are five boroughs comprising New York City. We have already seen Manhattan. Today, we will see three more, Brooklyn, Queens and, the Bronx. This order is moving from south to north. Each borough is also a county. All of these are to the east of Manhattan. Remember that the really tall buildings are in Manhattan, and in many of the views Manhattan can be seen in the background.


On the south shore of Brooklyn lies Coney Island. The name is synonymous with amusement parks. Coney Island was not just one amusement park, but was the place where amusement parks were located, going back to the Nineteenth Century.

There are multiple scenes following. To see the scenes, after the first one, you must first click the up arrow, ^, before you can move on to the next scene by clicking the right or forward arrow, >, After clicking the up arrow, you can then hide the previews of successive scenes, if you wish.

https://www.google.com/maps/@40.5757754,-73.9707903,3a,75y,242.17h,90t/data=!3m7!1e1!3m5!1soieaPeFN_i_aHteBnczOog!2e0!6s%2F%2Fgeo0.ggpht.com%2Fcbk%3Fpanoid%3DoieaPeFN_i_aHteBnczOog%26output%3Dthumbnail%26cb_client%3Dmaps_sv.tactile.gps%26thumb%3D2%26w%3D203%26h%3D100%26yaw%3D235.20389%26pitch%3D0%26thumbfov%3D100!7i16384!8i8192

This is Grand Army Plaza, in Brooklyn. Brooklyn's arch is the Soldiers and Sailors Arch. There are a vast number of ethnic neighborhoods in Brooklyn.

https://www.google.com/maps/@40.6726759,-73.9697703,3a,75y,122.43h,90t/data=!3m7!1e1!3m5!1sJ6OGbZWLnQbwEvr1LcnCtw!2e0!6s%2F%2Fgeo0.ggpht.com%2Fcbk%3Fpanoid%3DJ6OGbZWLnQbwEvr1LcnCtw%26output%3Dthumbnail%26cb_client%3Dmaps_sv.tactile.gps%26thumb%3D2%26w%3D203%26h%3D100%26yaw%3D129.95218%26pitch%3D0%26thumbfov%3D100!7i16384!8i8192

Many of the best-known U.S. warships were built at the Brooklyn Navy Yard. The river between Brooklyn and Manhattan is the East River. The taller buildings are usually on the Manhattan side. The bridge closest to the Navy Yard is the Williamsburg Bridge, but the Manhattan and Brooklyn Bridges are not far away.

https://www.google.com/maps/@40.7069994,-73.9689519,3a,75y,151.9h,90t/data=!3m5!1e1!3m3!1s55hv5C8j3DGYu-0RauVW0g!2e0!6s%2F%2Fgeo1.ggpht.com%2Fcbk%3Fpanoid%3D55hv5C8j3DGYu-0RauVW0g%26output%3Dthumbnail%26cb_client%3Dmaps_sv.tactile.gps%26thumb%3D2%26w%3D203%26h%3D100%26yaw%3D157.96097%26pitch%3D0%26thumbfov%3D100

This is in Brooklyn near the Manhattan and Brooklyn Bridges. The Brooklyn Bridge is the oldest one, with the stone arches. Many of the views are looking across at Manhattan.

https://www.google.com/maps/@40.6958809,-73.9938008,3a,75y,84.81h,90t/data=!3m7!1e1!3m5!1s3roTLnxoOjOaBiGLhJRP6Q!2e0!6s%2F%2Fgeo3.ggpht.com%2Fcbk%3Fpanoid%3D3roTLnxoOjOaBiGLhJRP6Q%26output%3Dthumbnail%26cb_client%3Dmaps_sv.tactile.gps%26thumb%3D2%26w%3D203%26h%3D100%26yaw%3D83.16795%26pitch%3D0%26thumbfov%3D100!7i16384!8i8192

Moving on to the borough of Queens, this is the area known as Astoria. It was named in honor of John Jacob Astor, who we saw in the posting on this blog, "The Waldorf-Astoria", in the hope that he would invest there. Remember that each of the five boroughs is a county unto itself. Usually, cities are within counties but New York City is so large that there are five counties within the city.

https://www.google.com/maps/@40.7643256,-73.9233467,3a,75y,83.74h,90t/data=!3m7!1e1!3m5!1s1Wzn3fYHzkW5zNnjiGK07g!2e0!6s%2F%2Fgeo0.ggpht.com%2Fcbk%3Fpanoid%3D1Wzn3fYHzkW5zNnjiGK07g%26output%3Dthumbnail%26cb_client%3Dmaps_sv.tactile.gps%26thumb%3D2%26w%3D203%26h%3D100%26yaw%3D81.75872%26pitch%3D0%26thumbfov%3D100!7i16384!8i8192

Here is something that is extremely important. When I landed in the U.S. as a boy, there was a lot of faith in the future with regard to science and technology. Someday not too far in the future space travel would be commonplace and much of the world would be run by computers. I picked up on it and have been interested in science ever since.

I later realized that it was due to the influence of the 1964 World's Fair, that had been held in Queens. Before this, computers and putting humans and satellites in orbit was something that people had heard about, but had no real connection to. This is what brought the general public into both the space age and the computer age.

Pretty soon everyone was watching "Lost in Space" and "Star Trek". Next came the movie "2001 A Space Odyssey".

Follow are scenes of the Unisphere, the globe which remains from the 1964 World's Fair. It should be the symbol of the internet.

https://www.google.com/maps/@40.7459012,-73.8450528,3a,75y,173.98h,90t/data=!3m7!1e1!3m5!1s5ZCnt-4JEBW6Rwgfp7CN5g!2e0!6s%2F%2Fgeo0.ggpht.com%2Fcbk%3Fpanoid%3D5ZCnt-4JEBW6Rwgfp7CN5g%26output%3Dthumbnail%26cb_client%3Dmaps_sv.tactile.gps%26thumb%3D2%26w%3D203%26h%3D100%26yaw%3D175.43117%26pitch%3D0%26thumbfov%3D100!7i13312!8i6656

Brooklyn and Queens are both known for their many distinct neighborhoods. The following scenes are of Sunnyside, in Queens

https://www.google.com/maps/@40.7416692,-73.9235753,3a,75y,40.83h,90t/data=!3m5!1e1!3m3!1spcCvfvHsbzb7gHL3vTV_PQ!2e0!6s%2F%2Fgeo0.ggpht.com%2Fcbk%3Fpanoid%3DpcCvfvHsbzb7gHL3vTV_PQ%26output%3Dthumbnail%26cb_client%3Dmaps_sv.tactile.gps%26thumb%3D2%26w%3D203%26h%3D100%26yaw%3D33.208336%26pitch%3D0%26thumbfov%3D100

In New York City, we inevitably run into the very controversial issue of urban renewal. A famous (or infamous) name associated with urban renewal is Robert Moses. He was the driving force behind much of what we see in the city today, such as highways, apartment complexes and, parks. But many historic neighborhoods had to be bulldozed for that to happen.

No project of Robert Moses is as controversial as the Cross-Bronx Expressway. Some believe that it was very detrimental to the South Bronx. Robert Moses even got blamed for causing Brooklyn's two legendary baseball teams, the Dodgers and the Giants, to leave.

What it comes down to is cars. If we are going to drive, there has to be room for highways and parking. On the one hand, we want to preserve historic and beloved neighborhoods. But, on the other hand, we don't want to spend half hour in a traffic jam and then another half hour looking for a place to park. Something has got to give.

Just one tip. If you ever want to win a popularity contest, don't have anything to do with urban renewal. Even if urban renewal is very successful, it often takes a long time to be appreciated. In the short term. the focus is on mourning what has been lost.

In the Bronx, there is Yankee Stadium. The narrow river is the Harlem River, which separates the Bronx from Manhattan. Yankee Stadium goes back a long way, the original stadium was just south of this.

https://www.google.com/maps/@40.8292211,-73.9251031,3a,75y,226.32h,90t/data=!3m5!1e1!3m3!1sSr7D2nLFk6AY5XLpsT9hjg!2e0!6s%2F%2Fgeo0.ggpht.com%2Fcbk%3Fpanoid%3DSr7D2nLFk6AY5XLpsT9hjg%26output%3Dthumbnail%26cb_client%3Dmaps_sv.tactile.gps%26thumb%3D2%26w%3D203%26h%3D100%26yaw%3D218.39133%26pitch%3D0%26thumbfov%3D100

The focal point of the Bronx seems to be The Hub, where several streets come together.

https://www.google.com/maps/@40.8160803,-73.9175986,3a,75y,296.52h,90t/data=!3m7!1e1!3m5!1s9bRIUSakNJZjkeGcbrmkMw!2e0!6s%2F%2Fgeo1.ggpht.com%2Fcbk%3Fpanoid%3D9bRIUSakNJZjkeGcbrmkMw%26output%3Dthumbnail%26cb_client%3Dmaps_sv.tactile.gps%26thumb%3D2%26w%3D203%26h%3D100%26yaw%3D303.39853%26pitch%3D0%26thumbfov%3D100!7i13312!8i6656

In the Bronx, this is the Mott Haven Historical District

https://www.google.com/maps/@40.8111785,-73.9243229,3a,75y,69.65h,90t/data=!3m7!1e1!3m5!1sk-LBKHgkLVoK19_ItUe57w!2e0!6s%2F%2Fgeo0.ggpht.com%2Fcbk%3Fpanoid%3Dk-LBKHgkLVoK19_ItUe57w%26output%3Dthumbnail%26cb_client%3Dmaps_sv.tactile.gps%26thumb%3D2%26w%3D203%26h%3D100%26yaw%3D63.895924%26pitch%3D0%26thumbfov%3D100!7i16384!8i8192

Other Postings About New York City

There are many theories about 9/11. I have a spiritual theory that we saw in section 16) THE SECOND NIAGARA PROPHECY in the compound posting, "The Aztec Prophecy" April 2018. Christianity can block ancient curses but if we fall away from Christianity then those curses can take effect, specifically for the taking of Cleopatra's Needles from Egypt.

