Computing in schools

Recently I have heard of a new As or A level computing course that I want to try and find out more about as a Governor with a special interest in Engineering and Technology.

Today 8 July 2015 I read about an announcement of a new BBC computer  using Scratch from MIT I think. I will have to see if my school has a link with a middle school where I can get involved and learn about this.   http://www.bbc.co.uk/news/technology-33409311

5 January 2016:
This new BBC Micro Bit has been delayed yet again.

4 April. Maybe it is out now:
http://www.techradar.com/news/computing/bbc-micro-bit-10-things-you-need-to-know-1298581

Data comm-s packet Switching in Bournemouth

I was talking to my friend Russ ( http://btckstorage.blob.core.windows.net/site8867/Journals/2006/J06%20Pg%2037-39.pdf)  at Stewarts (http://www.stewarts.co.uk/our-garden-centres/coffe-shop/coffee-shop-broomhill/)  the other morning about my  life  in Data Comms, and he was telling me that there had been an early meeting about something to do with the development of Packet Switching in Bournemouth. I am trying to find out something about that. So far, because of my reading about Turing  after we had seen the movie about him, I did come across a reference to one of the pioneers in packet switching who also worked on the ACE machine in Manchester with Turing:  http://www.rutherfordjournal.org/article040101.html#davies
Donald Davies is acknowledged to be the inventor of packet switching.

Russ mentioned a guy called Ray Henville at Blandford Camp, but as yet I cannot tie them together.
I have found a Kevin Ray Henville born 1959 who is interested in Antique radios as Russ is, and one who worked on early computers at Irton Moor, who must have been significantly older.

So, keep digging.


http://www.livinginternet.com/i/iw_packet_inv.htm

from Wikipedia:

The concept of switching small blocks of data was first explored independently by Paul Baran at the RAND Corporation in the US and Donald Davies at the National Physical Laboratory (NPL) in the UK in the early to mid-1960s.^{Abbate 2000}

Leonard Kleinrock conducted early research in queueing theory which proved important in packet switching, and published a book in the related field of digital message switching (without the packets) in 1961; he also later played a leading role in building and management of the world's first packet-switched network, the ARPANET.

Baran developed the concept of message block switching during his research at the RAND Corporation for the US Air Force into survivable communications networks, first presented to the Air Force in the summer of 1961 as briefing B-265^[3] then published as RAND Paper P-2626 in 1962 and then including and expanding somewhat within a series of eleven papers titled On Distributed Communications in 1964. Baran's P-2626 paper described a general architecture for a large-scale, distributed, survivable communications network. The paper focuses on three key ideas: first, use of a decentralized network with multiple paths between any two points; and second, dividing complete user messages into what he called message blocks (later called packets); then third, delivery of these messages by store and forward switching.

Baran's study made its way to Robert Taylor and J.C.R. Licklider at the Information Processing Technology Office, both wide-area network evangelists, and it helped influence Lawrence Roberts to adopt the technology when Taylor put him in charge of development of the ARPANET.

Baran's work was similar to the research performed independently by Donald Davies at the National Physical Laboratory, UK. In 1965, Davies developed the concept of packet-switched networks and proposed development of a UK wide network.^[4] He gave a talk on the proposal in 1966, after which a person from the Ministry of Defence (MoD) told him about Baran's work. A member of Davies' team (Roger Scantlebury) met Lawrence Roberts at the 1967 ACMSymposium on Operating System Principles, bringing the two groups together. Scantlebury urged Roberts to use the highest speeds possible to reduce latency.

Davies had chosen some of the same parameters for his original network design as Baran, such as a packet size of 1024 bits. In 1966 Davies proposed that a network should be built at the laboratory to serve the needs of NPL and prove the feasibility of packet switching. The NPL Data Communications Network entered service in 1970. Roberts and the ARPANET team took the name "packet switching" itself from Davies's work.

The first computer network and packet switching network deployed for computer resource sharing was the Octopus Network at the Lawrence Livermore National Laboratory that began connecting four Control Data 6600 computers to several shared storage devices (including an IBM 2321 Data Cell^[5] in 1968 and an IBM Photostore^[6] in 1970) and to several hundred Teletype Model 33 ASR terminals for time sharing use starting in 1968.^[7]

In 1973, Vint Cerf and Bob Kahn wrote the specifications for Transmission Control Protocol (TCP), an internetworking protocol for sharing resources using packet-switching among the nodes.

