TH16664A - How to reduce the effects of signal changes for a vibrator receiver with at least two antennas. - Google Patents

Abstract

A signal with a synchronized signal set and a data set is sent along the channel in which the signal is changed to a vibrby receiver (11,12). Such signals are received by the antenna. And it is sampled to a signal at the receiving antenna (Sin, r (k)). A channel projection (hest, r) for each antenna is generated. For Viterbi analysis A hypothetical input signal (Sa, r (Tij, k)) for the data set is generated. With the help of channel projections (hest, r), the metric value (Mr (Tij, k)) is generated from the difference between the signal received by the receiving antenna (Sin, r (k)) and the input signal. The appropriate hypothetical output (Sa, r (Tij, k)) for the vitorbis (Tij) hierarchy, for a certain hierarchy, a metric value is generated as: The sum of the metric values (M (Tj, k-1)) for the old step (Tj) at the point of the subsequent sampling period (k-1) added with the weighted sum (Kr) of The metric value (Mr (Tij, k)) that belongs to the individual channel estimate (hest, r), the appropriate metric value is generated for the total stage to the new step (Ti) and the smallest value. These metrics Will be selected according to the vibrator algorithm

Claims (5)

1.How to reduce the effect of signal variation of a vibrator receiver with at least two antennas. The receiver receives radio signals on one channel, which is easy for interference. Such method It consists of steps of: - Receiving a signal on a number of antennas. - A sampling of the signals received from the antennas into the signals received by the receiving antenna. - The generation of channel projections. Estimation of the transmitting function of the channel and - signal action in the vibrator equalizer. According to the vibrator algorithm Where the symbols Will be assumed for the distance of the witerb algorithm step with the effect Where the estimate of the channel It will include at least the two (R) channel estimation (hest, r) channel estimation (hest, r) that follows each (4) antenna, where such method, at which sampling interval is shown (k. ) Also includes a procedure of - the generation of a hypothetical input signal. (Sa, r (Tij, k)) from fictional symbols. (Sa (Tij)), with the help of the section (hest, r) channel projection, where the hypothetical input signal (Sa, r (Tij, k) for each segment estimate (hest, r) is Generated for each step phase (Tij) of the vibrator algorithm, - Generation of metric values (Mr (Tij, k)) for each channel projection (hest, r) by It depends on the received antenna signal (Sin, r (k)), which is the estimate of the channel. And appropriate hypothetical input signal (Sa, r (Tij, k)) - Generations for the phase range expressed (Tij) between the old (Tj) and the new (Ti) stages in the Viterb algorithm. Where a metric value (M (Tij, k)) as such a metric value (M (Tj, k-1)) is selected according to a Viterb algorithm. For the old step (Tj), the sampling interval (k-1) follows the displayed sampling interval point (k), which is incremented by the additional weighted sum (kr) of the metric value (Mr ( Tij, k)) belonging to the individual channel projections (hest, r), and - the formation of which the metric value corresponds to the metric value (M (Tij, k) for the stage distance field shown (Tij). This is used for the total stage (Tij) of the new step (Ti) and the selection based on the vibrator algorithm. Which the smallest value (M (Tj, k)) of these metric values (M (Tij, k)) at the step to new step (Ti). 2. The method according to claim 1 is characterized by the creation of individual metric values. (Mr (Tij, k)) depends on the absolute value of the difference between the signals at the receiving antenna. (Sin, r (k)) and an appropriate assumed input signal. (Sa, r (Tij, k)) 3. Method according to any of Clause 1 or 2 It is characterized by the fact that all of the coefficients (Kr) for the weighting of metric values (Mr (Tij, k)) are the same values that are controlled with (Kr = P / R). 4. Method for any of Clause 1 or 2 There is a peculiarity where the coefficient (Kr) is selected for the gravity of metric values (Mr (Tij, k)) depending on the signal magnitude at the appropriate receiving antenna (formula). 5. The method according to claim 4 has special characteristics in which the coefficient (Kr) for gravity of metric values (Mr (Tij, k)) will be proportional (c) to the energy of the signal at the receiving antenna (Sin, r (k)).