The geology of New York City is explained by the supporting document, 84) COOLING CHANNELS in the book-length compound posting "The Story Of Planet Earth", on the geology blog www.markmeekearth.blogspot.com . This geological theory, involving the impact of Continental Asteroids, leaves no major feature of the earth's surface unexplained, either on land or on the seafloor.

Measurement

I periodically collect postings about similar subject matter into one compound posting. This is a new compound posting about measurement. Much of the material is new.

TABLE OF CONTENTS

1) THE UNTOLD STORY OF THE METRIC SYSTEM

2) WHAT THE METRIC SYSTEM MISSED

3) THE REAL STORY OF AMERICA AND THE METRIC SYSTEM

4) MOLES AND COULOMBS

5) THE MOST USEFUL UNIT

6) WHY WE SHOULD COUNT BY TWELVES

7) A VERY USEFUL TOOL

8) THE MEASURABLES

9) THE 720 DEGREE CIRCLE

10) CHART NAMES

11) NEW UNITS OF MEASUREMENT



1) THE UNTOLD STORY OF THE METRIC SYSTEM

Division used to be far more important in society than it's opposite, multiplication.

Time is the most thing that we measure. But time is something that we have in fixed quantities. It can be divided between tasks that have to be done, but cannot be multiplied. 

Another thing that comes in fixed quantities is land. Land is divided up into plots for buildings, farms or, homes, but it cannot be multiplied. Being a fixed quantity, it can only be divided.

The meat from animals that had been hunted, the crops that have been grown, pies and bread that had been baked and, eggs that had been collected, are divided up between the people that have to be fed, but are not multiplied.

Clay is divided into bricks. Water is divided between the farms and homes that need it. But neither is multiplied.

Humans can be said to have lived in a division, rather than a multiplication, society. Crops don't multiply, the number of crops is the same as that of the seeds that were planted. The vast majority of investments were governed by addition, rather than by multiplication. 

In times past, human population stayed relatively constant, rather than multiplying, the world's population didn't reach a billion until about 1850.

As we might expect the systems of measurement that humans used were intended for division. Time especially was measured in round numbers that were easily divisible. There were 24 hours in a day, averaging 12 hours of daylight and 12 hours of night. There were 60 seconds in a minute and 60 minutes in an hour.

A circle is something that may be divided, but is not multiplied. Should we be surprised that a circle is divided into a nice, round easily divisible 360 degrees?

After addition and subtraction, it was very much a division society.

But the Industrial Revolution, particularly the printing press, changed everything. Even before the perfection of assembly line manufacturing techniques, industry usually involved making multiple copies of some product.

This facilitated the move from a division society to a multiplication society. This was especially true as mechanization increased the efficiency of agriculture, leading more people to work in factories rather than on farms.

The Industrial Revolution also changed our concept of time. In an agricultural society, the calendar is more important than the clock. Planting and harvesting have to be done at a particular time of year, but not at a particular time of day.

Manufacturing, in contrast, requires workers to show up for work at a particular time of day, usually regardless of the time of year. The industrial society thus had it's concept of time based on the clock, rather than on the calendar of the agricultural society.

In 1789 came the French Revolution, which can be said to have opened the modern political era. The revolutionaries were obsessed with the number 10, considering it as a symbol of their implacable hostility to both the monarchy and the Catholic Church.

They wanted to base everything on the number 10. The revolutionaries introduced a year with 10 months, a day with 10 hours, and an hour with 100 minutes. There was also a measurement system, with interconnected units and based on multiples of 10.

The time measurements, based on 10, did not last. The reason being, as we saw above, is that our measurements of time are based on division, blocks of time are something that tend to get divided rather than multiplied. 10 is a poorly-divisible number. Using round, easily-divisible numbers, such as 60-second minutes, 60-minute hours and, 24-hour days is much more practical.

But the system of other measurements, length, mass, volume, electric current, etc., based on multiples of 10 is different. The reason that it is different is that the Industrial Revolution had caused the change from the division society to the multiplication society. In contrast with the earlier division of agriculture, there was now the multiplication of making multiple copies of the same thing by industrial processes.

This is why the measurement system that was introduced during the French Revolution, and based on multiples of 10, is still with us today. It is known as the Metric System.

The reason that a measurement system with the emphasis on multiplication, as opposed to the division of the older system, was not implemented before the French Revolution was simply the entrenched way of doing things. The Industrial Revolution had set the stage but it took the upheaval of a political revolution to get it implemented.

2) WHAT THE METRIC SYSTEM MISSED

Here is something that I have never seen written about the Metric System.

The Metric System is based on the meter as the unit of length. The primary unit of volume, the liter, is defined as a cubic decimeter, which is a tenth of a meter. The primary unit of mass, the kilogram, is defined as the mass of one liter of water. 

A gram is defined as the mass of one cubic centimeter, which is a hundredth of a meter, of water. This means that a cubic meter is 10 x 10 x 10, or one thousand, liters. The mass of a cubic meter of water is defined as a metric ton.

There are other Metric units that are unrelated to the meter. The Celsius scale of temperature defines the freezing point of water as zero degrees and the boiling point as one hundred degrees. As with length, Metric units are based on the number ten and it's multiples.

But the meter is an arbitrary unit of length. It could just as easily have been based on some other length. The meter was originally intended to be one ten-millionth of the distance from the north pole to the equator, along the meridian through Paris, but that did not end up being used as the final definition of the meter.

There is one important thing that the Metric System could easily have included, but it missed.

The Metric System was developed by the French Revolutionaries who overthrew and guillotined the king and queen. They considered the number ten as a symbol of their implacable hostility to both the monarchy and the Catholic Church. Aside from the Metric System there was an attempt to implement a year with ten months, a week with ten days, a day with ten hours, and an hour with a hundred minutes.

During the reign of Louis XVI and Marie Antoinette, the Bourbon monarchs that the revolutionaries had overthrown and guillotined, the first human flight had taken place, in a balloon built by the Montgolfier Brothers.

What if the revolutionaries who created the Metric System could have foreseen how important aeronautics would be in the future? 

Although the Wright Brothers are generally credited with the first powered flight in a heavier-than-air craft, much of the early development of flight, long after the Montgolfier balloons, took place in France. A legacy of that is the Paris Air Show of today.

When humans were able to fly, the acceleration due to gravity which governs how fast things fall, became more important. This acceleration is defined as 32 feet, or approximately 9.8 meters, per second squared. Although the rate of gravitational acceleration is not perfectly consistent across the earth, the variation is relatively slight.

I have brought up the idea of a "grav", short for "gravity", as a unit of measure. As long as we measure time in seconds a grav would be equal to 16 feet, which is half of the gravitational acceleration per second.

This would be a very useful unit for measure of vertical distances. Doesn't it make sense that the unit used to measure vertical distances should be based on the rate of fall?

If we measured the height or altitude of something in gravs, the square root of that number would be the time that a heavy compact object would take to fall to the surface from that height, neglecting air resistance. If we measured the time the object took to fall from that height, again neglecting any air resistance, squaring the time in seconds would give the height in gravs.

The gravitational acceleration due to gravity is 9.8 meters per second squared, half that would be a grav. That is a rounded figure, a grav would actually be 4.87 meters.

But use of the grav as a unit of measure involves figuring the square root of it, to get the fall time from an altitude in seconds. This is made awkward by the fact that 4.87 meters would be a difficult number to deal with.

What I cannot help wondering is what if the revolutionaries had foreseen flight, and how important vertical distances would become?

The meter is an entirely arbitrary unit, it could have been either longer or shorter. If the meter had been made just a little bit shorter the acceleration due to gravity could have been exactly 10 meters per second squared, instead of the 9.8 that it turned out to be.

This would mean that a grav would be equal to exactly 5 meters, which would have been very easy to work with. The 10 meters per second squared would be ideal for the Metric System, which is supposed to be based on 10.

