Apparatus and method of landing a well in a target zone

What is claimed is: 1. An method comprising: controlling activation of a transmitter sensor on a tool structure arranged relative to a drill bit in a well to probe a formation; acquiring signals in a receiver sensor of the tool structure in response to activation of the transmitter sensor, the receiver sensor set apart from the transmitter sensor by a separation distance sufficiently large to provide real time processing of the signals prior to reaching a boundary of a target zone, wherein the separation distance is sufficiently large to sense ahead of the drill bit by a sensing distance ranging from above 10 feet up to 200 feet ahead of the drill bit; processing the acquired signals in real time, including generating data corresponding to formation properties ahead of the drill bit including conducting inversion operations with respect to the acquired signals; conducting a confidence verification process by comparison of results of at least two inversion operations from at least two acquired signals while drilling before using the results of the inversion operations to control geosteering the well; and geosteering the well when a difference between the at least two inversion operations is less than a threshold value and the generated data corresponds to desired formation properties such that the well approaches a target in the target zone with minimal or no overshoot of the target. 2. The method of claim 1 , wherein the method includes: repeating controlling activation of the transmitter sensor and acquiring signals corresponding to the activation at each of different log points during drilling the well; conducting inversion operations on the acquired signals corresponding to the different log points, generating inverted data from the acquired signals correlated to the different log points; performing a confidence process on the inverted data generated from the acquired signals correlated to the different log points; adding, to a target list, inverted data that satisfied the confidence process, or parameters generated from the inverted data that satisfied the confidence process; ranking the target list; and geosteering toward the target based on the ranked target list. 3. The method of claim 2 , wherein ranking the target list includes sorting the target list with respect to time that the inverted data is generated. 4. The method of claim 3 , wherein sorting the target list with respect to time includes applying weights such that higher weights are applied to most recently generated inverted data. 5. The method of claim 2 , wherein ranking the target list includes computing forward responses for a number of target models, the forward responses being results of forward modeling with respect to the number of target models, and applying weights according to a difference between each forward response and a measured response corresponding to one or the acquired signals from which the inverted data or parameters is added to the target list such that the smaller the difference the higher is the weight assigned. 6. The method of claim 2 , wherein ranking the target list includes calculating average values of the inverted data in the target list, and applying weights to the inverted data in the target list according to a difference between the inverted data in the target list and the average values of the inverted data in the target list such that the smaller the difference the higher is a value of weight assigned. 7. The method of claim 2 , wherein ranking the target list, the target list having elements, includes: sorting the target list with respect to time that the generated inverted data is generated, including a most recently generated inverted data, and applying a time weight such that a higher time weight is given to the most recently generated inverted data; computing forward responses for a number of target models, the forward responses being results of forward modeling with respect to the number of target models, and applying response weights according to a difference between each forward response and a measured response corresponding to one or the acquired signals from which the inverted data or parameters is added to the target list such that the smaller the difference the higher is a value of response weight assigned; calculating average values of the inverted data in the target list, and applying averaged value weights to the inverted data in the target list according to a difference between the inverted data in the target list and the average values of the inverted data in the target list such that the smaller the difference the higher is a value of averaged value weight assigned; and adding the time weight, the response weight, and the averaged value weight for each element in the target list to determine a model from which to geosteer. 8. The method of claim 2 , wherein the method includes, after reaching the target, the target having a shape in the target zone: repeating controlling activation of the transmitter sensor and acquiring a signal corresponding to the activation at each of different log points during drilling the well; conducting inversion operations on the acquired signals corresponding to the different log points, generating inverted data from the acquired signals correlated to the different log points; performing a confidence process on the inverted data generated from the acquired signals correlated to the different log points; and geosteering the well along the shape of the target. 9. The method of claim 1 , wherein conducting the inversion operation includes generating a parameter set that minimizes error between measured voltage and a forward response of a forward model. 10. The method of claim 1 , wherein geosteering the well includes directing drilling of the well to the target identified as a target plane in the target zone. 11. The method of claim 1 , wherein geosteering the well includes geosteering along a course according to a dogleg criteria. 12. The method of claim 11 , wherein the dogleg criteria includes a maximum angle of around 10° per 100 feet. 13. The method of claim 1 , wherein the method includes iteratively controlling activation of the transmitter sensor, acquiring a signal corresponding to the activation, and processing the acquired signal to identify the target or the target zone. 14. The method of claim 1 , wherein the method includes: repeating controlling activation of the transmitter sensor, acquiring signals, in the receiver sensor or another receiver of the tool structure, corresponding to the activation, processing the acquired signals of the repeated acquisition to generate inverted data, and geosteering the well in an iteration process such that the iteration process provides for detection of the target or geosteering to the target; generating, for a next signal to be acquired, an estimated signal value from processing a last signal processed; acquiring the next signal and generating a measured signal value of the next signal; and if a difference between the estimated signal value and the measured signal value is within a threshold value, refraining from processing the acquired next signal to generate inverted data and accepting the inverted data generated from the last signal processed as accurate. 15. The method of claim 14 , wherein generating, for the next signal to be acquired, the estimated signal value includes using a forward model. 16. The method of claim 15 , wherein using a forward model includes using a forward model used in an inversion operation to generate the inverted data from the last signal.