All posts tagged: LX Group

Electronics Design House wins ‘Digital Home’ Award at Electronics Future Awards 2010 with Yellowbird ALERT

For the second year running, LX Group has won a major award at the Electronics Future Awards 2010.

LX Group was awarded winner in the Digital Home category, Highly Commended in the Communications category and nominated in the Wellness and Environment categories with YellowBird ALERT.

YellowBird ALERT (Automatic Linking to Emergency Radio Transmissions) is an emergency alert system that warns of natural disasters, such as bush fires or floods, by utilizing AM and FM radio transmissions.

YellowBird logs onto a registered radio station and sits dormant until an alert is received.

In the event of an emergency, authorities may decide to send an alert by creating a message and alert tone package, which sends out an immediate radio broadcast. If contact it lost with the registered radio station, Yellow Bird will notify the user and scan for alternative stations.

Simon Blyth, director of LX Group said ”my team and I are thrilled and greatly encouraged to receive this award” and added that he was pleased to be able to support an event that recognized and promoted electronics innovation.In 2009, LX Group was awarded overall winner at the EDN Innovations Awards for Best Project with WMD3000, a device that monitors a user’s gym workout and provides feedback wirelessly. Also awarded to LX, was first place in Best Application of Test/Data Acquisition category and highly commended in the category of Best Application of RF Wireless Design.

The Electronics News Future Awards, continuing the tradition founded by the EDN Innovation Awards, recognizes excellence in Australian and New Zealand electronics (http://www.electronicsnews.com.au/awards.aspx).

About LX

LX Group is an award winning Australian electronics design house, specializing in the wireless and low power electronics designs. LX offers clients a range of professional solutions designed to take a new product idea from concept through to production.

LX Group services include full turnkey electronics design, electronics, firmware and software design, electronics engineer consultancy, rapid prototyping, electronics manufacturing and commercialization and technical support. LX’s team takes an innovative approach to developing each project to ensure it gets to market fast with the best possible features.

For more information about LX Group please visit www.lx-group.com.au or call 1800 810 124

Links:

http://www.prlog.org/10954702-lx-innovations-wins-electronics-future-award.html

Published by LX Group for itself and the LX Group of companies, including LX Design House, LX Solutions and LX Consulting, LX Innovations.

Virtual reality is a term that has been used frequently in sci-fi novels and movies. Virtual reality is a technology which allows the user to interact with an environment that exists only in a computer. Augmented reality, which is one of the newest innovations in the electronics industry, tries at superimposing a range of elements such as graphics, audio and other sense enhancements from computer screens onto real-time environments.

Virtual reality and augmented reality systems go far beyond the static graphics technology and try to assimilate the user’s movement and actions to create complex virtual worlds that can “trick” a person into believing that s/he is experiencing reality. These virtual environments have the capability to revolutionise how we view, interact and use information to perceive the world around us, and embedded technology is powering the future of these systems.

Virtual Reality (VR) is an artificial environment created with a computer and presented to the user in such a way that it appears and feels like a real environment. To experience a virtual reality environment, the user is required to wear special gloves, earphones and goggles, all of which receive inputs from the computer system. The computer continuously monitors and analyses the user’s actions and alters the information fed to the devices the user has worn. For example the goggles, track head movements and respond accordingly by sending a new video input which makes the user feel s/he is in a real environment. The simulated environment can be similar to the real world – for example, simulations for pilot or combat training – or it can differ significantly from reality – such as alien worlds and creatures depicted in Virtual Reality games.

In contrast, the goal of Augmented Reality (AR) is to add information and meaning to a real object or place. Unlike Virtual Reality, Augmented Reality is not aimed at creating a simulated computer-based environment. Instead, it takes a real object or space that the user is viewing, as the foundation, and incorporates contextual data to deepen a person’s understanding of the object. For example, Augmented Reality can add data such as an audio commentary, location data, historical context or similar information that can make a user’s experience of a thing or a place more meaningful. Similarly, AR systems can be used to superimpose images from an X-ray or MRI (Magnetic Resonance Imaging) scanner directly onto a patient’s body to help a surgeon analyse and clearly understand the nature of a fracture or a tumour.

Augmented reality is the next step in Virtual Reality, created by combining information, digital data received from different devices and the internet, to create a surreal world which gets displayed to the user in such an intuitive fashion that the user may not be able to differentiate between the real world and its virtual augmentation.

Creating The Virtual World

Getting the right information at the right time and the right place is the key to the functioning of a VR and AR system. The basic requirements of both VR and AR systems are same – both depend on data generated from user movements and perspective to arrive at the information (text, visuals, sound etc.) to be provided to the user. AR systems and VR systems employ similar hardware technologies but differ in the complexity of the systems used. In general, the devices used in both VR and AR systems can be summarised as below.