Clearly it was 1789 and, although people had flown in balloons, the revolutionaries who created the Metric System just didn't foresee how important flight, and thus vertical distances, would become. A slight adjustment in the meter, 10 meters instead of 9.8, would have made it very useful for measuring vertical distances and their associated fall rates.

Ironically the Eiffel Tower would be built in celebration of the centennial of the French Revolution, which brought about the Metric System. It would be the prototype of the modern skyscraper, which would make vertical distances even more important than aircraft would already make them. The Eiffel Tower seems to be a recreation of the balloon flights, taking off for the sky in an elevator instead of a balloon.

3) THE REAL STORY OF AMERICA AND THE METRIC SYSTEM

It has long mystified many people why America, with it's emphasis on technical progress, has lagged behind the rest of the world in adapting the Metric System for measurements. The system has been creeping into the U.S. but the rest of the world has long since been Metric.

There is an answer, but it's complicated.

It goes back to America's beginnings. When America declared independence from Britain, the first country to give America diplomatic recognition was France. It helped America win independence and the appreciation of this help can be seen today in the enduring popularity of the name "Lafayette", for the French general.

France was a monarchy, led by the famous king and queen Louis XVI and Marie Antoinette. They lived in the absolutely fabulous Palace of Versailles.

The original royal palace of Paris was on the island in the Seine River, where Notre Dame Cathedral is also located. They moved from there a short distance away to an even grander palace. The French royals eventually topped that with an even greater palace, and moved there. 

There wasn't enough space to build the new palace complex in the city, so the Palace of Versailles was built to the southwest of Paris. The second palace would become what is now the Louvre.

But France's royal glory was not to last. Not too long after it had helped America gain independence, the king and queen were overthrown and guillotined in the French Revolution, which can be said to have begun the modern political era.

Ironically the original royal palace, on the island in the Seine River, would serve as a notorious prison during the French Revolution.

The French Revolution would ultimately result in the rise of Napoleon, as the prototype of the modern dictator. Although he had nothing to do with initiating the revolution. Napoleon collected a lot of art during his conquests, which is what got the Louvre, in the second royal palace, started as a great art museum.

With the French Revolution America lost it's close friends, the king and queen who were the first foreign government to give the U.S. diplomatic recognition and who helped it gain independence.

The French revolutionaries, who had overthrown and guillotined the king and queen, were obsessed with the number ten. They wanted to eradicate anything to do with the monarchy and the Catholic Church.

The revolutionaries introduced a calendar with ten months in a year and ten days in the week. There are still clocks in museums with ten-hour days, with a hundred minutes to the hour.

None of that lasted but there is the system of measurement that the revolutionaries developed, based on the number ten, that is still with us. It has become the global system of measurement and is known as the Metric System.

The Metric System is based on the number ten and it's multiples. Each unit is ten times, or one-tenth of, the previous unit. A meter is the unit of length, a decimeter is one-tenth of a meter and a centimeter is one-tenth of a decimeter, or one-hundredth of a meter.

The different Metric units are related to each other and connected by water. A liter, the unit of volume, is a cubic decimeter. A liter of water has a mass of one kilogram, which is a thousand grams, which is the Metric unit of mass. This means that a cubic centimeter of water weighs one gram.

There is a base unit for each entity that gets measured, length, volume, mass, etc. The Metric System uses the Celsius system of temperature measurement which is, once again, based on water. 0 degrees Celsius is the freezing point of water and 100 degrees is it's boiling point.

The same prefixes are used with each base unit. Kilo, for example, means one thousand so that a kilogram is a thousand grams and a kilometer is a thousand meters. There is a different prefix for every ten, but some of the prefixes are rarely used. 

Length is usually always measured in meters, kilometers or a thousand meters, centimeters or a hundredth of a meter, or millimeters or a thousandth of a meter. Units like decameters or ten meters, or decimeters or one-tenth of a meter, are rarely used.

The system that the Metric System replaces is an arbitrary collection of units. 16 ounces is a pound. 12 inches is a foot. 3 feet are a yard. 5,280 feet are a mile. The freezing point of water is 32 degrees and the boiling point is 212 degrees. There is nothing like a common multiple or interconnection of units.

The world has adopted the Metric System, with the curious exception of the United States. Although use of the Metric System has gradually been seeping in.

To see the reason, let's go back in history. America has never forgotten, even if it is not commonly articulated, that the Metric System is a product of the revolution that overthrew and guillotined America's close friends, the ones that were the first to give America diplomatic recognition, and who helped it to gain independence.

That is why America has been so resistant to adopting the Metric System.

This is part of the scenario in the compound posting on this blog, "America And The Modern World Explained By Way Of Paris", December 2015.

4) MOLES AND COULOMBS

This is about something that I mentioned recently that just doesn't make sense. It involves the units of moles and coulombs.

A mole is a quantity such that this number of atoms or molecules of an element or compound would have a mass of the atomic or molecular weight of the element or compound in grams. Mass is the actual amount of matter while weight is the effect of gravity on the mass.

The atomic or molecular weight or mass of an element or compound is simply the number of protons and neutrons in it's nuclei. An atom of oxygen has eight protons and eight neutrons, in it's most common isotope, so it's atomic weight is 16. 

A molecule of water consists of one atom of oxygen and two of hydrogen, hence the familiar chemical formula, H2O. Atoms of the most common isotope of hydrogen have only one proton in their nucleus, so their atomic weight is 1. Since there are two atoms of hydrogen in a water molecule, their combined atomic weight is 2. Since an atom of oxygen has an atomic weight of 16, adding this together means that water has a molecular weight of 18.

I should mention that it is a little bit more complicated than this because elements almost always have isotopes. An element is defined by the number of protons in it's nucleus, which is it's atomic number. But the same element may have different numbers of neutrons in it's atoms. Atoms with the same number of protons but a different number of neutrons are known as isotopes. 

Isotopes are important in our discussion here because the number of neutrons in the nucleus affects the atomic weight or mass. Remember that the atomic weight or mass is the total number of nucleons, protons and neutrons, in the nucleus. 

An example of an isotope is heavy water, which you have probably heard of. Ordinary hydrogen atoms have only a proton in the nucleus, with no neutrons. But an isotope of hydrogen, known as deuterium, also has a neutron in the nucleus. If the hydrogen atoms in a water molecule are deuterium then it will be about 10% heavier than ordinary water because the molecule now has 20 nucleons, instead of 18.

Heavy water is useful in nuclear technology. Ordinary water absorbs neutrons, turning it into heavy water. This makes heavy water, where the hydrogen atoms already have a neutron, useful as a moderator in a nuclear reactor because it slows down, but doesn't absorb, neutrons. When it comes to fusion of atoms deuterium is the easiest atom of all to fuse because it already contains the neutron. That is why a hydrogen bomb consists of an ordinary atomic bomb surrounded by a jacket of heavy water and there are "brown dwarfs", would-be stars that only have enough mass to fuse deuterium atoms but nothing else.

Atoms also contain electrons. But while the electric charge on an electron is equal, but opposite, to the charge on a proton, the electron is so light in mass that it is not even considered in the atomic or molecular weight or mass. A proton has 1,836 times the mass of an electron. A neutron does not have exactly the same mass as a proton, it has the mass of proton and electron combined because neutrons are formed by electrons being crunched into protons by stellar fusion.

A mole is based on Avogadro's number. As long as we measure mass in grams Avogadro's number of atoms or molecules will have a mass of the atomic or molecular weight in grams. Avogadro's number of water molecules will have a mass of 18 grams. If we measured mass in a unit other than grams then Avogadro's number would be different.

Avogadro's number is 6.02 x 10 (23)

Another number that is beyond the scope of human understanding is the coulomb. This is the standard unit of electric charge, defined as the number of electrons. In electricity a current is measured in amperes. An ampere is defined as the flow of one coulomb per second.

Unlike the mole, which is defined by atoms and grams, the coulomb is a somewhat arbitrary unit. It is not really defined by anything. An ampere is the flow of one coulomb per second, but the coulomb isn't defined by seconds. 

A coulomb is defined as 6.24 x 10 (18) electrons.

So here is the question. Electrons come from atoms. Electrons are measured in coulombs and atoms are measured in moles. I live in a place where electrochemistry has been very important in industry and just do not understand why these two units were not coordinated.

Moles and coulombs are vast numbers, far beyond human ability to grasp. But yet, relatively speaking, the two numbers are in the same general "neighborhood". A mole is roughly 9,650 times a coulomb.

I am not saying that we should measure electric charge or current in moles, that would be too large of a unit. But if we decreased the size of a coulomb, and thus an ampere, to about .965 of it's present value, so that a coulomb was one-ten thousandth of a mole, that would be very convenient.

It would mean that if a milligram, multiplied by the atomic or molecular weight, of atoms or molecules each gave up one electron, there would be a coulomb of electrons.