And Lawrence Roberts  I recognize, I think it is possible that he was in Telenet corporation. Here is his writeup on it: http://www.packet.cc/files/ev-packet-sw.html

This report is US biased I think: http://ethw.org/Packet_Switching

This report is about the UK Network  created at NPL:
http://www.computer.org/cms/Computer.org/Computer.org/ComputingNow/computingthen/atty/1988/CT_1988-1_DataCommunications.pdf
It used the Plessey XL-12 initially  whose successor was built at Plessey Christchurch, so there may have been discussions in Bournemouth.

Here's more about Donald Davies: http://ethw.org/Oral-History:Donald_Davies_%26_Derek_Barber
I like this comment from here:
Donald would probably know more about that,  But what I was trying to say was that because of that coming together of one big department, they wanted to focus amongst other things the computing industry. And that's why, when we tried to use the Plessey latest machine [for the NPL network], which just would have been ideal, we were told, "No, the Ministry policy is: we want to support ICL, you will not use that, you don't have to use that, etc." And of course when we wrote down the spec and looked around, the next best machine was a Honeywell 516. If we had gone for the Plessey XL-12, which was actually a much better machine, architecturally, than the 516, the whole story could have been quite different. But such is the way decisions are made in ministries.


 A last compendium:   http://rogerdmoore.ca/PS/

From the book  "Intercept" about computing, cryptography and spying, it states that Donald Davies wrote a paper on packet switching and when the US designed theirs for Arpanet, his document was well thumbed and worn.

To Annabelle

I had to write a poem
But I couldn't do it at home
So I went to the playground
And thought as I spun round and round
I've got to write a poem
but I can't do it at home.
This poem is going round and round
so home and to bed
and it goes around in my head.

More Merchant Family History

This family history is intriguing. From Rootsweb for Essex I recently saw that someone was looking for the Linnet family and responded. Sarah Linnet(widow) is my Great-great-grandmother. She married William Marchant in 1808.

What has come out of Rootsweb and other sources is that she was born Sarah Smyth in about 1782, and married Joseph Linnet (or Linnot) in 1802. He died in January 1807. Meanwhile she had a son William in early 1802, and we can only assume that Joseph was the father. Later they had a daughter Phoebe in 1806.

I wonder if young William died, because in 1815 Sarah and William had a son who they called William.

I have found a Pheba Sargeant age 30 in the 1841 census living only about 10 miles away, and I wonder if this was Phoebe.

It's a shame that I can't find anything more about the family in the early 1800's, because that would be nice to flesh them out a bit. Did Phoebe grow up a Merchant, or remain a Linnet?

Does this mean that I have more branches of relatives around?  

Consider this an unfinished blog, because I will flesh it out (Hah!) as I learn more.

2020 More

When William and Sarah went to Hockley I surmise that Phoebe went with them, as she married John Smith on 18 October 1824 in Hockley.

John and Phoebe had three children

Elizabeth (1832

Phebe ( 1839

Ann (1843 -

Elizabeth married William Walley on 4 April 1856

Phebe married William Camper in 8 November 1863

After the death of William Merchant, (1770-1853) Sarah (1782-1863) lived with the Walley family until her death.

In 1891 Phebe Smith was living with the Walleys as a Widow. (Age 83)

Thinking about God

I was thinking about God this morning. It probably was because I was speaking to my old Friend Ed G. last night and he seems to be quite religious. It started when I was getting the car out of the garage and looked at the wheels. They have 5 (or 6) spokes and they were designed by someone somewhere. They are not beautiful. And I thought of all the things in nature that have repetitive geometry and how beautiful they are, as works of God. Even down to the hated dandelion, it has a beautifully shaped puffball of seeds, and if you look at each individual seed it is a work of art.

Then I looked at my bicycle because that is what I was really going for. It looks so good. It is a wonderful fusion of engineering, craftsmanship, and art. The person who put it together must have sat back and had a tremendous rush of satisfaction, a real feeling of being with God.

So I went for a ride and thought about those thoughts, and the sun beaming through the trees, and came home and wrote this.  