Tracking devices: The “input” unit of a virtual system or tracking devices help sense the movements of the user to identify the user’s coordinates in real-time. The requirements for AR in such cases are much stricter than those for VR systems. VR systems use indoor tracking devices to track the entire body actions of a user to “transport” the user to a virtual environment. For example a flight or parachute-landing simulator simulates the movement of the user to display a real-life scene on a screen or a Head Mounted Device (HMD). In the case of AR, the tracking system uses a combination of indoor and outdoor tracking devices to recognize what a user is viewing at a given movement. For example, a handheld device showing information about a building or a piece of art the user is viewing.

Scene processor: VR systems need to process and generate realistic images because they completely replace the real world with the virtual environment for the user. Thus, a complex and high performance intelligent embedded system capable of rendering text, graphics and sound to match user movements is critical in a VR environment. In AR, the virtual images only supplement the real world. Therefore, fewer virtual objects need to be drawn, and they do not necessarily have to be realistically rendered. However, an AR system needs to have the intelligence to interface with a centralised database or connect to a network, internet or GPS (Global Positioning System) to fetch and display the right information to the user. In addition, an AR system tracks the position and orientation of the user’s head so that the overlaid material can be aligned with the user’s view of the world.

Display device: The display devices used in AR may be less complex when compared to VR systems. For example, monochrome or low-resolution display may be adequate for some AR applications, while VR systems need to use full colour high-resolution display systems. Optical see-through Head Mounted Devices (HMD) with a small display device may be satisfactory in the case of an AR system because the user can still see the real world. However, a complex HMD that blocks the user’s view to the real-world is critical in the case of a VR system.

Difference between Virtual and Augmented Reality

Immersion

Virtual reality provides a totally immersive environment while Augmented Reality adds information to the user’s existing view of the world.

User senses

In Virtual Reality, a user has to be in a controlled environment, a simulator capsule or a head mounted device (HMD) that feeds the user visuals, sounds, motion, sensation and in some cases smell as well.

In Augmented Reality, the user maintains a sense of presence in real world and the information is generally displayed on HMD or a handheld device.

Complexity

Virtual Reality systems are complex since it needs to process all details associated with the virtual environment. Augmented Reality systems are less complex but needs to combine virtual and real worlds to provide a rich user experience.

Embedded intelligence

Similar to a central processing unit of a computer, the scene processor forms the core part of a VR or AR system where the data gets processed and results are generated for the user. Embedded systems are playing a vital role in creating advanced, intelligent and affordable scene generators for VR and AR systems. The increase in processing power and miniaturisation of embedded components are paving way to the creation of scene processors with higher processing power yet in sizes that fit inside the palm of the user. The use of embedded technology also supports interconnectivity of similar devices and also ensures connectivity to external systems, networks or internet to give a rich holistic user experience.

Virtual Reality Applications

Flight, parachute, vehicle simulation
Simulation for space missions
Robotics and tele-robotics
Sci-fi movies
Medical surgery simulation
Virtual Reality games
Amusement rides

Augmented Reality Applications

Pre-operative anatomy imaging of X-ray & MRI scans
Virtual HMDs to aid military combat operations
Virtual navigation systems
Shopping – providing enhanced reviews of goods
Sightseeing
Entertainment and education – in schools, exhibitions & museums

Conclusion

Though Virtual Reality has been around for some time, the incorporation of advanced embedded technologies is helping researchers improve the quality and control of the system. Augmented Reality, which is a relatively new advancement in electronics, has also scaled new heights with the use of Embedded Technology. The virtual systems of the future can be so advanced in the near future it could even work on the thoughts of the user. The potential of virtual systems are huge, and embedded systems that are powering it reach outstanding levels of interactivity.

About LX Group
LX Group incorporates LX Innovations, LX Design House, LX Solutions and LX Consulting, and is an award-winning electronics design company based in Sydney, Australia. LX services include full turnkey design, electronics, hardware, software and firmware design. They specialise in embedded systems and wireless technologies design.

LX Group offers clients a range of professional solutions designed to take a new product idea from concept through to production and beyond. LX focuses on fully understanding all aspects of a client’s requirements (both technical and business) and works on creating custom-made solutions. LX Group’s expertise in developing electronic products enables a quicker design process and reduces cost in bringing a concept to reality. www.lx-group.com.au

Published by LX Group for itself and the LX Group of companies, including LX Design House, LX Solutions and LX Consulting, LX Innovations.