The other units of the Metric System, such as length, volume and, mass, are coordinated around water. A cubic meter of water has a mass of one metric tons. A decimeter is 1/10 of a meter, or 10 centimeters. A cubic decimeter defines a volume of one liter. A liter of water has a mass of one kilogram because a gram is defined as the mass of one cubic centimeter of water, which is also a volume of one milliliter.

So why were moles and coulombs never coordinated? This really doesn't make sense, since electrons reside in, and flow from, atoms. If a coulomb were a millimole, or one-ten thousandth of a mole, this would be revolutionary.

If there was a chemical reaction where one mole of atoms each lost an electron to another mole of atoms we would know, without doing any calculations, that the total movement of electrons was ten thousand coulombs.

The most common isotope of copper has an atomic weight or mass of 63. So if we have 63 grams of copper in an electric wire and one ampere of current is flowing through the wire we would know, without any calculation, that each copper atom, on average, is giving out, and taking in, ten thousand electrons every second.

This would be very useful in a myriad of ways.

5) THE MOST VALUABLE UNIT

There is a common measurement that could be extremely useful to us but is rarely used. Whenever we look at an object, it manifests a certain angular diameter in our field of vision. The angular diameter of any object in our vision is proportional to it's actual diameter divided by it's distance from us. Of course, if it is an unevenly sided object, trigonometric functions must come into play. 

But measuring and expressing angular diameter is something that we handle very poorly. We usually express angular diameter in imprecise, subjective terms such as "loomed large in the sky". 

I believe that getting in the habit of precision measurement of angular diameter would be very useful because it gives us an immediate ratio of the diameter of the subject in relation to it's distance from us. This ratio determines how much of our field of vision, or that of a camera, the object will occupy. Angular diameter could be measured at least as easily as physical diameter using a simple scope or square. 

The beginning of the problem is the way that we measure angles. We measure in degrees. 90 degrees is a right angle, 180 is a straight line and 360 is a complete circle. 

Measurement in degrees works just fine if we are measuring the outside of a circle, such as latitude and longitude on the earth's surface. But it is my conclusion that we must deal with circles and spheres as two different entities if we are measuring the circle from the inside, instead of the outside. 

Whenever we look at an object some distance away, we are forming a circle with us at the center and the object on the edge of the circle. If there is vertical elevation involved, then we form a three-dimensional sphere rather than a two-dimensional circle. 

We do sometimes express angular diameter, such as the apparent distance between two stars in the sky. However, the reason that we are not making full use of this measurement is that we try to measure in degrees. While this works fine for the outside of a sphere or circle, it works very poorly for measuring the inside and this is what we are doing when we look at an object some distance away. 

My solution is to dig out that old standby of math class known as a radian. This is simply the distance on a circle equal to the radius of the circle, meaning that there are 2 pi radians in a complete circle. 

This is a textbook unit that is rarely used in the "real world" and I find that to be a shame because it could easily be extremely useful. Since measurement in radians is a ratio, the actual diameter of the object divided by it's distance from us, we can treat measurement of angular diameter in radians in the same way as trigonometric functions, which are also ratios. 

If you look at an object such as a building perpendicular to it's center from a distance equal to the width of the building, it will occupy an angular diameter of one radian. We only have to keep in mind that this angular diameter is the arc of the circle of which the observer is at the center and not the straight line side of the building, which is actually a chord on the circle. This means that if we look at the side of a building along a line perpendicular to the side, we actually have to subtract the sine of the angle which is half the angular diameter of the building. 

If the building occupies an angular diameter of 1.57 radians, which is 90 degrees, we would take the sine of half that angle, 45 degrees, which is 0.5. So, if we subtract 0.5 of 1.57 radians, we get 0.785. This means that the side of the rectangular building that we are looking at along a line perpendicular to it's side and which occupies an angular diameter of 1.57 radians, is at a distance from us of 0.785 the length of the side of the building. 

Probably the reason that we do not make more use of this versatile unit is that it does not fit with our base ten number system. There is 2 pi, or 6.28 radians in a complete circle. The conversion factor with degrees is 57.3. This means that if you looked at an object from a distance ten times the object's diameter, it would occupy an angular diameter of .1 radian or 5.73 degrees. 

The radian would appear to be especially useful in space travel because when a spherical body, such as a planet, occupies an angular diameter of one radian, it means that the observer is at a distance from the planet's surface equal to the radius of the planet, or the distance from it's surface to it's center. 

One reason that the radian is such an interesting unit is that it is actually the only completely natural unit that human beings use. The vast majority of units that we use were created arbitrarily. Seconds, meters, feet, miles and, pounds are entirely arbitrary. A degree was chosen to be 1/360 of a complete circle because 360 is a very round and easily divisible number, but even so this is an arbitrary unit that is meaningless in the universe of inanimate matter. 

Days and years can be said to be natural units because they are based on the rotation and revolution of the earth. Yet these are natural units only on earth or while measuring it. Further out in space, the day and the year are just as arbitrary as the other units. 

Radians, however, are a natural unit anywhere in the universe and as far as I can see, is the only unit of which this claim can be made.

6) WHY WE SHOULD COUNT BY TWELVES

Here is something to really think and talk about. Have you ever stopped to ponder just how inefficient our basic counting system is, the one that we have taken for granted since early childhood? In my book, "The Patterns of New Ideas", I suggested that our present system of counting by tens is woefully inefficient and we began using this system only because we have ten fingers and people in ancient times used their fingers to count. This is surely the supreme example of how we can be technologically forward but system backward. 

For ancient people, using their ten fingers to count worked just fine. But the world was to get far more complex. The four basic arithmetical operations are: addition, subtraction, multiplication and, division. Basing our counting system on any number, such as the tens that we use now, will do very well with the first three. 

However the last of the four, division, is the tricky one. Division is very important in the flow of daily life, just as are the first three. The difference with division is that not all of the convenient numbers that we could possibly base our counting system on are equally divisible. 

I maintain that, for maximum efficiency, the number on which we base our counting system should be as divisible as possible. It does not make sense to base the system on too high of a number because that would mean that more symbols (1,2,3,...) would have to be use and that would hinder communication. However, we have made a really great mistake by counting by tens simply because ten is so poorly divisible. 

Consider that by far the most important and most frequent measurement that human beings take is that of time. In fact, we take measurements of time many times more often than all other entities that we measure such as distance, weight, temperature, etc. Now notice when you look at a clock or watch that we base our measurement of time not on the number ten, but on twelve and multiples of twelve. There are twelve hours in a day, sixty seconds in a minute and, sixty minutes in an hour. 

You may notice that there was once ten months. The sept- of September means seven in Latin, just as oct- means eight, nov- means nine and, dec- means ten (as in "decimal", for example). But the logic of counting by twelves, rather than by tens, prevailed. Two more months were added to make twelve, July is named for Julius Caesar and August is named for Augustus Caesar. 

The truth is that when measuring time, division is very important and people instinctively adapted a system based on twelve, rather than the conventional ten. This is also why eggs are sold by the dozen, rather than by tens, twelve eggs are more likely to be evenly divisible by the members of a family. 

Time is not the only measurement in which twelve is very obviously a better base to use than ten because of it's easy divisibility. A complete circle, such as the circumference of the earth, is divided into 360 degrees. This is a nice, round, easily divisibly multiple of twelve. 

The Metric System is an absolutely brilliant idea that was conceived at the time of the French Revolution. But yet something is still missing about it. The Metric System is superior to the old English system of feet, yards and, miles. 

However, here we are in the Twenty-First Century and that old system still has not gone away and the Metric System usually has to be forced on people by law. The reason is very clear, the Metric System is far better with regard to multiplication and the easy convertibility of units, but the old system still has the advantage of divisibility. Twelve inches are a foot, 36 inches are a yard and 5,280 feet are a mile. Notice that measurement of time was never metricized. 

The Metric System is at the mercy of the number base that we use and will never reach it's full potential as long as we count by tens, rather than twelves. Fractions are still as useful as they are because ten is such an awkward number to divide, basing our number system on twelve would change this by incorporating much of the useful divisibility of fractions. 

Just think how convenient it would be if we could express time in decimal form based, of course, on twelve, rather than ten. Consider a decimal such as 1.63 hours. It is difficult for us to grasp quickly because it straddles the two number systems. 

By using a grid, we can easily express any point on the grid by using cartesian coordinates. What if we could do this with the entire planet? We can, but expression in terms of latitude and longitude are based on twelve but we will have to express the coordinates in base-ten decimal form and it makes for an awkward and inefficient arrangement. Latitude and longitude are getting ever-more important in these days of GPS but we cannot effectively express the coordinates of a point in decimal for and will not be able to most-effectively do so until we count by twelves. 

Our number system plainly and simply revolves around twelve but we try to make it revolve around ten because we happen to have ten fingers. This is certainly one of the greatest mistakes ever made. We do not still write in hieroglyphics yet we still count by tens. 