Ukip Proposals

UKIP Proposals

Reduce foreign aid budget by at least 1% of GDP, and apply this to the armed forces. Most people will like the first and Obama will certainly like the second. Make the army responsible for supplying foreign aid. This means that we have not really reduced foreign aid, we are just supplying it in the form of personnel and skills. How do we get the skills? The army opens up training centres and universities and gives apprenticeships to the young. That helps the unemployment situation. Most people will like that.

If you build up medical training facilities, then you can train nurses who can help with foreign aid, or if they leave, go into the public service. Then we do not need to import so many nurses. Most people will like that.

If the army trains teachers, they could then leave and go into the public sector after doing some foreign aid. Personally I think that many schools could do with a bit of military ethos in educating the young.

The army is becoming ever more high-tech, especially in the need for counter-espionage and cyber warfare. Training of people in these disciplines would help keep Britain in the lead of high technology development. Another winner.

So overall, I have redirected the foreign aid budget to help build Britain, with no reduction in actual foreign aid, just a reduction in the number of Mercedes being bought by despots.

Nice to have a brother who knows great scientists

And from the Daily Telegraph Obituaries 29 January 2015

Charles Townes, Nobel Prize winner - obituary

Physicist who developed a forerunner of the laser and won the Templeton Prize for religion

Charles Townes in 1964 Photo: The LIFE Images Collection/Getty

Charles Townes, who has died aged 99, earned the unusual distinction of winning both the Nobel Prize for Physics, for his work on the theory and application of the maser (the forerunner of the laser), and the Templeton Prize for Progress in Religion.

Townes’s belief that science can be reconciled with a belief in God stemmed from his own career as a physicist. When in 1951 he suggested that microwaves could be used to make ultra-precise measurements in the laboratory, he was told by Niels Bohr, the pioneer of quantum mechanics, that he was wasting his time. His head of department at Columbia University, the Nobel laureate Isidore Rabi, also told him to forget it. Yet he refused to give up.

Townes had first became involved with microwave technology during the Second World War when he worked at Bell Laboratories on the design of radar bombing systems. After the war, he turned his attention to applying microwave techniques to spectroscopy, which he saw as a potential tool for the study of the structure of atoms and molecules and for controlling electromagnetic waves.

In 1951 he conceived the idea of a new way to amplify microwaves, by stimulating excited molecules to emit radiation. Three years later, he and his assistants built the first “maser” (an acronym for “microwave amplification by stimulated emission of radiation”). An intense flurry of research followed. Masers have limited applications, although they are used in atomic clocks and as electronic amplifiers in radio telescopes. It was Townes’s brother-in-law, Arthur Schawlow (who would win the 1981 Nobel Prize for Physics), who in 1957 set the ball rolling for the more revolutionary “laser” when he began wondering if the maser principle could be extended to light waves instead of microwaves.

The two men bounced ideas back and forth and decided that potassium vapour might be a suitable medium. Together they wrote a paper outlining the principles of “Infrared and Optical Masers” (now known as lasers – light amplification by stimulated emission of radiation), which appeared in Physical Review in December 1958.

Townes and Schawlow received the first laser patent, but made little profit from their discovery. Early in their research Townes had talked to Gordon Gould, a Columbia graduate student who subsequently wrote up his own ideas for a laser and was granted the patent rights in 1973. The US Court of Customs and Patent Appeals ruled that the patent awarded to Schawlow and Townes had been too general, and did not supply enough information to create certain key components of the laser.