Electric power systems constitute fundamental infrastructures in of modern society. Often continental in scale, electric power grids and distribution networks connect the generating stations to virtually every home, office, factory and institution across the country. Increased bulk power transactions and large scale integration of renewable energy sources are posing challenges to high-voltage transmission systems.Environmental constraints and energy efficiency requirements also have significant effects on the design and operation of power transmission infrastructures. To address these challenges, power grids worldwide are undergoing a revolutionary transition to the so-called “Smart Grid”.

Smart Grids are designed to imbibe intelligent processes and methodologies to the power grids to improve their flexibility, reliability and overall efficiency.The electric power grid can be defined as a large system of high-tension cables that connects the power plants to consumers across a region. The grid is responsible for transmitting the generated power to the end-user. The electricity produced at power plants is usually “stepped up” to high voltages before it is transmitted through the grid. At a substation near the consumer, the power gets “stepped down” to voltage suitable for household and commercial use.

The beauty of the grid is that power can be bought and sold across vast expanses. Since the storage of electricity is very difficult, power grids support an optimal distribution of electricity allowing for a more balanced supply-and-demand equation. Also, minor transmission failures in one section of the grid can also be compensated for by using electricity available in another section of the grid.Due to expanding demand, higher fuel costs and pollution-related issues, there has been a recent push to develop smarter electrical grids that are more efficient, cost effective and robust. The introduction of renewable energy systems such as wind, solar, biomass and geothermal generation facilities also entail the use of complex power management techniques in the grid. Since the power generated from the renewable power systems heavily depend on environmental factors, the power grids need to have sufficient “intelligence” to switch the transmission on/off based on the power generated.

The Smart Grid
The Smart Grid is achieved by incorporating digital technology to power grids to deliver electricity from power plants to consumers in a more intelligent, efficient, and transparent way. The basic concept of the Smart Grid is to add monitoring, analysis, control and communication capabilities to the power in order to maximise the throughput of the system while reducing the energy consumption. As all systems are automated and metered, they track when and how much electricity is used. By analysing and reporting all critical usage and health statistics, Smart Grids help system engineers to better manage loads and effectively cater to power demands.

Smart Grid Architecture
Smart Grid architecture relies on embedded technology to manage an energy system and automatically track usage. The conventional power grid management was carried out manually by disparate teams situated at each section of the grid, i.e. power plant, substation etc. The information available to these teams was mostly limited to their subsections alone and information about demand and outages were usually communicated through phone calls or fax messages.

In sharp contrast, Smart Grids allow for seamless transfer of information across the entire power grid. Embedded systems deployed at various points of the grid, from power generation to end-user consumption, help in analysing the critical characteristics of the system and also communicate it to other systems attached to the grid to achieve excellent energy management capabilities. Embedded systems are computers that can be integrated or “embedded” into a larger electrical or electronic equipment, to allow the equipment to have the necessary “intelligence” to function automatically. The use of embedded technology also allows the deployment of centralised Smart Energy Management Software to control the power available across the entire grid.

Interfacing with Electrical Appliances
Embedded systems are ubiquitous and are finding its use in almost all kinds of consumer and commercial equipment. Thus, a power delivery network built on embedded technology can far easily be interfaced with such equipment. This can ensure flow of electricity as well as information between the power plant and the equipment. The combined intelligence of the interconnected devices, coupled with automated control systems, can permit real-time power transactions and seamless interfaces among people, buildings, industrial plants, generation facilities and the electric network.

The information received from all the interconnected applications will enable the centralised energy management software to create an efficient power generation and transmission plan. An “intelligent” electric grid will also facilitate the proper delivery of electricity from renewable power systems such as wind, hydro and geothermal power plants that are often located at remote regions, far off from load centres. Additionally, interconnected systems will also enable faster detection of outages, correction of faults and quicker restoration of power supply. This will also improve the reliability of the grid and ensure security of the region as well.

Conclusion
The Smart Grid can be considered as a futuristic extension to the power grid and aims for better and efficient power management and consumption. Intelligent embedded power grids can create value up and down the chain – from efficient production of electricity in power plants to optimal supply and distribution of power to match the usage patterns of the end-users. The use of embedded technology would play a significant role in enhancing the “intelligence” of the existing power grids.

The primary advantage is that the grid can be transformed from an operator controlled and managed system to an “intelligent” automated network that works continuously to match the supply with the demand. Smart power grids can dramatically improve the reliability, efficiency, and cost effectiveness of electric power delivery systems. Embedded and intelligent power grids is the way forward in ensuring a smarter, cleaner and a well-organised management of energy sources driving future growth requirements.

