Silicon ChipThe Fox Report - December 2021 SILICON CHIP
  1. Outer Front Cover
  2. Contents
  3. Subscriptions: PE Subscription
  4. Subscriptions: PicoLog Cloud
  5. Back Issues: PICOLOG
  6. Publisher's Letter
  7. Feature: The Fox Report by Barry Fox
  8. Feature: Techno Talk by Mark Nelson
  9. Feature: Net Work by Alan Winstanley
  10. Project: Easy-to-build Digital AM/FM/SW Receiver by Charles Koslna
  11. Project: Balanced Input and Attenuator for the USB by Phil Prosser
  12. Project: Mini Digital Volt/ Amp Panel Meters by Jim Rowe
  13. Feature: Max’s Cool Beans by Max the Magnifi cent
  14. Feature: KickStart by Mike Tooley
  15. Feature: Circuit Surgery by Ian Bell
  16. Feature: AUDIO OUT by Jake Rothman
  17. Feature: Electronic Building Blocks by Julian Edgar
  18. PCB Order Form
  19. Advertising Index

This is only a preview of the December 2021 issue of Practical Electronics.

You can view 0 of the 72 pages in the full issue.

Articles in this series:
  • (November 2020)
  • Techno Talk (December 2020)
  • Techno Talk (January 2021)
  • Techno Talk (February 2021)
  • Techno Talk (March 2021)
  • Techno Talk (April 2021)
  • Techno Talk (May 2021)
  • Techno Talk (June 2021)
  • Techno Talk (July 2021)
  • Techno Talk (August 2021)
  • Techno Talk (September 2021)
  • Techno Talk (October 2021)
  • Techno Talk (November 2021)
  • Techno Talk (December 2021)
  • Communing with nature (January 2022)
  • Should we be worried? (February 2022)
  • How resilient is your lifeline? (March 2022)
  • Go eco, get ethical! (April 2022)
  • From nano to bio (May 2022)
  • Positivity follows the gloom (June 2022)
  • Mixed menu (July 2022)
  • Time for a total rethink? (August 2022)
  • What’s in a name? (September 2022)
  • Forget leaves on the line! (October 2022)
  • Giant Boost for Batteries (December 2022)
  • Raudive Voices Revisited (January 2023)
  • A thousand words (February 2023)
  • It’s handover time (March 2023)
  • AI, Robots, Horticulture and Agriculture (April 2023)
  • Prophecy can be perplexing (May 2023)
  • Technology comes in different shapes and sizes (June 2023)
  • AI and robots – what could possibly go wrong? (July 2023)
  • How long until we’re all out of work? (August 2023)
  • We both have truths, are mine the same as yours? (September 2023)
  • Holy Spheres, Batman! (October 2023)
  • Where’s my pneumatic car? (November 2023)
  • Good grief! (December 2023)
  • Cheeky chiplets (January 2024)
  • Cheeky chiplets (February 2024)
  • The Wibbly-Wobbly World of Quantum (March 2024)
  • Techno Talk - Wait! What? Really? (April 2024)
  • Techno Talk - One step closer to a dystopian abyss? (May 2024)
  • Techno Talk - Program that! (June 2024)
  • Techno Talk (July 2024)
  • Techno Talk - That makes so much sense! (August 2024)
  • Techno Talk - I don’t want to be a Norbert... (September 2024)
  • Techno Talk - Sticking the landing (October 2024)
  • Techno Talk (November 2024)
  • Techno Talk (December 2024)
  • Techno Talk (January 2025)
  • Techno Talk (February 2025)
  • Techno Talk (March 2025)
  • Techno Talk (April 2025)
  • Techno Talk (May 2025)
  • Techno Talk (June 2025)
The Fox Report Barry Fox’s technology column Not all tech progress is for the better W atchmaker Timex broke new ground in 1994 with the introduction of its DataLink series of digital watches, which very usefully stored user information, like telephone numbers, in on-board memory. In 1997, they added the ‘Ironman Triathlon’ edition to the series and the Ironman name stuck. When introduced, DataLink watches were known as ‘PIM’ watches – ie, ‘personal information managers’. Bill Gates was known as an owner of one, and Microsoft was involved in the project – see image. Timex cleverly enabled DataLink/ Ironman to ‘talk’ to a PC by ‘looking’ at the display screen and decoding data from a sequence of light flashes – rather like a bar code reader. I used one for years, storing essential phone numbers, along with addresses, passport numbers and credit card info dressed up as phone numbers. In 2003, and with the slow flash rate of LCD displays causing transfer problems, the optical system was scrapped. The Timex Ironman DataLink USB did what it said on the tin, and sucked data from a PC via a proprietary USB cable. Memory capacity was bigger, and the system worked very well. New Ironmans are no longer available because everyone and their dog turned to storing personal information on smartphones. I have a couple of The Datalink line shown (left to right): Datalink model 50 (1994), Ironman Triathlon, with the Ironman Triathlon logo on the upper part of the face (1997) and Datalink USB sports edition (2003). The small communication system lens is seen at the top of the face on both the model 50 and the Ironman. Microsoft’s logo appears at the top of the model 50’s display, just under the lens. (Courtesy Tasoskessaris, Wikipedia) Die-cast enclosures: flanged and waterproof Learn more: hammfg.com/small-case More than 5000 standard stocked