Benefits of digital wireless, Akes, Ireless – Line 6 DIGITAL WIRELESS XD-V75 User Manual

9

W

hat

m

akes

a

W

iReless

d

igital

?

In a typical analog wireless microphone system the signal between the transmitter and the receiver

consists of a very high frequency radio wave carrier that is continually varied slightly in frequency by

the audio signal from the microphone (or other transducer). The electronic circuitry in the receiver

removes the carrier frequency and leaves the audio signal – the same principle that is used in FM radio

broadcasts. The signal is highly compressed upon transmission and expanded at the receiver – the origin

of the word “companding.” Analog transmissions are vulnerable to many interference effects from other

RF and electromagnetic signals – and the interference is usually audible as well as having the effect of

shortening range or rendering the channel unusable.

Input

Signal

(dBu)

+ 25

+ 20

+ 15

+ 10

+ 5

0

- 5

- 10

- 15

- 20

- 25

- 30

- 35

- 40

- 45

- 50

- 55

- 60

- 65

- 70

- 75

- 80

- 85

- 90

+ 25

+ 20

+ 15

+ 10

+ 5

0

- 5

- 10

- 15

- 20

- 25

- 30

- 35

- 40

- 45

- 50

- 55

- 60

- 65

- 70

- 75

- 80

- 85

- 90

Output

Signal

(dBu)

2:1 Compression Ratio

100dB

Dynamic

Range

50dB

Dynamic

Range

Input

Signal

(dBu)

+ 25

+ 20

+ 15

+ 10

+ 5

0

- 5

- 10

- 15

- 20

- 25

- 30

- 35

- 40

- 45

- 50

- 55

- 60

- 65

- 70

- 75

- 80

- 85

- 90

+ 25

+ 20

+ 15

+ 10

+ 5

0

- 5

- 10

- 15

- 20

- 25

- 30

- 35

- 40

- 45

- 50

- 55

- 60

- 65

- 70

- 75

- 80

- 85

- 90

Output

Signal

(dBu)

No Compression

115dB

Dynamic

Range

115dB

Dynamic

Range

Digital wireless microphone systems provide a much more robust and interference resistant performance.

Within the microphone transmitter, the audio signal from the voice or other source is digitally sampled,

and the sample is converted into a digital “word” consisting of the electrical equivalent of a string of

1’s and 0’s. As in analog wireless, a very high frequency carrier wave is modulated, but in this case with

the digital “stream” of samples so that the carrier frequency only has two distinct states that represent

the signal in the same manner that the flat areas and pits on a CD represent the music. The receiver

retrieves this information from the carrier and decodes it via a D/A converter and outputs an audio

signal that is the replica of what was encoded at the mic.

Analog signal with noise

Digital signal with noise

Benefits of Digital Wireless

As mentioned above, analog wireless transmissions are susceptible to a variety of noise and interference

conditions, related to signal strength and/or interference from external electronic devices and other

wireless signals. These can ride along with the carrier frequency and its audio signal as added noise,

affect the receiver directly because the antennas that pick up the transmitter signal are also wide open

to pick up other radio signal in the same general RF band, or interact with the carrier frequency to create

additional harmonic frequencies. Problems can come from sources as diverse as a television broadcast

signal, other wireless mics in use, digital signal processors, or even malfunctioning fluorescent lighting

ballasts or other electrical devices.

While the same physics applies to a digital signal riding on a carrier wave, the digital signal with just two

states is more difficult to damage. If the receiver finds that something has come in that is not equivalent