Published by LX Group for itself and the LX Group of companies, including LX Design House, LX Solutions and LX Consulting, LX Innovations.

Mr RICHARD TORBAY (Northern Tablelands) [6.23 p.m.]: LX Group: It is often noted that Australians are very good at invention but lack the backing of national commerce and industry to capitalise on it. Recently, I held a meeting in my parliamentary office with just such a young inventor and entrepreneur, Simon Blyth, whose family live at Inverell in my electorate, and who is seeking financial backing for a remarkable invention. Simon, at the age of 23, has won many awards for technology and innovation and with his research partner, Kelly Poole, has just won the State university finals for a new electronic system which could revolutionise our classrooms. They have adapted new Zig Bee technology to produce a system that can give teachers an instant response on their students’ comprehension levels during class time. The device which Simon showed me during our talk solves this problem by enabling real-time, anonymous student feedback.

http://www.prlog.org/10802081-mr-simon-blyth-lx-innovations-electronics-inventors.html

Through this system tutors can assess students’ understanding and adapt their teaching style accordingly during lectures and classes. The Dynamic Feedback System [DFS] works through the use of handsets, one per student, and a control panel or base station operated by the teacher or lecturer. The base station gathers all the data from the student devices, processes it and then displays the understanding level of the class to the lecturer. If the class understanding level drops, the lecturer can immediately respond.

The DFS can also be used to hold class tests and automatically track student attendance. Students can get their results instantly, and the teachers have no marking, allowing them to focus on more important teaching issues. More importantly, because of the low overheads, teachers can hold regular tests, even a short test before each class in order to ensure students read the material beforehand.The attendance tracking feature of the DFS is also relevant to the Federal PRISMS policy which requires educational institutions to track overseas student attendance. Because of large lecture sizes, this often does not occur because it is impractical. Universities require an innovative automated approach; otherwise too much lecture time is spent simply marking the roll. We hear all the time about initiatives that will increase literacy and numeracy in our schools.

A major concern is the number of students who fall behind without teachers being aware of it or through sheer pressure of class sizes being unable to give the individual attention that is needed at the time it is needed. I can see great potential for the new device and I urge the Minister for Education and Training and members of her department to look at this invention and give their support to it so it receives full financial backing from the commercial sector for its development.Simon Blyth has an outstanding record of achievement. He was joint dux and captain of Inverell High School and received the Premier’s

Award for Excellence and the Minister’s award for achieving 100 per cent in electronics technology for the Higher School Certificate. While he was at school he played in the Rugby Union First XV and took the lead role in several school musicals. He is a born inventor and started work in a TV and video repair shop in Inverell at the age of 12. During his school holidays he took on work experience in engineering companies to gain more experience. He is a member of the Young Business Forum, Enterprise Network for Young Australians, BizNet Club, the Institute of Electronics and Electrical Engineers and the Institute of Engineers Australia.

He applied for his first patent at the age of 17 and to date three of his inventions have received national recognition. He is a co-founder and director of Navitas Technologies, a company based around one of his inventions, Virtual Buttonz, and located at the Australian Technology Park. He also won the Nescafe Big-Break competition with his invention to combat driver fatigue. He won the National Shell Science Award and BHP Science Award for his invention VIPER, an ultrasonic guidance system for the visually impaired. He has a further long list of achievements and inventions. Time does not permit me to list them all.

Simon won a faculty scholarship to the University of New South Wales to study electrical engineering and physics. He has just graduated and the Dynamic Feedback System I have already mentioned was the subject of his thesis. It has now entered the national university finals, which will be judged in April next year. I congratulate Simon and Kelly and all young inventors for the wonderful contribution they are making.

Private members’ statements noted.

Published by LX Group for itself and the LX Group of companies, including LX Design House, LX Solutions and LX Consulting, LX Innovations.

LX Group is a contract electronics design company, specialising in the design of embedded systems and wireless technologies. Simon Blyth, a participant in the 2004 NSW Enterprise Workshop leads the company.

http://www.prlog.org/10802084-making-innovation-business-success.html

Simon entered the Workshop to improve his understanding of business. Commenting on his Workshop experience Simon said, “The Workshop provided a practical and start-up focussed program that taught us the nuts and bolts of business in real life as opposed to just the theory.”Simon added, “The lectures, advisory board sessions and mentoring challenged our thinking at all levels and helped to develop a strong business foundation. It was also very exciting and encouraging to meet and work alongside other likeminded entrepreneurs.”LX Group has evolved significantly. Simon and his team have been recognised nationally and globally for their innovative designs, business strategy and research. Awards include the Institute for Engineering and Technology competition (IET), National Shell Science Awards and the Premier’s Award for Excellence. Commenting on his team, he said, “Members of the LX team are passionate and innovative when it comes to turning revolutionary ideas into commercial products”

Published by LX Group for itself and the LX Group of companies, including LX Design House, LX Solutions and LX Consulting, LX Group.

