Relative frequency hops in low-power, wide-area network

The invention claimed is: 1. A wireless communication network comprising a plurality of radio transmitting devices in a frequency band that is divided into a plurality of channels, wherein, the transmitting devices have each a local frequency reference, and are arranged to modulate a carrier and processing the modulated signals into a spread spectrum radio signal by switching a frequency of the carrier among several hopping frequencies in the frequency band according to a hopping sequence and, the transmitters being arranged to determine the hopping sequence by incrementing repeatedly a channel of an initial hopping frequency according to a determined succession of increments, thereby obtaining a sequence of channels, each channel in the sequence defining an element of the hopping sequence, and transmit the spread spectrum radio signal through a radio interface. 2. The wireless communication network of claim 1 , wherein the channels do not overlap. 3. The wireless communication network of claim 2 , wherein, in the determination of the hopping sequence, the transmitter applies a modulo operation after each increment, to maintain the hopping frequencies within predetermined limits. 4. The wireless communication network of claim 1 , including at least one receiving gateway arranged for: detecting a transmission from a transmitting device at an initial received frequency; forecasting the hopping frequencies by incrementing repeatedly an initial received frequency according to the determined succession of increments; receiving the spread spectrum signal at the forecast hopping frequencies. 5. The wireless communication network of claim 3 , wherein the receiving gateway is arranged to determine when a hopping frequency is expected to fall close to the predetermined limits; to compute two distinct values of frequency according to whether the increment resulted in a frequency judged outside of the predetermined limits or in the predetermined limits by the transmitter, and to listen at both distinct values of frequency. 6. The wireless communication network of claim 3 , wherein the transmitter device is arranged to omit the transmission of a hop whose hopping frequency falls closer to the predetermined limits than a determined threshold. 7. The wireless network of claim 1 , wherein the frequency band is divided into sub-bands; the transmitters being arranged to determine a sequence of sub-bands, and to transmit each element of the hopping sequence in a sub-band defined by the sequence of sub-bands at a channel defined by the sequence of channels. 8. The wireless network of claim 1 , wherein the transmitting device is arranged for selecting a hopping sequence among a plurality of possible sequences. 9. The wireless network of claim 8 , wherein the selection of a hopping sequence is based on a synchronization state of the frequency reference of the transmitting device. 10. The wireless network of claim 8 , wherein the hopping sequence is signalled through a first frequency of the hopping sequence. 11. The wireless network of claim 1 , wherein the transmitting device is arranged for signalling a value of a hopping frequency as synthesized. 12. The wireless network of claim 11 , wherein the frequency band is divided into sub-bands; the transmitters being arranged to determine a sequence of sub-bands, and to transmit each element of the hopping sequence in a sub-band defined by the sequence of sub-bands at a channel defined by the sequence of channels, wherein the value of a hopping frequency as synthesized is implicitly signalled through the choice of the first sub-band. 13. The wireless network of claim 11 , wherein the value is explicitly signalled by including in spread spectrum signal modulated data designating the channel or the frequency used for the first element or for any element in the hopping sequence.