enclosure designs uksales<at>hammfg.com • 01256 812812 8 Practical Electronics | December | 2021 beat-up DataLink USB devices that still work, but only when their ‘sticky’ control buttons can be persuaded to respond reliably. I liked ‘em! I wish I could buy a new Ironman. Why? Because although I can buy any number of smart watches that ‘talk’ (by Bluetooth) to their smartphone, I have so far been unable to find one that can store anywhere near as much useful data as the old Ironmen. Usually, smart watches only cater for a dozen or so phone numbers. Perhaps some of our smart readers will have had more luck? If so, do please share the good news. More is less Instead of storing data, the new breed of smart watches boasts all manner of detailed health checks and analysis. One of their favourite tricks is to measure how far the wearer has walked. The top-end watch I borrowed (which stores a measly few phone numbers) consistently assures me I have walked far greater distances than I’ve actually travelled. It also measures my heart rate in beats per minute, displays it on the watch face and vibrates alarmingly when the rate goes high. The only problem is that – like distance travelled – the logged heart rate is consistently far higher than BPM measured by traditional methods, such as finger on pulse or blood pressure machine readout. My posh watch usually shows around twice the actual BPM. I have checked this by reading the watch rate while measuring BPM with a blood pressure ‘pod’ in a GP surgery. I have also checked it while a GP is measuring blood pressure and BPM with a surgery sphygmomanometer; and I recently checked the watch readout while being checked by a hospital ECG machine (electrocardiogram). In each case the watch was more or less doubling the actual BPM. I asked the hospital cardiac physiologist who was running the tests, why my smart watch was reading 70 BPM and over, while his ECG equipment was showing a near-steady 44 BPM. Was the watch doing something very clever, perhaps? He sighed, with resigned exasperation, and said with a world-weary tone: ‘It happens all the time. People make medical emergency calls because their watches tell them their heart rate is something like 300 BPM, when actually it’s just a little bit high. Usually all they need do is to stop worrying about what their watch says’. Early professional VTR from the BBC Experimental VERA (Vision Electronic Recording Apparatus) linear VTR developed by the BBC in the 1950s. I n the early 1950s the BBC almost invented the world’s first broadcast quality video recorder. VERA, the Vision Electronic Recording Apparatus, filled a small room and in pre-metric days boasted 20.5-inch spools of half-inch tape, running at 200 inches per second to record 15 minutes Practical Electronics | December | 2021 of 405-line monochrome pictures and mono sound. Two machines were ganged together to make continuous recording possible. Previous attempts at video recording had failed because of the difficulty of capturing low frequencies on tape that had to move fast to capture high frequencies. VERA simultaneously recorded three tracks, two video and one audio. The 3MHz picture signal was split into two bands, one 0 – 100kHz, the other 100kHz to 3MHz. The high band was recorded normally on one track, like very high-fidelity audio. The low-band frequency modulated a highfrequency carrier on the other track. Complicated braking systems were needed to start, stop and rewind the tape without snapping or stretching it. The recording heads were handmade, with insulating material hand sheared from mica sheet. The tape gave best results only after a few dozen playings had polished its surface and improved contact with the heads. The BBC used VERA for a few broadcasts, but dropped the project in 1958 when NEW! 5-year collection 2015-2019 All 60 issues from Jan 2015 to Dec 2019 for just £35.95 i files ready or ediate do nload See page 6 for further details and other great back-issue offers. Purchase and download at: www.electronpublishing.com the UK and Europe adopted a new 625line standard which needed a 5MHz bandwidth. Running VERA faster to achieve this would have reduced recording time to only a few minutes per reel. US company Ampex had by then proved that its Quadruplex recorder, first demonstrated in 1956 under team leader Charles Ginsberg, could record a full hour of 625-line TV on a single spool. It did so by running the tape slowly but mounting the heads on a wheel and spinning them rapidly across the tape width. Although he did not like to talk about it, a young Ray Dolby was part of the Ampex team. Dolby later became famous for Dolby Noise Reduction, but that’s another story. More technology stories and images at: https://tekkiepix.com/stories Practical Electronics is delighted to be able to help promote Barry Fox’s project to preserve the visual history of preInternet electronics. Visit www.tekkiepix.com for fascinating stories and a chance to support this unique online collection. 9