ITL Design and LX Group collaborate to design and manufacture ‘Nero’, a retail display and theft control device for small consumer electronic devices.

http://www.prlog.org/10802090-lx-innovations-itl-design-introduce-nero.html

The first production quantity of the product, which were manufactured at ITL’s Malaysian based manufacturing facility and in South East Asia, have been delivered to the client all within a 12 month time frame. By blending ITL Design’s extensive industrial design and manufacturing capabilities with LX Group leading electronic design services, Nero is now the most innovative and unique retail theft control device on the market.

Nero is a retail display and theft control device, designed to display consumer electronic products, which attach to the device via a magnetic head, allowing customers to interact with the product. The design is intended to complement the modern retail environment in order to maximise the visual impact of retailer’s products, which can vary from small mp3 players to mobiles phones, digital cameras and camcorders. The post can be shelf or wall mounted and rotated to suit the most appropriate display angle.

ITL Design provided the mechanical design and manufacturing, building upon and adding value to the client’s existing IP through innovative industrial design, mechanical design and manufacturing using their Malaysian based manufacturing facility. LX Group provided the system level design, electronics, firmware, PC software and off-shore manufacturing co-ordination. The system has passed certification for commercial sale.

About ITL Design Background:

ITL Design & Manufacturing is part of an Australian listed company that has been providing clients with complete, innovative solutions to develop their ideas into commercially successful products for the past 15 years.

About LX Group Background:

LX Group is an innovative contract electronics design company based in Sydney and Canberra, specialising in the design of embedded systems and wireless technologies. They offer clients a range of professional solutions designed to take a new product idea from concept through to production.

Published by LX Group for itself and the LX Group of companies, including LX Design House, LX Solutions and LX Consulting, LX Innovations.

They are young, smart and come from industries as diverse as IT, fashion and agriculture. BRAD HOWARTH profiles 30 hot young entrepreneurs aged 30 years and under.

By Brad Howarth www.smartcompany.com.au

http://www.prlog.org/10802093-30-hot-entrepreneurs-aged-30-and-under.html

They are young, smart and come from industries as diverse as IT, fashion and agriculture. We profile 30 hot young entrepreneurs aged 30 years and under. As the Australian economy starts to slow, many pundits are wondering how the latest generation of entrepreneurs will cope in the unfamiliar territory of an economic downturn.It’s a tough question, but we wouldn’t mind betting they’ll survive and even thrive.

We’ve scoured the country to find 30 entrepreneurs aged 30 or less, and found an extremely talented bunch emerging from a broad range of market sectors, from beauty products and fashion to high technology and marketing LX Group Services.

They have a wealth of ideas and many have very interesting personal backgrounds. But what they all have in common is energy and passion to back their ideas.

Simon Blyth, 26 – LX Group

Simon Blyth’s business is better described as an idea factory. Among its inventions is a device that enables visually impaired people to detect objects in a similar way to how a bat does, while another monitors vehicles for signs of driver fatigue. A participant in the NSW Enterprise Workshop scheme, Blyth and his team have won awards from the Institute for Engineering and Technology and the Premier’s Award of Excellence. ##END##

http://www.smartcompany.com.au/Premium-Articles/Top-Story/20080520-30-hot-entrepreneurs-aged-30-and-under.html

Simon Blyth of LX Group Ranked in ‘30 Hot Entrepreneurs Aged 30 and Under’

Close SmartCompany named Simon Blyth, from LX Group , amongst the top 30 entrepreneurs in Australia aged 30 and under in May 2008. Blyth founded LX Group in 2006 with the vision of developing a strong team of talented engineers that can develop unparalleled electronic designs.

He has a passion for electronics, and for enabling others to realise their dreams of developing new products and innovative designs. “It was an honour to be named in the top 30 under 30 list” said Blyth. “I just love what I do. I can’t wait to get to work every morning!” The other entrepreneurs came from a range of industries, including IT, fashion and agriculture.

http://www.ferret.com.au/c/LX-Innovations/Simon-Blyth-of-LX-Innovations-Ranked-in-30-Hot-Entrepreneurs-Aged-30-and-Under-n844873

Published by LX Group for itself and the LX Group of companies, including LX Design House, LX Solutions and LX Consulting, LX Innovations.