View allAll Photos Tagged automation,
Robotic process automation (RPA) is the use of software package with AI (AI) and machine learning capabilities to handle high-volume, repeatable tasks that previously needed humans to perform. These tasks will embody queries, calculations and maintenance of records and transactions.
RPA software isn’t a part of an organization’s IT infrastructure. Instead, it sits on top of it, enabling a corporation to implement the technology quickly and with efficiency — all while not changing the existing infrastructure and systems.
Quick Here to Know More: www.shrimisri.com/automation-services/
A smart home is more than just a place to live. It’s a place you experience comfort, safety, and simplified living. With our range of smart home products, you can control your home with just a touch from anywhere at any time. Want to know more about smart homes?
Read more about our home automation video
The 'Browne' issue system in a Gloucestershire library in 1991, about to be replaced by the new computer based system (CIRCO from BLCMP). The 'Browne' issue system was the traditional card-based charging system in which a card was transferred from the book to a pocket containing the reader's name. The tickets were then filed in order and retained until the book was returned - a very labour intensive system.
This automation has been installed by our representative company in Bratislava. In this site you can see a complete STAR KIT 200, made up of PS-200, gear motor 24Vdc, 900CT-2-24V, 24Vdc control unit with gradual departure and slowdown in closure and connections for radio insertion, 900RXI-41, receiver 1 channel, fix code, 900LASA-24S, falshing light 24Vdc with antenna.
Generation Automation
Will society benefit from continued industrial automation? Robotics and automated processes are replacing thousands of humans in the workplace, in the main but not exclusively the lower skilled occupations that thousands of individuals and their famillies rely on. My concern is as automated technology advances into various industries and occupations, low-skilled individuals will be left with little or no future employment prospects, it boils down to capitalists who motivated by greed choose automation over people and the enviroment in order to reap more and more monetary rewards.
Automated technologies are beneficial in 'human' high risk work areas, and should be limited to use in these areas, however implementing automated processes in 'human low risk' work areas will result in ever increasing numbers of predominately low-skilled workers being squeezed out of the workplace, this can only lead to a new and impoverished underclass as well as impacting negatively on society.
There will always be a low-skilled workforce demographic within every country in the world, for obvious reasons, so will industrial productivity through increased automation really benefit society or does it just serve corporate greed and profitability? Are future automated processes really progression or will they eventually contribute to the break down of society into a two class system, the wealthy affluent skilled, and the 'underclass' of unskilled (SNLR's) 'Services No Longer Required' poor?
These automated technologies are slowly drip feeding into various roles, occupations and industries, this is deemed progression and is promoted as such through various mediums to the masses by the minority of 'mover & shaker' capitalists?
"Robots do not need jobs, people do!".
Update: 15 April 2010
The flagship library in my home city employed 10 librarians who gave valuable advice and assistance to people of all ages and abilities, they were a great source of information and for many older people they played an important role in their daily social interactions. Eight have now been 'replaced' by an 'automated system' with the only human input being reduced to limited reception cover at busy periods by the two remaining Librarians.
(Q) Is this really progression?
The most recent thing I've made in Automation so far is this 1959 European saloon car.
It's rear engined, rear wheel drive with 69 horsepower, but as its just a few kilograms under a ton, Automation claims it has a top speed of 88 mph, which is just right. I've yet to test this theory in BeamNG, but it survived bumping along over some hills, matched the performance of a similarly rear-engined Skoda 130 GL and sounded pretty nice too.
Automation priced it at around $8000-9000 which is somewhere around £6000-7000, though I think it does everything in present day prices since £6000 in 1959 was a rather hefty amount.
This is a car, called the TRS Ninja, which I made for so far the only Automation/BeamNG competition I've entered. You might think that it was a pretty straightforward affair since once the car is done it's done... right?
Wrong. Once exported to BeamNG, half the parts had a fuzzy white outline around them which I couldn't get rid of because that was the newest glitch that had decided to occur between the two games that week (with every Automation or Beam update something new breaks, this time it was fixture edges and tail lights). I had to live with that as I had no choice, BUT when imported back into Automation the body morphs would reset and some of the details and figures would change, meaning it was no longer within the parameters of the challenge it was made for.
After a long and annoying process of importing, exporting, making copies of cars in Automation and in BeamNG's mod folder I got a car that, once exported to Beam and then imported back into Automation retained its body mouldings and the performance figures had changed a fraction, but were still within what they needed to be. So that's what I had in the end, but I will not be impressed if the car that makes it into the challenge breaks itself upon importing to Automation.
For the actual car, all I can remember is it's a 4 cylinder turbo front wheel drive! But as you can see, it has all the important features like pop-up headlights, an intercooler and yellow pin-striping around the edges of the wheel rims. It's got brakes too, and door handles, and a differential which I think is of the limited slip variety. Flat out it does somewhere in the region of 120mph.