^{Charles Townes (left) and J P Gordon presenting their atomic clock in 1955 (ROGER VIOLLET)}
Townes often cited his discovery of the principles of the maser — an insight that had occurred to him as he sat on a park bench in Washington DC — as a “revelation” akin to a religious experience, and he was often teased by his scientific colleagues for his religious beliefs. In 1966 he published a seminal article, “The Convergence of Science and Religion”, which established him as a unique voice in seeking common ground between the two disciplines. “My own view is that, while science and religion may seem different, they have many similarities, and should interact and enlighten each other,” Townes wrote.
After learning that he had won the Templeton Prize in 2005, Townes explained that his views arose out of his perception that science, like religion, embodies paradoxes which can only be resolved by acts of faith. “There are many mysteries still in science, many mysteries and inconsistencies. Quantum mechanics is inconsistent with general relativity… So what do we do? Physicists just accept it. They believe in both. I think that’s what we have to do in life, recognise there are inconsistencies, places we don’t understand. We have to accept the mysteries and proceed.”
One of six children, Charles Hard Townes was born at Greenville, South Carolina, to Baptist parents on July 28 1915. His father was a lawyer. He was educated at local schools and at Furman University, a Baptist college in Greenville where he took degrees in Physics and Modern Languages and served as curator of the university’s natural history museum.
After taking a master’s degree in Physics at Duke University in 1936 he went on to the California Institute of Technology (Caltech) where he took a doctorate on isotope separation and nuclear spins.
In 1939 Townes became a member of the technical staff at Bell Laboratories, where he specialised in microwave generation, vacuum tubes, and solid-state physics. The radar bombing systems which he developed during the Second World War proved particularly effective in the humid conditions of the Pacific theatre.

^{Charles Townes in 1961 (The LIFE Picture Collection/Getty)}
In 1948 Townes moved to the Physics department of Columbia University, where he became a full professor in 1950. His research continued to be partly funded by the US Navy, which wanted radar systems with smaller wavelengths. This led him to focus on microwave research. He served as executive director of the Columbia Radiation Laboratory from 1950 to 1952 and was chairman of the Physics department from 1952 to 1955.
In 1961 Townes was appointed Provost and Professor of Physics at the Massachusetts Institute of Technology (MIT). In 1966 he became Institute Professor and resigned the provostship in order to return to more intensive research in quantum electronics and astronomy. He went on to look for radiation from molecules in outer space and later became a champion of the search for extraterrestrial intelligence . He was appointed University Professor at the University of California at Berkeley in 1967.
Townes served on a number of scientific committees, notably as chairman of the advisory committee for the first human landing on the moon, and later as chairman of a US Defense Department committee which advised President Ronald Reagan against the deployment of the contentious MX missile system in 1982.
In addition to the Templeton Prize and the Nobel Prize, which he shared with two Russian scientists in 1964, Townes was appointed an Officer of the French Légion d’honneur in 1990, and was the recipient of the Niels Bohr International Gold Medal and nearly 100 other honours and awards. His scientific autobiography, How the Laser Happened: Adventures of a Scientist, was published in 1999.
Charles Townes married, in 1941, Frances Brown, with whom he had four daughters.

Charles Townes, born July 28 1915, died January 27 2015 

Notes from viv: The awarding of the Nobel prize to Townes was very controversial, because they didn't build a laser, only discussed it and laid out some of the principles of the laser.  They were very familiar with the spectroscopy of Ruby crystal (because that's what the maser was made from) and said that it would never work as a laser.

 

But Ted Maiman at Hughes Research did more careful measurements of the spectroscopy of Ruby and lo and behold made a laser out of it.  The first operating laser.  but he didn't get the Nobel prize.

 

It's said that he didn't get the prize because he worked for a company rather than for a university or a government. 

 

I've seen Ted Maiman's notebook , it's in the archives at the Simon Fraser University library.  He ended his career there as an adjunct professor.

 

Goodbye Guildford

After 15 years of association with Guildford, we are now finished there. From the time in 1999 when Madeleine and Michael first attended the University, through both of their degrees, a number of visits to the Royal Surrey Emergency  ward, and all sorts of good things, to now when Michael is taking his wife and new baby Sophie up to live in Manchester. We have got to know the Guildford area quite well, especially the not-quite-so-good areas where they have had student accommodation, like Park Barn and Bellfields. During this period both Uncle Gordon and Auntie Petroula have died, so that is the end of that families  relationship with Guildford. From the start when the children were in Cathedral court and we visited every fortnight to see that they were OK, and of course because we missed them, to now when we stayed in the Premier Inn in order to see Sophie in the Special Care Baby Unit, it has been an enjoyable relationship. I know my way around Guildford quite well now. We have been to concerts every six months becasue Madeleine played her cello with the Guildford Orchestra. Madeleine has done time in the Royal Surrey Hospital, and Michael has been a stalwart of the Ion Beam centre getting his PhD and working with Charlie.

I liked the shopping areas too.

I also associate Guildford with the A31, because that is the nicest run down to the south, with plenty of interesting places to visit such as Jane Austin's house.

I shall miss it.