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Increased Spectral Efficiency with HD Mode
Shure Applications Engineer, Tom Colman explains how high-density mode allows us to take the spectral efficiency of digital wireless to whole new lev…
Marc Henshall,
Increased Spectral Efficiency with HD Mode
Increased Spectral Efficiency with HD Mode Whiteboard Session
Shure Applications Engineer, Tom Colman explains how high-density mode allows us to take the spectral efficiency of digital wireless to a whole new level.
As we've determined in previous sessions, digital wireless systems are typically more spectrally efficient than analogue wireless systems. In other words, a digital transmission often takes up less RF spectrum, and therefore we can fit more transmissions into a given portion of spectrum at a given time. With ULX-D, we can take this one step further by using high-density (HD) mode.
In standard mode, a Shure ULX-D wireless system will comfortably operate between 17 and 22 transmissions within an 8MHz band TV channel. To obtain this performance, the RF engineer will typically deploy an output power of around 10mW, with 200KHz of output bandwidth and channel-to-channel spacing of 350KHz.
However, we can take this efficiency even further by reducing the output power to 1mW, limiting the modulation bandwidth from 200KHz down to 100MHz, and lastly, by reducing the channel-to-channel spacing from 350 to 125KHz. Collectively, these operating principles are referred to as High-Density mode, which enables us to run up to 63 transmitters in a given 8MHz TV channel portion of spectrum. (That's over 500 compatible channels within an entire tunable bandwidth).
HD Mode does reduce the operating range, and therefore, is not suitable for applications where the typical range is required — say a live stadium gig for example. HD Mode is best suited to more contained RF conditions, such as tradeshows and conference events, or corporate office facilities. The reduced output power, in particular, makes HD-mode perfect for these busy, zoned events, where reduced signal range is actually desired to help contain sets of wireless kit within a given portion of the venue. Best of all, the audio quality is unaffected by switching from standard to HD transmission; we still retain a full 20Hz to 20KHz frequency range for all transmissions.
LEARN MORE
As demand for RF spectrum continues to increase, the role we play as sound engineers is imperative. It's important we stay up-to-date with the latest technology to make the best of the spectrum available. To learn more about best practice wireless operation — including how digital wireless systems play a huge role through spectral efficiency — consider attending one of our Shure Wireless Mastered seminars. To register or find out more, visit the Shure Audio Institute section of our website.
About the Author
About the Author
Marc Henshall
Marc forms part of our Pro Audio team at Shure UK and specialises in Digital Marketing. He also holds a BSc First Class Hons Degree in Music Technology. When not at work he enjoys playing the guitar, producing music, and dabbling in DIY (preferably with a good craft beer or two).
Marc forms part of our Pro Audio team at Shure UK and specialises in Digital Marketing. He also holds a BSc First Class Hons Degree in Music Technology. When not at work he enjoys playing the guitar, producing music, and dabbling in DIY (preferably with a good craft beer or two).
All Whiteboard Sessions
All Whiteboard Sessions
Whiteboard Sessions cover a wide variety of best practice operating principles surrounding the mysterious science of wireless audio. We look at topics such as intermodulation, how to properly coordinate a wireless system, how to troubleshoot, and even topics around antennas and cabling.