The Industrial Automation Industry in India projected to grow at a CAGR of 10-12% during 2015-2020, is expected to touch $3.49 billion by 2020
The Canon AE-1 is a 35 mm single-lens reflex (SLR) film camera for use with interchangeable lenses. It was manufactured by Canon Camera K. K. (today Canon Incorporated) in Japan from April 1976 to 1984. It uses an electronically controlled, electromagnet horizontal cloth focal plane shutter, with a speed range of 2 to 1/1000 second plus Bulb and flash X-sync of 1/60th second. The camera body is 87 mm tall, 141 mm wide, and 48 mm deep; it weighs 590 g. Most are black with chrome trim, but some are all black.
The AE-1 is a historically significant SLR, both because it was the first microprocessor-equipped SLR and because of its sales. Backed by a major advertising campaign, the AE-1 sold over one million units,[1]:66 which made it an unprecedented success in the SLR market.
Contents
1Features
2Design history
2.1Legacy
3References
4External links
Features
The AE-1 has a Canon FD breech-lock lens mount and accepts any FD or New FD (FDn) lens. It is not compatible with Canon's later Canon EF lens mount, though adapters made by independent manufacturers can be found. The camera will also accept Canon's earlier FL-mount lenses through the use of stop-down metering.[2] Original FD lenses, introduced in 1971, did not rotate in the mounting process; instead, a locking ring at the base was turned to attach the lens. This was often criticized as being slower than the bayonet mounts of competing cameras.[1]:201 The counter argument, though, was that as the lens/body mating surfaces did not rotate, there was no wear that could affect the critical distance from lens to film plane. In 1979, Canon introduced the New FD series of lenses that rotate the whole outer lens barrel to lock. The inner lens barrel remained stationary, and thus the signal levers and pins still did not rotate. During the late 1970s, there were over 50 Canon FD lenses available for purchase. They ranged from a Fisheye FD 15 mm f/2.8 SSC to a FD 800 mm f/5.6 SSC, plus special purpose lenses such as a 7.5mm circular fisheye and a 35 mm tilt and shift lens.
Accessories for the AE-1 included the Canon Winder A (motorized single frame film advance up to 2 frames per second), the Canon Databack A (sequential numbering or date stamping on the film), and the Canon Speedlite 155A (guide number 56/17 (feet/meters) at ASA 100) and Canon Speedlite 177A (guide number 83/25 (feet/meters) at ASA 100) electronic flashes. The later Power winder A2 was also compatible, but the Motor Drive MA was not.
The AE-1 is a battery-powered (one 4 LR44 or 4 SR44) microprocessor-controlled manual focus SLR. It supports either manual exposure control or shutter priority auto exposure. The exposure control system consists of a needle pointing along a vertical f-stop scale on the right side of the viewfinder to indicate the readings of the built-in light meter (center-weighted with a silicon photocell). The viewfinder used by the AE-1 is Canon's standard split image rangefinder with microprism collar focusing aids.
Design history
Canon AE-1 detail
The AE-1 was the first in what became a complete overhaul of Canon's line of SLRs. The 1970s and 1980s were an era of intense competition between the major Japanese SLR brands: Canon, Nikon, Minolta, Pentax and Olympus. Between 1975 and 1985, there was a dramatic departure from heavy all-metal manual mechanical camera bodies to much more compact bodies with integrated circuit (IC) electronic automation. In addition, due to rapid advances in electronics, the brands leap-frogged each other with successively more automated models.
Although Canon Camera K. K. had been making quality 35 mm cameras for decades, it had always been overshadowed by their rival Nippon Kokagu K. K. and their Nikon cameras. While Canons easily led in the amateur compact fixed-lens rangefinder market (where Nikons did not compete), Canon SLRs had far less cachet than Nikon SLRs. Nikon, with its solid reputation for quality of material and workmanship, held a stranglehold on the prestigious professional SLR market that competitors could not break.
The AE-1 was the vanguard of the landmark Canon amateur level A-series SLRs and led Canon's charge into the emerging electronically controlled SLR market. The other members of the A-series were the AT-1 (released 1977), A-1 (1978), AV-1 (1979), AE-1 Program (1981) and AL-1 (1982). They all used the same compact aluminum alloy chassis, but with different feature levels and outer cosmetic plastic top panel. By sharing most major components, including an inexpensive horizontal cloth-curtain shutter, viewfinder information display, and autoflash control, Canon further reduced costs and could undercut the price of the more expensive SLRs then on the market.