THE EXPRESSION OF TIME IN DEGREES

 While we are on the subject of counting and measurement systems, let's consider the units of hours and minutes. Hours and minutes are completely arbitrary units and were adapted due to the easy divisibility of the units which we use for time. 

We cannot actually measure time but only motion, which is a function of time. Our measurement of time is based on the motions of the earth. The earth rotates 360 degrees in one day. Thus, one degree of the earth's rotation corresponds to 240 seconds or what we would now refer to as four minutes. An hour is fifteen degrees. 

Since humans are now spending quite a bit of time in space, in earth orbit, why not express time in degrees? This would base the passage of time on how far the earth has rotated during that interval of time. I am certain that this would be much more convenient and efficient, hours and minutes were merely convenient everyday units in the pre-space age.

7) A VERY USEFUL TOOL

There is a very simple measurement tool that I thought of that can quickly and easily accomplish tasks that are very cumbersome and time-consuming with existing methods. This tool can be very easily homemade and I believe that anyone involved in any kind of building, constructing or, surveying would find it invaluable. I have decided, for various reasons, not to pursue a patent for it any longer. So, I have decided to put it here in the public domain so that anyone can make their own and no one else can get a patent on it. 

One day, I drove past some large oil storage tanks in Tonawanda, NY near the South Grand Island Bridges. Just as a mental exercise, I tried to dream up a way to quickly measure the circumference of such tanks or another large, circular object. I started thinking of measuring the curvature over a given linear distance with the idea that the less the curvature per linear distance, the larger the circumference. 

But then another idea clicked into my head. What if someone got an ordinary magnetic compass and enlarged either the compass itself or it's mounting so that it was circular and of a known circumference, such as a yard or a meter? Suppose we then placed the edge of the compass against the side of a large oil tank and noted the directional reading given by the compass needle. Then we would note the point on the side of the compass that was in contact with the side of the tank. If we proceeded to rotate the compass over a complete circle and noted the change in the directional reading of the needle, we would have all the information needed to quickly and easily calculate the circumference of the oil tank. 

If we placed the compass against the side of the oil tank and noted that the directional reading of the needle was 192 degrees and then rotated the compass a complete circle so that the point on it's edge that had originally contacted the side of the tank was back in the same place, all we would have to do would be to take the fraction of a complete circle that the needle changed during the rotation and multiply it by the circumference of the compass mounting and we would have the answer, the circumference of the tank. 

For example, If the compass mounting was one yard in circumference and, upon completion of the rotation the needle had moved from 192 degrees to 196 degrees, the circumference of the tank would be 360/4 times one yard. In other words, 90 yards. 

As I stopped to have dinner in a restaurant, my mind really began racing. I realized that I was onto something. I asked the waitress for something I could use for a sheet of paper and by the time I was done, I had filled a side of the paper with all manner of tasks that such a simple device could quickly and easily accomplish. I decided that the device would be called "The Compass Ruler". 

I made one of my own by getting a Wal-Mart hiking compass, breaking off the casing and, gluing it onto a piece of plywood I had cut with a jig saw to a circumference of one meter. I knew enough about building and construction to know that such a tool was not in common use. However, I checked extensively to see if such a tool was in use anywhere and found no sign that it was. There was once such a thing as a surveyor's compass, that had fallen into disuse, but it was a compass mounted on a stand and was in no way used like my Compass Ruler would be. On my device, measurements would be taken by actually contacting the side of a structure. 

The principle of the operation of the Compass Ruler is simple. Just as a plumb, a weight tied to a string, uses the earth's gravity as a fixed reference point for measurment of vertical angles, the Compass Ruler uses the earth's magnetic field as a fixed reference point for measurement of horizontal angles. The Compass Ruler obviously must be marked around the circumference edge in degrees, just as a protractor would be. 



There is an even simpler version of the Compass Ruler. Simply take a square of wood, 1 x 4 for example, and glue a compass in the middle of it. For best results, be sure that it is indeed a square and that each cardinal direction faces toward the middle of one side of the wood. Suppose you have built a corner between two walls or fences and you want to be sure that it does indeed form a right angle. Simply hold one side of your Compass Ruler against one wall and note the directional reading of the needle. Then hold the same side against the other wall. You should get a change in the needle of ninety degrees. Simple. 

This method is just as useful if the two walls do not actually contact each other, or for that matter do not even come near each other. This makes the old standby, the builder's square seem awkward and obsolete by comparison. Verifying a right angle by the 3-4-5 Pythagorean Theorem method is also awkward and time-consuming. 

Suppose it is necessary to measure the angle beyween any two walls that do not actually intersect. With a builder's square it is impossible. With tape measures it is tedious, time-consuming and, prone to error. With a surveying crew, it is expensive. With my Compass Ruler, it is almost effortless. 

What if you have built a long wall or fence and want to verify it's straightness? All you have to do is walk down the wall, taking periodic measurements with the Compass Ruler by placing it's edge against the wall. If the wall is indeed straight, you will get the same directional reading of the needle on every measurement. If it is not straight, by measuring the wall with the Compass Ruler at given intervals, you can tell by how much it curves. 

This is also useful for a vast number of other such similar measurements. How would you verify that two parallel walls are truly parallel? Just take a reading on one wall with the Compass Ruler. Then, go to the other wall and put the same edge against that wall. If the walls are parallel, you will get a difference in the directional readings of 180 degrees. 

Suppose you wished to set up a series of signs along a road and wished them to all have the same directional orientation. How would you do it? What if you were setting up a sign along the road and wanted it to be set at 45 degrees to the road to give maximum exposure. Or suppose you were building a wall or fence and wished it to run parallel (or perpendicular) to the road. 

All of these tasks would be difficult, impossible or expensive with existing methods. With my Compass Ruler, all would be simple and easy. To measure the directional orientation of the road with the Compass Ruler, simply place the device on the road surface alongside a traffic line on the road. 

Measurement of curvature is just as easy with the Compass Ruler. Just take readings against the curved structure at regular intervals. Curvature can be expressed as change in the directional orientation of the needle per given linear distance. Another advantage of either version of the Compass Ruler, either the circular or the simpler square version of the device, is that contact measurements, such as those described above, are not hampered if two structures to be measured and compared are not visible from each other or if there is an obstacle, like a row of bushes, between two structures. 

Surveying is easy with the Compass Ruler. Suppose you want to get an accurate measurement of the distance to a certain remote point. First, you would either set up or pick out a remote visible reference point to use in the measurements. Then you would mark the local point from which you would take the measurement to the remote point. Then you would establish a measurement point a convenient distance away so that a line from the local point (Point A) to the measurement point (Point B) would form a right angle with a line from point A to the remote point (Point C). 

Using a straight-edge, such as a perfectly straight 1 x 4 board, you would sight on the remote point C from the local point A looking straight down the straight-edge. You would use the Compass Ruler to note the directional orientation of the straight-edge as it points from Point A to Point C. You would then go to the measurement Point B that you have selected and take another sighting on the remote Point C from there. 

All you would than have to do is take the difference in the angular reading of the two measurements. Using a scientific calculator, you would get the cotangent of the angular difference. You would then multiply the cotangent by the distance from Point A, the local point, to the measurement Point B. That would give you the distance from Point A to the remote Point C. 

Obviously, for best results in surveying using the Compass Ruler, measurements must be taken carefully. The distance from Point A to Point B must be accurately measured. And, the same spot on the remote point must be sighted upon. The longer the carefully measured distance from Point A to Point B is in relation to the distance from Point A to the remote Point C is, the better the result will be. It should always be at least 10% of the distance. 

It is not necessary to have a right angle between the two lines from points A to C and from A to B, but if not, the simplicity of a cotangent calculation will be lost and a graphical calculation will become necessary. If possible, the baseline for the measurement from Point A to Point B can make use of a pre-existant line, such as a road. 

The straight-edge can be built onto the Compass Ruler if it is to be used for surveying. For even better results, the straight-edge can be fitted with a small telescope, a laser pointer, or, both. A vertically diagonal mirror can make it possible to see the compass on the Compass Ruler at the same time that the sighting is being done. For a finishing touch, the entire device can be set on a mounting. 

To set up a marker, such as a traffic cone, at a given distance in a given direction from a starting point, use the reverse of this method. Pre-set a sighting from a Point B to that distance and have a rodman walk with the marker until he is in the sight. Then use hand signals or radio/phone communication to have the marker set up at the correct point. 

Suppose you are out on the water in a boat and wish to measure how far you are from shore because you notice a shipwreck or some other object of interest under the water and wish to record the position. You would pick out two easily recognizable objects on shore such as trees or large rocks. The two objects should be in a line perpendicular to the line between you and one of the objects. Measure the angle between the two objects from where you are in the boat and record it. 

Later, you would carefully measure the distance between the two objects using a tape measure or a map. Then you would take the cotangent of the angle measured from the boat and multiply it by that distance. Alternatively, you could simply take the directional readings of any two (or more) prominently visible, fixed position objects. The position on the water could then be charted using a map or satellite photo of the area. 

