Adaptive FHSS using Detect And Avoid (DAA) is a mechanism by which a given hopping frequency is made 'unavailable' because an interfering signal was reported after transmissions on that frequency. This mechanism should operate as intended in the presence of an unwanted signal on frequencies other than those of the operating band.

Adaptive FHSS equipment using DAA should comply with the following minimum set of requirements.

• During normal operation, the equipment should evaluate the presence of a signal for each of its hopping frequencies. If it is determined that a signal is present with a level above the detection threshold defined in step 5, the hopping frequency should be marked as 'unavailable'.
• The hopping frequency should remain unavailable for a minimum time equal to 1 second or 5 times the actual number of hopping frequencies in the current (adapted) channel map used by the equipment, multiplied with the Channel Occupancy Time, whichever is greater. There should be no transmissions during this silent period on this hopping frequency. After this, the hopping frequency may be considered again as an 'available' frequency.
• The total time during which an equipment has transmissions on a given hopping frequency without re-evaluating the availability of that hopping frequency is defined as the Channel Occupancy Time. The Channel Occupancy Time for a given hopping frequency should be less than 40 ms. For equipment using a dwell time > 40 ms that wants to have other transmissions during the same hop (dwell time), an Idle Period (no transmissions) of at least 5% minimum of the Channel Occupancy Period with a minimum of 100 μs should be implemented. After the Idle Period has expired, the equipment may continue its normal operation as explained in step 1.
  
  Example: An equipment with a dwell time of 400 ms can have 9 transmission sequences of 40 ms each, separated with an Idle Period of 2 ms.
  
  For FHSS equipment using DAA with a dwell time < 40 ms, the maximum Channel Occupancy Time may be non-contiguous; in other words, spread over a number of Hopping Sequences (equal to 40 ms divided by the dwell time [ms]).
• In case the 'unavailable' channels remain in the Hopping Sequence, apart from the Short Control Signalling Transmissions, there should be no transmissions on these 'unavailable' channels. In case the 'unavailable channels' are removed from the Hopping Sequence, a minimum of N hopping frequencies should always be maintained.
• The detection threshold should be proportional to the transmit power of the transmitter: for a 20 dBm e.i.r.p. transmitter the detection threshold level (TL) should be equal to or less than -70 dBm/MHz at the input to the receiver, assuming a 0 dBi (receive) antenna assembly. This threshold level (TL) may be corrected for the (receive) antenna assembly gain (G); however, beamforming gain (Y) should not be taken into account. For power levels less than 20 dBm e.i.r.p., the detection threshold level may be relaxed to:
  Equation 3. TL = -70 dBm/MHz + 10 × log10 (100 mW / Pout)

  Pout in mW e.i.r.p.

• The equipment should comply with the requirements defined in step 1 to step 4 of the present clause in the presence of an unwanted CW signal as defined in Table 5-10.