You are in site section:

Wi-fi

Defining Moments in Australian History

Warning: This website includes images and names of deceased people that may cause sadness or distress to Aboriginal and Torres Strait Islander peoples.

Wi-fi

1996: CSIRO patents technology that allows optimum performance of wireless local area networks, permitting the development of stable wi-fi


three men in suits standing beside a table on which sit a collection of cumbersome electronic equipment.

The work of CSIRO scientists lies at the heart of wireless networks now in use around the globe.

CSIRO’s groundbreaking work in radioastronomy, involving detailed knowledge of the structure and behaviour of radio waves, led to a successful solution to the problem of how to move large quantities of data around indoor environments.

By 2012, CSIRO had licences with 23 companies which had generated a revenue in excess of $430 million.

More on the development of wi-fi

From the citation of the European Inventor Awards 2012 presented to the CSIRO team:

[This] invention made the wireless LAN as fast and powerful as the cabled solutions of the time, and is the basis for the wireless networking technology (wi-fi) now used in billions of devices worldwide. O’Sullivan and his team thus ushered in the age of high-speed, always-on wireless connectivity we enjoy today.

Radio waves

The history of wireless local area networks (WLAN) stretches back more than a century to the work of Guglielmo Marconi, the Italian inventor who began experimenting with radio waves in 1894. WLAN uses long radio waves, which Marconi discovered could carry complex signals.

In the First World War, both sides used radio technology. In the Second World War the military was able to encrypt radio transmissions by transferring messages rapidly between frequencies. This was called spread-spectrum technology and was crucial to the later development of WLAN.

In the 1930s the American physicist Karl Jansky discovered that the universe emits radio waves. He built an antenna capable of receiving those signals, and radio astronomy was born.

Fast Fourier Transform

John O’Sullivan was a young Australian electrical engineer working in radio astronomy in the Netherlands during the 1970s. One of his tasks was to analyse hundreds of cosmic radio signal recordings.

O’Sullivan was frustrated with the monotony of the work. ‘I guess I’m inherently lazy,’ he has since said, ‘but I was starting to think … there must be a better way of doing this’. So he invented what would become one of the keys to cracking wireless communication – a Fast Fourier Transform (FFT) computer chip.

The Fourier Transform (FT) is a mathematical equation that transforms one form of communication to another. It has the capacity to break radio waves down into their constituent frequencies and reassemble them. The FFT chip could perform thousands of these operations (and so the fast) almost simultaneously and therefore rapidly interpret the radio signals.

three men in suits standing beside a table on which sit a collection of cumbersome electronic equipment.
John O'Sullivan, Terence Percival and Graham Daniels with the WLAN test equipment. National Museum of Australia

CSIRO and signals processing

In 1983, O’Sullivan returned to Australia to work with the Commonwealth Scientific and Industrial Research Organisation (CSIRO) on the receiving systems for the new Australia Telescope in Narrabri, NSW. It was a time of diminishing research budgets and O’Sullivan’s Signals Processing Group (SPG) was charged with finding industrial applications for the technologies they were developing.

Their research led to commercial applications in ultrasonic proximity detection for coal mine safety, ultrasound processing and CT scanning.

One of the underlying connections between these technologies was the Fourier Transform equation. It was able to interpret the signals used in each application.

In the mid-1980s, O’Sullivan worked with Austek Microsystems, an Adelaide-based computer chip manufacturer, to create the first commercial chip developed around his original FFT chip. These chips had many applications in astronomy and medical imaging, and held records for processing speeds for many years.

Moving data quickly

The Signals Processing Group had a goal of earning 30 per cent of their funding from these commercial activities but this was proving difficult and O’Sullivan believed they needed to focus their attention on one major investigation with worldwide impact.

Newly developing technologies for moving data quickly in congested interior environments presented such a challenge. The decision to solve the WLAN problem was a bold one. Portable computing was just taking off and contemporary processing speeds were so slow that there could be no immediate commercial application.

Ambitiously, the team set their target data transfer rate at 100 megabits per second (Mbps), the same rate as the best optical fibre networks at the time. Existing wireless networks were transmitting at only between one and two Mbps.

This wildly optimistic target proved crucial because it forced the project to be framed in a completely different way. The team could not just upcycle standard technology; they had to approach the issue from a multitude of different angles.

a piece of equipment with a small screen showing a wave formation of some kind.
40 GHz transmitter unit from the original WLAN test equipment. National Museum of Australia

New CSIRO team

In 1990 a new team was assembled: O’Sullivan was the leader; Dr Terry Percival the principal research scientist, John Deane, systems analyst; Graham Daniels, design engineer; and Diethelm Ostry, mathematician and physicist.

The primary difficulty with short-range wireless transmission was how radio waves bounce off almost any surface and arrive at their destination at different times. Like echoing sound waves, these delays led to the break up and distortion of waves. This is referred to as multiple path propagation.

To transfer large quantities of data wirelessly the data needs to be separated into small portions and transmitted on multiple radio frequencies simultaneously, and then reassembled in the right order by the receiver.

The key to this deconstruction and reconstruction was the Fourier Transform equation that O’Sullivan had worked on in the 1970s. As with the stripping down and reassembling of cosmic radio waves, that same process could be applied to low power radio waves.

a hand wearing plastic glove holds coin-sized black square with gold-coloured chip at its centre
Early Austek computer chip. National Museum of Australia

Patents and challenges

In 1992 the first Australian WLAN patent was filed for, the US patent was filed for in 1993 and approved in 1996. This led to the creation of prototypes and the founding of Radiata Inc by Dave Skellern and Neil Weste from Macquarie University. They took out a non-exclusive patent on the technology from CSIRO in 1997.

In September 2000, Radiata demonstrated a chip compliant with the new IEEE 802.11a wi-fi standard at the Networld-Interop conference in Atlanta. On the strength of this demonstration Cisco Systems bought the company for $567 million.

Court case

By 2002 the first unlicensed WLAN products had been released on the market and CSIRO began efforts to persuade those computer chip manufacturers to pay royalties. They had no success and in 2005 resorted to litigation.

The legal action evolved into a David versus Goliath scenario. Dell, Intel, Microsoft, Netgear, Hewlett-Packard and Apple all sued CSIRO to declare its patent invalid. Eventually CSIRO, a relatively small government research body, was up against 14 of the largest tech companies in the world.

In 2009, Hewlett-Packard was the first of the litigants to break ranks and sign an out-of-court agreement. Then, one by one, the other 13 companies followed suit, leading to a reported settlement for CSIRO of over $205 million.

Emboldened by the settlement, CSIRO went after the big mobile phone operators in the USA – Verizon Wireless, T-Mobile USA and AT&T – and came to another out-of-court settlement. By 2015, CSIRO had received over $450 million in settlements and over $150 million of that has been placed in trust for future research.

In our collection

Search our collection placeholder image

CSIRO WLAN collection

Further reading

Wi-fi prototype collection highlight

The Story Behind CSIRO’s Wi-Fi Patent ‘windfall’ on The Patentology Blog

Christopher Cheng, Australia’s Greatest Inventions and Innovations, Random House Australia, Milsons Point, NSW, 2012.

< Previous Next >

Other featured moments from this period

1991: Port Hedland immigration detention centre opens
1992: High Court decision in Mabo case recognises native title
1996: Port Arthur massacre leads to tighter gun laws
1993: AFL player Nicky Winmar responds to racist abuse from spectators

Browse related featured moments

Topics:Science and Technology Places:AustraliaInternational Curriculum subjects:History School years:Year 6Year 9