Astronomers have long used this technique to measure the distance to stars, it is known as parallax. The carefully measured distance from Point A to Point B is referred to as the baseline. The same principle can be used with the Compass Ruler to map an entire area. Simply pick out visible objects such as trees, houses, etc. Measure the distances from a central point to the objects and then measure the angular distances between those objects from the central point. The map then can be easily made using a ruler and protractor. Of course, on complex maps, more than one central point can be used. If the terrain to be mapped is hilly, the logical place for the central points would obviously be on the high ground. 

Aside from the contact measurement and surveying versions, there is yet another version of the Compass Ruler, the drawing version. Simply fasten or glue a small compass to a straight-edge such as a ruler and it makes the protractor used in geometric drawings just as obsolete as the builder's square is in construction. To draw two lines at a certain angle to each other, simply draw one, noting the angle indicated on the compass dial. Then move the straight-edge so that the difference showing on the dial is now the desired angle and then draw the second line. To measure the angle between two existing lines, simply reverse this process. 

If the drawing paper is securely taped down, aligned either east-west or north-south with the compass for best results, an entire geometric drawing can be made with unprecedented accuracy using the drawing version of the Compass Ruler. Parallel lines will have the same compass dial reading anywhere in the drawing. Perpendicular lines will differ 90 degrees in reading. Existing methods are far inferior to this. Of course, it would be simple to draw a map that was surveyed using the surveying version of the tool, just drawing the measurements on paper. 

There are certainly many more everyday applications of this simple but extremely useful device. The device could also bring geometry and trigonometry classes to life. The lessons that now consist of drawing lines and circles on paper could occasionally be done as actual measurements in the gym or schoolyard. 

Anyone can make their own of any version of the Compass Ruler, the circular or the simpler square version for contact measurements. Or the surveying or drawing versions with an attached or accompanying straight-edge. It can also be manufactured and sold although it will not be patentable now that I have put it in the public domain. 

I will not earn any money on this but I just want to have contributed something to the world. We read of George Washington Carver and how he revealed many things that the humble peanut can be used for. I would like to do the same thing for the simple device known as the compass. Just as GPS systems are becoming ubiquitous and it seems to be of little use any more, we see that there is a whole world of tasks that it can accomplish most effectively. Any simple compass would have it's usefulness multiplied if it were encased with a straight side to perform some of the measurements listed above.

8) THE MEASURABLES

There are 92 elements, or different atoms. But most of these are rare. We have seen how the few common atoms act as points of information that affects how the environment operates. There are two separate "Rules Of Common Atoms", one for the universe of inanimate matter and the other for biology.

You may remember the acronym from biology class, "CHNOPS". This stands for carbon, hydrogen, nitrogen, oxygen, phosphorus and, sulfur. These are by far the most common atoms in biological molecules, and they act as information points. Color does not really exist in the universe of inanimate matter, it is just the way our eyes and brains interpret the different wavelengths of visible light.

But have you ever wondered why there are six basic colors, red, orange, yellow, green, blue and, violet? It is because we are composed of six common atoms, and these act as information points. This applies to all living things, and is the reason that living things are classified into six "kingdoms". This does not mean that the rare "trace" elements are not important but the abundance of these six atoms causes them to act as information points.

Today I would like to add something else to "The Rule Of Common Atoms". There are six basic measurable entities and this is because of the six common atoms, CHNOPS, in the same way as colors and biological kingdoms.

According to the Wikipedia article, SI Base Unit, there are seven basic measurables. These are time, measured in seconds, distance, measured in meters, mass, measured in kilograms, temperature, measured in Celsius or Kelvin, electricity, measured in amperes, amount of substance, measured in moles, and luminous intensity, measured in candelas.

But a mole is simply a number of atoms, actually 6.02 x 10 raised to the 23rd power, of atoms or molecules. This many atoms or molecules of an element or substance will have a mass in grams of it's atomic weight or molecular weight. But that means that the mole is related to the unit of mass, gram or kilogram, and thus is not an entirely separate measurable unit. That leaves us with six basic measurable units, the same number as the common atoms represented by the acronym CHNOPS.

All of the other units that we use to measure, such as meters per second, miles per hour, or newton-meters, are combinations of these fundamental units or their English equivalents.

But what my theory of "The Flow Of Information Through The Universe" points to is that, like the colors, we see these six basic measurables in the universe not really because of what it is but because of what we are. We are more complex than our surrounding universe of inanimate matter and, when we measure anything, we are projecting our complexity onto it and it is reflected back at us, specifically the information brought about by the six common atoms.

The universe is actually only negative and positive electric charges but we have our own scale and perspective when we look at the universe, and this adds information.

My cosmology theory, "The Theory Of Stationary Space", which is separate from this theory about "The Flow Of Information Through The Universe", reveals that time is actually something that is within us and not the inanimate universe around us. Distance is simply the number of electric charges in a straight line in space. Electric charge, in amperage, involves the concentration of like charges in matter. Temperature, the energetic movement of atoms and molecules, is a function of time and distance like any other velocity but we perceive it as heat, rather than the kinetic motion that it is, because of our relative scale perspective.

Luminosity is a function of electric charge since space is, according to my cosmology theory, composed of a multi-dimensional checkerboard of alternating negative and positive electric charges. But, once again, we see it as light, and other electromagnetic radiation, due to our scale perspective. The checkerboard of alternating electric charges ordinarily balances out to zero but we see the waves as electromagnetic because they disturb this underlying balance.

This means that length, electric charge and, mass are all really the same thing. We see it in the different forms that we measure only because we are projecting our complexity on the inanimate universe. The length is the number of charges in a straight line through space. Electric charge is the concentration of like charges, held together by energy, in matter. The mass is actually the energy in matter that holds the like charges together against their mutual repulsion, which we express as the well-known Mass-Energy Equivalence. Weight is simply the effect of gravity on mass.

We can thus see that, once again, we see the universe as we do not only because of what it is but also because of what we are. We see these fundamental six measurable entities because we are projecting our own complexity on the less-complex inanimate universe around us. There are six because of the information of the six common atoms, in the same way as the fundamental colors and the "kingdoms" into which living things are classified.

9) THE 720 DEGREE CIRCLE

This has been added to the compound posting, "Measurement" September 2021.

A circle is divided into 360 degrees. If we had defined an angular degree so that it is half as wide as it is now there would have been 720 degrees in a circle. I am surprised that we didn't do this.

An angular degree is not something that most people would be immediately familiar with. The first example that would occur to many people is that 360 degrees divided by the 12 hours on a clock means that there are 30 degrees between each hour number on the clock.

The sun and the moon are of about the same angular diameter in the sky, about half degree. The diameter of the sun is 400 times that of the moon but it is also 400 times as far away as the moon. The sight of the sun and moon in the sky is something that everyone can immediately relate to.

If we divided a degree in half, so that there would be 720 degrees in a circle, the angular diameter of the sun or moon would be just about exactly one degree. It wouldn't be precise because neither the sun nor moon are at a perfectly consistent distance from earth. But I think the angular diameter of the sun and moon would have been an obvious choice for the unit of measure of angular diameter.

The 360 degree circle is rooted in ancient Babylon, which also paid a lot of attention to astronomy. Maybe if the astronomical community and the mathematical communities had hung out together we might be using a 720 degree circle today.

10) CHART NAMES

For most of human history the vast majority of people have lived in relatively small communities. They knew virtually all of the people that they interacted with. In recent times that has definitely changed. Not only is there more people but the size of cities has grown exponentially. With more moving around knowing the people that we are interacting with is getting to be more the exception than the rule.

First names, such as James, William, Mary, Charles, and so on, are useful only as long as we are dealing with people that we know. A first name doesn't tell you much about a person, other than whether they are male or female and maybe their ethnicity. First names are from the days when people knew most of those that they would interact with.

What if we could make first names more useful? We could do that if names could tell us more about a person, specifically what they looked like.

Suppose that you are working behind a counter and there are thirty people in the room in front of you. You see the person that you are looking for but don't know their name. How would you get their attention? You could shout out "sir" or "ma'am", until they looked your way, but that would disturb everyone in the room.

You see someone fleeing and suspect that they have committed a crime. How would you very quickly describe what they look like? 

You send a driver to give someone a ride from an event, but the driver and rider don't know each other. How would you quickly give the driver an idea of who to look for, considering that there might be a hundred people there and a photograph of a person often isn't a good guide to recognition?

You are writing a story and describing what a person looks like. Describing how a person looks is often a laborious process, don't you wish there was an easier way?

So much nowadays has been categorized, to make identification or computer programming easier. The categorization is usually done with numbers, every shade of every color has been assigned a number for example. Why couldn't we categorize what people look like, not by number but by name?

We could make up a chart with drawings or photographs of three hundred different people. Half would be male and half female. They would all look different from one another. One or another of the people on the chart would have every different combination of race, general height, general body structure, general ethnicity, skin tone and, hair color. Everyone in the world would fairly closely resemble one of the people on the chart.

