Determining distance between two radio transceivers

The invention claimed is: 1. A method for determining a distance between an initiator radio transceiver and a reflector radio transceiver, the method comprising: the reflector radio transceiver determining a frequency offset of a sampling clock signal from one or more radio signals received by the reflector radio transceiver, and determining an adjustment factor in dependence on the determined frequency offset; the initiator radio transceiver transmitting a first radio signal at a first transmission time; the reflector radio transceiver: receiving the first radio signal at a first reception time; generating an electrical signal representative of the received first radio signal; generating a sampled signal by sampling the electrical signal using the sampling clock signal; processing the sampled signal to determine a first reception-time value, representative of the first reception time, at a temporal resolution that is finer than a sampling period of the sampling clock signal, whereby the first reception-time value comprises a fractional component representative of a fraction of the sampling period; and using the fractional component and the adjustment factor to transmit a second radio signal at a second transmission time that follows a pulse of the sampling clock signal by an offset amount that is equal to said fractional component plus the adjustment factor, such that the second transmission time is delayed from the first reception time by a predetermined dwell time that is determined to an accuracy finer than the sampling period; and the initiator radio transceiver: receiving the second radio signal at a second reception time; determining a second reception-time value representative of the second reception time; and processing the second reception-time value and a first transmission-time value representative of said first transmission time to determine a distance value representative of a distance between the initiator radio transceiver and the reflector radio transceiver. 2. The method of claim 1 , wherein the first and second radio signals are in a 2.4 GHz band. 3. A reflector radio transceiver for use in a method for determining a distance between an initiator radio transceiver and the reflector radio transceiver, wherein the reflector radio transceiver is configured to: determine a frequency offset of a sampling clock signal from one or more radio signals received by the reflector radio transceiver, and determine an adjustment factor in dependence on the determined frequency offset; receive a first radio signal from the initiator radio transceiver at a first reception time; generate an electrical signal representative of the received first radio signal; generate a sampled signal by sampling the electrical signal using the sampling clock signal; process the sampled signal to determine a first reception-time value, representative of the first reception time, at a temporal resolution that is finer than a sampling period of the sampling clock signal, whereby the first reception-time value comprises a fractional component representative of a fraction of the sampling period; and use the fractional component and the adjustment factor to transmit a second radio signal at a second transmission time that follows a pulse of the sampling clock signal by an offset amount that is equal to said fractional component plus the adjustment factor, such that the second transmission time is delayed from the first reception time by a predetermined dwell time that is determined to an accuracy finer than the sampling period. 4. The reflector radio transceiver of claim 3 , comprising a digital-to-analog converter that is clocked by the sampling clock signal, for sampling radio signals received by the reflector radio transceiver, and an analog-to-digital converter that is clocked by the sampling clock signal, for converting digital signals to analog signals for transmission as radio signals by the reflector radio transceiver. 5. The reflector radio transceiver of claim 3 , comprising a digital correlator configured to cross-correlate the sampled signal with reference data representative of the first timing signal, wherein the reflector radio transceiver is configured to process an output of the digital correlator using a timing-offset determination method to determine the first reception-time value. 6. The reflector radio transceiver of claim 3 , configured to store the first reception-time value, including the fractional component, as data in a memory of the reflector radio transceiver. 7. The reflector radio transceiver of claim 3 , comprising a fractional delay filter for introducing a delay to the transmission of the second radio signal of less than one sampling period. 8. The reflector radio transceiver of claim 7 , configured to control the fractional delay filter to implement a delay that is equal to the fractional component or that is a predetermined function of the fractional component. 9. The reflector radio transceiver of claim 3 , comprising a memory for storing a digital signal template data, representing part or all of the second radio signal at a plurality of different fractional delays, wherein the reflector radio transceiver is configured to select template data from the memory in dependence on the factional component and to use the selected template data for transmitting the second radio signal. 10. The reflector radio transceiver of claim 9 , wherein the respective fractional delays are spaced at equal intervals over one sampling period. 11. The reflector radio transceiver of claim 3 , wherein the second transmission time follows a pulse of the clock signal by an offset amount equal to the fractional component. 12. The reflector radio transceiver of claim 3 , wherein the second transmission time follows a pulse of the clock signal by an offset amount equal to the fractional component plus a constant adjustment factor. 13. The reflector radio transceiver of claim 3 , comprising a local oscillator for down-mixing received radio-frequency signals, wherein the local oscillator is synchronized with the sampling clock signal, and wherein the reflector radio transceiver is configured to determine the frequency offset of the sampling clock by determining a frequency offset between the local oscillator and a received radio signal. 14. The reflector radio transceiver of claim 3 , wherein the first and second radio signals are respective modulated digital signals comprising a respective modulated pseudo-random sequence. 15. The reflector radio transceiver of claim 3 , configured to support a version of the Bluetooth™ Low Energy protocol. 16. A radio system comprising an initiator radio transceiver and the reflector radio transceiver of claim 3 , wherein: the initiator radio transceiver is configured to transmit said first radio signal at a first transmission time; and the initiator radio transceiver is further configured to: receive the second radio signal at a second reception time; determine a second reception-time value representative of the second reception time; and process the second reception-time value and a first transmission-time value representative of said first transmission time to determine a distance value representative of a distance between the initiator radio transceiver and the reflector radio transceiver. 17. The radio system of claim 16 , wherein the initiator radio transceiver is further configured to: determine the first transmission-time value at a temporal resolution that is finer than the second sampling period; generate a second electrica