Backscatter localization

The invention claimed is: 1. An apparatus, comprising: at least one processor; and at least one memory including computer program code which, when executed by the at least one processor, causes the apparatus: to receive distance information associated with at least two access points, APs, from a set of APs, wherein the distance information associated with each AP of the at least two APs is determined based on: dynamically switching the role of said each AP in different time intervals to a transmission mode for transmitting a localization signal to a tag, with the other APs in the set of APs switched to a receiving mode for receiving a backscatter signal from the tag in response to the transmitted localization signal from said each AP, wherein, for each time interval, the AP in the transmission mode is excluded from being in the receiving mode and the other APs in the receiving mode are excluded from being in the transmission mode; for each time interval, determining, by the other APs in the receiving mode, distance information with respect to the AP in the transmission mode based on the received backscatter signals corresponding to the transmitted localization signal from said AP; and to determine a location estimate of the tag based on the received distance information with respect to each of at least two different APs when in the transmission mode in different respective time intervals. 2. The apparatus of claim 1 , wherein the distance information associated with an AP comprises data representative of: one or more backscatter signal measurements performed by another AP in receiving mode when said AP is in transmission mode; or a compound distance estimate with respect to said AP, the tag and the another AP that is performed by said another AP in receiving mode when said AP is in transmission mode. 3. The apparatus of claim 1 , wherein: the apparatus is further configured for coordinating, from a set of time intervals, when APs from the set of APs dynamically switch between the transmission mode and the receiving mode; and the set of APs are each configured to randomly switch between the transmitting mode and the receiving mode, wherein the probability of each AP in the set of APs randomly switching to the receiving mode being greater than the probability of each AP in the set of APs randomly switching to the transmitting mode. 4. The apparatus of claim 1 , wherein: the apparatus is further configured for coordinating, from a set of time intervals, when APs from the set of APs dynamically switch between the transmission mode and the receiving mode; and a designated AP of the set of APs is configured to coordinate the dynamic switching of at least two APs in the set of APs between the transmitting mode to the receiving mode over a set of two or more time intervals, wherein each time interval in the set of time intervals has one of the at least two APs switched in the transmitting mode and the other of the at least two APs switched in the receiving mode. 5. The apparatus of claim 1 , wherein one of at least two APs from the set of APs is configured to dynamically switch to the transmission mode during a time interval different to the other of said at least two APs and dynamically switch to a receiving mode before or after the time interval. 6. The apparatus of claim 1 , wherein: a first AP of the set of APs is configured to dynamically switch to the transmission mode for transmitting a first localization signal to the tag in a first time interval and the other APs of the set of APs remain in the receiving mode for receiving a first backscatter signal from the tag corresponding to the first localization signal, wherein each AP of the other APs in the set of APs determine distance information for the first AP with respect to said each AP based on receiving the first backscatter signal; and a second AP of the set of APs is configured to dynamically switch from a receiving mode to a transmission mode for transmitting a second localization signal to the tag in a second time interval different to the first time interval, and the first AP is configured to dynamically switch to the receiving mode for receiving, along with any other APs in the set of APs in the receiving mode, to receive a second backscatter signal from the tag corresponding to the second localization signal, wherein the first AP and said any remaining APs in the set of APs determine distance information for the second AP with respect to the first or said any remaining APs based on receiving the second backscatter signal; wherein receiving distance information for each AP in the set of APs further comprises: receiving distance information for the first AP with respect to one or more of the other APs of the set of APs during the first time interval; and receiving distance information for the second AP with respect to one or more of the first AP and any remaining APs during the second time interval; and wherein determining a location of the tag further comprises: determining the location of the tag based on the distance information received in the first and second time intervals. 7. The apparatus of claim 1 , wherein a number of APs configured for transmitting a localization signal to the tag is increased based on an accuracy requirement of the location estimate. 8. The apparatus of claim 1 , wherein a number of time intervals for APs to be dynamically switched to the transmission mode for transmitting a localization signal to the tag is increased based on a required reduction in measurement noise in relation to the distance information. 9. The apparatus of claim 1 , wherein each AP in the set of APs receiving the backscatter signal from the tag determines distance information for the transmitting AP with respect to said each AP based on calculating carrier phases of the received backscatter signal resulting from said APs transmitting localization signals to the tag, and said each AP sending said determined distance information to said apparatus. 10. The apparatus of claim 9 , wherein the localization signal transmitted from an AP in the set of APs in the transmission mode further includes multiple frequency tones, and the APs in the set of APs in the receiving mode each receive a backscatter signal from the tag in response to the multiple frequency tones of the localization signal transmitted to the tag, the received distance information for the AP in the transmission mode with respect to each of the APs in the set of APs in the receiving mode includes a plurality of phase measurements associated with the resulting backscatter signals. 11. The apparatus of claim 1 , wherein the determining the distance information for an AP further comprises: determining distance information for an i-th AP further comprising calculating a compound distance between an i-th transmitting AP, the tag, and a j-th receiving AP, denoted d i +d j , based on: d i + d j = c 2 ⁢ π ⁢ N ⁢ ∑ n = 1 N -