Next we would give everyone on the chart a first name. The name of the person on the chart that you most closely resembled would be your "Chart Name". You wouldn't need to give the name to anyone because it would be obvious by just looking on the chart. But you would look up if anyone called the name. Hard copy charts could be posted on walls in offices and charts could easily be standard features on phones.

The reason this hasn't already been done is that classifying people by their physical features hints at racism. This is not any scientific classification of how people look, it is just for the purpose of recognition. We could also do the classification by numbers but I think it would be better to have a name to call to get someone's attention. The purpose of this is recognition at a distance, and so we probably wouldn't include eye color.

The examples of people on the chart would be in their prime. A general age could also be specified, including if it was a child. Possibly a separate chart of children could be made. It would not include anything uncomplimentary or readily subject to change, or whether the person was disabled in any way. 

It would not include any reference to excess weight or baldness or wrinkles. The description would be of the person whole and in their prime. It would have no reference to hairstyle and a person's Chart Name would change if they changed their hair color.

This will not only be helpful in crime fighting, making possible a quick description of a person and bringing up an image resembling the person, but will also cut down on fraud since a person's facial photograph often doesn't look a lot like them, especially if it was taken some time ago.

11) NEW UNITS OF MEASUREMENT

This has been added to the compound posting "Measurement", November 2021.

Units of measure, for length, area, and so on, would be more useful if we could relate to them. This was originally the idea. The yard was based on the length of a king's arm. The mile was when the left foot of a marching soldier had touched the ground a thousand times. The meter was originally supposed to be one ten-millionth of the distance from the equator to the north pole, along the line of longitude that passes through Paris, but has since been redefined by wavelengths of light.

However most of this relatability has since been lost. Acres are widely used as a measure of land area. But how many people seriously know what an acre is? It started as the area that a farmer could usually plow in a day. Below is an acre against a nearby parking lot, where you can see the cars and parking spaces.

Image from Google Earth.

The modern era, particularly cars, has brought the possibility of a new set of units that are easily relatable to everyone. Units of length are the primary unit of measurement, being squared or cubed to form units of area and volume. In the Metric System mass is also based on length, and water, a liter of water weighs a kilogram.

When you turn on the heat or the radio in a car you probably turn a knob. These knobs seem to all be of a standard size and the width of one would make an ideal unit of measurement that everyone could easily relate to.

Then there is the steering wheel, which also come in standard sizes. This would be the most ideal and relatable length unit of all.

The next higher unit of length could be the width of a lane on a highway, again something that is very familiar to everyone.

We could form units of area by simply squaring the units of length. But probably the most familiar unit of area is also automotive in origin. What would be better for a general unit of area than a standard parking space?

Just another thought about measurement, but this is not related to cars. We now know that the universe overall is a very cold place. The average temperature in the universe overall is believed to be 2.726 degrees Kelvin, although that may not be an extremely precise figure.

Kelvin is the temperature scale that begins at Absolute Zero. Heat is the energy of moving atoms and molecules. When something cools down it's atoms and molecules move more slowly. If cooling continued so that all motion stopped it would not be able to get any colder. This point is known as Absolute Zero and is equivalent to -459 degrees Fahrenheit or -273.16 degrees Celsius.

The Celsius scale is defined by the melting and boiling points of water. Water freezes at zero degrees Celsius and boils at 100 degrees Celsius.

This means that the freezing point of water is at 273.16 degrees Kelvin, since a Kelvin degree is the same size as a Celsius degree. Notice that the average temperature of the universe is just about exactly one percent of the freezing point of water, starting at Absolute Zero, and the figure for the average temperature may not be perfectly accurate.

The size of a Celsius degree is one-hundredth of the span between the freezing and boiling points of water. Now that we are in the Space Age, and cosmology is becoming ever more important, why don't we define the average temperature of the universe as one degree? Water will then freeze at 100 degrees and boil at 136.89 degrees.

The freezing and boiling points of water are not as precise as it may seem. The freezing point depends on the purity of the water. The salt water in the sea does not freeze at zero degrees Celsius. The boiling point of water is dependent on the atmospheric pressure.

Saturday, September 11, 2021

Tribute To New York City

As I do my writing here I have my souvenir model of the Empire State Building to remind me how fortunate I am to live in the same state with this great city.

On this twentieth anniversary of 9/11 I would like to express solidarity with New York City, on behalf of those of us upstate in the Buffalo area. New York is stronger than ever and this attempt to damage it was a complete failure.

But I still have never been to the Met.

In support of our most important city we are going to be revisiting it on our weekly visits.

NEW YORK CITY RULES!!!

Manhattan

New York City consists of five boroughs, Manhattan, Brooklyn, Queens, the Bronx and, Staten Island. Usually, cities are within counties and there may be several cities in a county. New York is such a large city that each of the five boroughs is a county, so that there are five counties within the city.


You may be seeing three rivers in our scenery. The broad river, over a km wide, is the Hudson River. It separates New York State from New Jersey. The medium river, in some places with an elongated island down the middle of it, is the East River. It separates the boroughs of Manhattan on one side from Brooklyn and Queens on the other side. If you see a very narrow river, it is the Harlem River that separates Manhattan from the Bronx.

The only two of the five boroughs that are not separated by water are Brooklyn and Queens. There are some famous bridges crossing the water in New York City. The George Washington Bridge links Manhattan with New Jersey, across the Hudson River. Also across the Hudson River, the Verrazzano-Narrows Bridge links Brooklyn with Staten Island.

Across the East River, linking Manhattan and Brooklyn are three old and venerable bridges. There is the Williamsburg Bridge, the Manhattan Bridge and, the oldest and best-known of all, the Brooklyn Bridge. Further north across the east River, the Queensboro Bridge joins Manhattan and Queens.

The following scenes begin on Wall Street, in front of Federal Hall. The statue is of George Washington, America's first president. When New York was briefly the country's capital, the Federal Hall is where he was sworn in as president. Next to Federal Hall is the Trump Building. Just around the corner, the building with the pillars is the New York Stock Exchange. In the general scenes of Lower Manhattan, the tallest building is One World Trade Center.

This is the New York Stock Exchange.

http://photos1.blogger.com/blogger/5492/3756/1600/dc_250976.jpg

There are multiple scenes following. To see the scenes, after the first one, you must first click the up arrow, ^, before you can move on to the next scene by clicking the right or forward arrow, >, After clicking the up arrow, you can then hide the previews of successive scenes, if you wish.

https://www.google.com/maps/@40.7068013,-74.0106861,3a,75y,41.61h,90t/data=!3m6!1e1!3m4!1sLmmJ1kdQlvjjvqhv8g9GcQ!2e0!7i13312!8i6656

These views begin at the arch on Washington Square. What is so significant about this arch is that it is where Fifth Avenue begins. Fifth Avenue runs the length of Manhattan from here and is the most important street in New York. Fifth Avenue is like the equator, except that it runs north-south, or the meridian of New York. Fifth Avenue separates streets that are east or west. For example, East 34th St. is east of Fifth Avenue and West 34th St. is west of Fifth Avenue. The address numbers get higher as you move away from Fifth Avenue. Fifth Avenue also defines the east side of Central Park, which is the large rectangular park on Manhattan.

One of the most famous intersections is Fifth Avenue and 33rd St. This is the address of the Empire State Building, and formerly "The Waldorf Astoria", as we saw in the posting by that name.

http://photos1.blogger.com/blogger/5492/3756/1600/dc_250977.jpg


https://www.google.com/maps/@40.7314038,-73.9970254,3a,75y,118.64h,90t/data=!3m7!1e1!3m5!1sboXldW2Hnbz0Xnlfm1X-jA!2e0!6s%2F%2Fgeo1.ggpht.com%2Fcbk%3Fpanoid%3DboXldW2Hnbz0Xnlfm1X-jA%26output%3Dthumbnail%26cb_client%3Dmaps_sv.tactile.gps%26thumb%3D2%26w%3D203%26h%3D100%26yaw%3D125.77827%26pitch%3D0%26thumbfov%3D100!7i16384!8i8192

Here is another arch. It is the entrance from the Manhattan side to the Manhattan Bridge, the bridge to Brooklyn. The Manhattan Bridge has steel towers supporting the suspension bridge. The older bridge nearby, with stone towers, is the Brooklyn Bridge. Almost all of the bridges in New York City are suspension bridges.

https://www.google.com/maps/@40.7155227,-73.9952449,3a,75y,75.61h,90t/data=!3m7!1e1!3m5!1s-fx2d6yh9wBadLQ5Ei8LZA!2e0!6s%2F%2Fgeo2.ggpht.com%2Fcbk%3Fpanoid%3D-fx2d6yh9wBadLQ5Ei8LZA%26output%3Dthumbnail%26cb_client%3Dmaps_sv.tactile.gps%26thumb%3D2%26w%3D203%26h%3D100%26yaw%3D71.29613%26pitch%3D0%26thumbfov%3D100!7i16384!8i8192