In keeping with its cost-cutting philosophy, Canon designed the AE-1 to use a significant amount of structural plastic for a lighter and cheaper camera at the expense of being less impact resistant. Canon went to great effort to disguise the use of plastic - the injection-molded acrylonitrile-butadiene-styrene (ABS) for the top panel finished with ether satin chrome (or black enameled) to give the look and feel of metal. The bottom plate were made of brass and then finished with satin chrome (or black enameled). Extensive use of electronics also allowed simpler modular internal construction instead of mechanical linkages. Five major and 25 minor internal modules reduced the individual parts count by over 300. Modular construction, in turn, allowed automated production lines in order to reduce cost. Unfortunately, cost concerns also resulted in the use of plastic in some of the moving/operating mechanisms.
The AE-1 was never designed to be a professional camera. However, it was made to have relatively straightforward controls and automatic aperture for newcomers, with various manual controls and system accessories to appeal to more experienced photographers. The AE-1 was the first SLR purchased by millions of amateur photographers, persuaded by its feature list and low price.
In many ways, the AE-1 represented the confluence of two streams of Canon camera development. The first generation electronically controlled 35 mm SLR Canon EF (1973) merged with the final generation rangefinder Canonet G-III QL17 (1972). After decades of chasing Nikon for Japanese optical supremacy, Canon finally hit upon a formula for success: high technology for ease of use, cheaper internal parts and electronics for lower price, and heavy advertising to get the message out. Despite outcries from traditionalist photographers who complained about an “excess” of automation ruining the art of photography, automation proved to be the only way to entice the amateur photographer.
The AE-1 had only one pointer needle used to indicate the light meter recommended f-stop, and neither a follower needle to indicate the actual lens set f-stop, nor plus/minus indicators for over/underexposure. The shutter-priority system of the AE-1 was more suited to sports action than to preserving depth-of-field, yet the 1/1000 s top speed of its horizontally traveling shutter limited its use for such activities. The battery door design was subject to frequent breakage, and over time owners have reported instances of shutter and mechanical gremlins, including mirror linkage wear (the "Canon squeal"). Canon's eventual abandonment of the FD lens mount for the EOS autofocus design also had an effect on prices for the AE-1 on the used market.
We make sure systems are fully installed, functioning properly and handed off successfully to your team before declaring the project complete. You can count on EPIC to support you in this transition and make sure you have operations manuals, training, recommended spare parts list, full documentation and continueing support.
Are you aware of the latest lighting automation services? Did you hear about the services provided by the GadgEon? Visit Website for more details.
A Pellergy PB-3550 wood pellet burner system mounted to the door of a Tarm cord wood boiler. Burn wood the Pellergy way. It's affordable, automatic, clean, whole house heat made in Vermont.
Following design, our team begins developing the programming and physical control panels required for your automated system. We design and program systems for a variety of platforms and will work with you to select the best one for your application.
Home automation Home Automation is a term used to describe the working together of all household amenities and appliances. For example, a centrally-controlled LCD panel can have the capability to control everything from heating, air conditioning, security systems, audio systems, video systems, lighting, kitchen appliances, and home theatre installations. A diagram of a home automation system is shown below.
Did you know the benefits of lighting automation? The GadgEon Smart Systems offers the best lighting automation services for the clients. Follow the link to know more details about the lighting automation
The lighting automation services have wide acceptance in the business and home security sector. The GadgEon Smart Systems provides wide range of lighting automation services for the clients. Click Here for more details.
A quick visit to Novelty Automation at Tudor House on Princeton Street in London.
Was a bit smaller than expected, so didn't stay long.
A Short History of Tudor House
Behind its mock Tudor exterior, Tudor house is genuinely Tudor, built at the the beginning of the 17th century. It was originally a tavern, with the barrels brought up a stream at the back of the house. Shakespeare’s ‘Comedy of Errors’ was first performed at the nearby Gray’s Inn hall, so its even possible he drank here.
At first surrounded by fields, the area was rapidly developed, by the lawyers to the east and by the Red Lion Square development to the west. Red Lion square was the very first speculative development in London, and at the time was fiercely opposed by the lawyers. Tudor house remained stuck between the two, a sort of no-man’s land.
Since then it has been through numerous changes. The roof was damaged in WW2 and rebuilt with an extra floor. The building was owned by an electrical contractor until 1980, when the ground floor became a specialist electric typewriter repair centre. In 1990, when offices everywhere were changing to computers, the business went bust. The building then became residential, with the ground floor let as a shop - for many years selling mosaic supplies.
Novelty Automation has its roots in the history of the area - a 21st century revival of the irreverent 18th century print shops and exhibitions of automata.
Gate Automation Australia - Gates automation systems and components for optimum security by Boswen Australia. Boswen installs gates and gate automation systems throughout Melbourne.
Check out blog "Home Automation: Benefits Galore, Convenience, Green Energy, Security." hellokarbon.com/home-theater-blog/home-automation-systems...