Much of the East Village, on the Lower East Side of Manhattan looks like it did a hundred years ago. The first of the following scenes is where the 2015 natural gas explosion took place. With property prices as they are in New York, vacant lots don't last long and the two-story modern concrete building has since been put on the site.

https://www.google.com/maps/@40.7285569,-73.9877316,3a,75y,187.6h,90t/data=!3m7!1e1!3m5!1smJcbAXclnjjNr6SrJawaPw!2e0!6s%2F%2Fgeo0.ggpht.com%2Fcbk%3Fpanoid%3DmJcbAXclnjjNr6SrJawaPw%26output%3Dthumbnail%26cb_client%3Dmaps_sv.tactile.gps%26thumb%3D2%26w%3D203%26h%3D100%26yaw%3D185.77257%26pitch%3D0%26thumbfov%3D100!7i16384!8i8192

These scenes begin on what is known as the Park Avenue Viaduct. Park Avenue is an important north-south street in New York. Fifth Avenue, Madison Avenue, Park Avenue and, Lexington Avenue are adjacent and parallel to one another. The Park Avenue Viaduct takes Park Avenue around Grand Central Station. or Grand Central Terminal. The other great rail station in the area is Penn Station, but that is underground beneath Madison  Square Garden. This is near the Chrysler Building, which was briefly the tallest building in the world, after the Trump Building that we have seen, and before the Empire State Building.

Remember that avenues run the long north-south length of Manhattan and the much-shorter streets run the east-west width. All are numbered but there are naturally many more streets than avenues. Some of what would be the numbered avenues running north-south have been given names, and some were added later. Park Avenue is really Fourth Avenue, and Madison Avenue is between Park and Fifth Avenues. Lexington Avenue is between Park Avenue and Third Avenue. The Avenue of the Americas is really Sixth Avenue.

This area is known as Midtown Manhattan. It is further north than Lower Manhattan, which we have already seen, but not as far north as Central Park.

https://www.google.com/maps/@40.7528736,-73.9764423,3a,75y,208.33h,90t/data=!3m7!1e1!3m5!1sCGsJUvt3rYL3-n66oKbmSg!2e0!6s%2F%2Fgeo3.ggpht.com%2Fcbk%3Fpanoid%3DCGsJUvt3rYL3-n66oKbmSg%26output%3Dthumbnail%26cb_client%3Dmaps_sv.tactile.gps%26thumb%3D2%26w%3D203%26h%3D100%26yaw%3D202.21193%26pitch%3D0%26thumbfov%3D100!7i16384!8i8192

Many people would say that the real heart of New York City is Times Square. The streets of Manhattan are set up as a grid pattern. But Broadway runs diagonally across Manhattan, from southeast to northwest. The Theater District of Broadway, sometimes called "The Great White Way", is along the part of Broadway that runs through Midtown Manhattan.

Important squares and parks are located where Broadway crosses the numbered avenues that run north-south. Times Square is where Broadway meets Seventh Avenue. Madison Square is where Broadway meets Fifth Avenue. The original Madison Square Garden, an arena and sports stadium, was there but the current one is not. The current Madison Square Garden is atop Penn Station which, along with Grand Central Station, are the two most important transportation hubs on Manhattan.

https://www.google.com/maps/@40.7572004,-73.9850507,3a,75y,336.56h,120t/data=!3m8!1e1!3m6!1sAF1QipMqvlDkLzTDmD9TfsQ2Do10dGiTNZ2mCx6e2aOd!2e10!3e11!6shttps:%2F%2Flh5.googleusercontent.com%2Fp%2FAF1QipMqvlDkLzTDmD9TfsQ2Do10dGiTNZ2mCx6e2aOd%3Dw203-h100-k-no-pi-30.000002-ya327.55728-ro-0-fo100!7i8704!8i4352

Just a short distance from Times Square, but very different, is Rockefeller Plaza. It is known for the very wealthy family by that name. This is also not far from the Empire State Building. If you see a view with people on an observation deck on the roof of a building, that is "The Top of the Rock", the roof of Rockefeller Center.

We could say that the Empire State Building represents "The Roaring Twenties", when the economy was booming and when it's building began, and the complex of buildings known as Rockefeller Center was built after the economy had crashed. The building style of this complex, as well as the Empire State Building, is known as Art Deco. Another famous place nearby that you can see is Radio City Music Hall.

https://www.google.com/maps/@40.7589743,-73.9786444,3a,75y,193.14h,90t/data=!3m7!1e1!3m5!1sGiPwKuNBGJL5Q_QJjgYY4A!2e0!6s%2F%2Fgeo1.ggpht.com%2Fcbk%3Fpanoid%3DGiPwKuNBGJL5Q_QJjgYY4A%26output%3Dthumbnail%26cb_client%3Dmaps_sv.tactile.gps%26thumb%3D2%26w%3D203%26h%3D100%26yaw%3D190.03044%26pitch%3D0%26thumbfov%3D100!7i13312!8i6656

There are not only bridges spanning the water in New York City, there are also tunnels. The following scenes begin in the Queens Midtown Tunnel. As the name implies, it connects the borough of Queens to Midtown Manhattan by going under the East River. Just on the Manhattan side of the tunnel is the Headquarters of the United Nations.

https://www.google.com/maps/@40.7466094,-73.9663093,3a,75y,25.44h,90t/data=!3m5!1e1!3m3!1shOK4XMvO2lToGfLl1WxBjQ!2e0!6s%2F%2Fgeo2.ggpht.com%2Fcbk%3Fpanoid%3DhOK4XMvO2lToGfLl1WxBjQ%26output%3Dthumbnail%26cb_client%3Dmaps_sv.tactile.gps%26thumb%3D2%26w%3D203%26h%3D100%26yaw%3D19.817352%26pitch%3D0%26thumbfov%3D100

The area adjacent to Central Park, but to the east of the park, is known as the Upper East Side. The Metropolitan Museum of Art is actually right in Central Park, on Fifth Avenue which forms the eastern boundary of the vast rectangular park. There are other museums on this stretch of Fifth Avenue and it is known as Museum Mile. The following scenes begin inside the Metropolitan Museum of Art, or simply "The Met".

https://www.google.com/maps/@40.7799163,-73.9631245,2a,75y,290.87h,90t/data=!3m7!1e1!3m5!1seRZNVE7ZgwRGJE66tijkmA!2e0!6s%2F%2Fgeo2.ggpht.com%2Fcbk%3Fpanoid%3DeRZNVE7ZgwRGJE66tijkmA%26output%3Dthumbnail%26cb_client%3Dmaps_sv.tactile.gps%26thumb%3D2%26w%3D203%26h%3D100%26yaw%3D296.71994%26pitch%3D0%26thumbfov%3D100!7i5632!8i2816

If the area of Manhattan adjacent to Central Park, but to the east of it, is called the Upper East Side, you will never guess what the area to the west of Central Park is called.

It is called the Upper West Side. Whenever you see "Upper" in Manhattan, it means on either side of Central Park. The following scenes begin in the Lincoln Center for the Performing Arts. You may notice that, as we go further north in Manhattan, the average height of the buildings gets lower. That means that the price of land is lower. If someone cannot afford to live in Midtown or Lower Manhattan, maybe they could afford to live here.

https://www.google.com/maps/@40.7723557,-73.983495,3a,75y,90t/data=!3m8!1e1!3m6!1sAF1QipPtiGG81kkJHhXx8F6Kd1lwt7Amf3imVqcYAPh8!2e10!3e11!6shttps:%2F%2Flh5.googleusercontent.com%2Fp%2FAF1QipPtiGG81kkJHhXx8F6Kd1lwt7Amf3imVqcYAPh8%3Dw203-h100-k-no-pi0.49998096-ya0.0043633785-ro-0.5000191-fo100!7i7776!8i3888

The northern part of Manhattan is known as Harlem. Between the Upper West Side and Harlem is Columbia University. The most famous location in Harlem is the Apollo Theater. The reason that it is so famous is that so many famous entertainers got their start there. So many stars have gotten their start in the Apollo that maybe it should be renamed "The Galaxy". I think that Motown, during the 1960s, was trying to copy this in Detroit. I cannot control the ads that get mixed in with the scenes.

https://www.google.com/maps/@40.8037391,-73.941867,3a,75y,129.11h,90t/data=!3m7!1e1!3m5!1sB9HcU_t-Rk8C0kQy755gBw!2e0!6s%2F%2Fgeo2.ggpht.com%2Fcbk%3Fpanoid%3DB9HcU_t-Rk8C0kQy755gBw%26output%3Dthumbnail%26cb_client%3Dmaps_sv.tactile.gps%26thumb%3D2%26w%3D203%26h%3D100%26yaw%3D137.0386%26pitch%3D0%26thumbfov%3D100!7i16384!8i8192