Electromagnetic signal booster

What is claimed is: 1. An electromagnetic (EM) signal booster, comprising: a bandpass filter comprising a high pass filter and a low pass filter coupled to the high pass filter, and further comprising a low cutoff frequency and a high cutoff frequency, both cutoff frequencies being adjustable; a first amplifier coupled to the high pass filter to amplify a filtered signal from the bandpass filter; and a second amplifier coupled to the first amplifier to further amplify the filtered signal from the band pass filter, wherein the high cutoff frequency is independently adjusted to within a first threshold value above a minimum high cutoff frequency and the low cutoff frequency is independently adjusted to within a second threshold value below a maximum cutoff frequency, wherein said first and second threshold values are such that, after said adjustments, a maximum telemetry error rate exceeds a measured telemetry error rate by at least 0.1% of the maximum telemetry error rate, wherein the maximum telemetry error rate is set based on factors selected from the group consisting of minimum vertical data resolution and statistical analysis of accuracy of formation data versus an amount of data discarded due to error. 2. The EM signal booster of claim 1 , wherein, to process an EM telemetry signal, the bandpass filter filters and the first and second amplifiers amplify the EM telemetry signal. 3. The EM signal booster of claim 1 , wherein each of the first and second amplifiers comprises a bipolar junction transistor. 4. A method for operating an electromagnetic (EM) signal booster, comprising: determining a maximum telemetry error rate; providing an EM signal booster including an adjustable bandpass filter having a high cutoff frequency; independently setting the high cutoff frequency to a value below which a measured telemetry error rate would meet or exceed the maximum telemetry error rate; independently setting the low cutoff frequency to a different value above which the measured telemetry error rate would meet or exceed the maximum telemetry error rate; after independently setting the high and low cutoff frequencies, using the EM signal booster to process EM telemetry signals; and using the processed EM telemetry signals to generate a display of information. 5. The method of claim 4 , wherein said EM signal booster is installed in a telemetry receiver system at the surface and the EM telemetry signals are received at the EM signal booster from a downhole tool. 6. The method of claim 5 , wherein said measured telemetry error rate is based on said EM telemetry signals. 7. The method of claim 4 , further comprising: prior to setting the high cutoff frequency to said value, decreasing the high cutoff frequency from an initial value until the measured telemetry error rate exceeds the maximum telemetry error rate. 8. The method of claim 7 , wherein, when the high cutoff frequency is set to said value, the maximum telemetry error rate exceeds the measured telemetry error rate by a predetermined threshold. 9. The method of claim 8 , wherein said predetermined threshold is 0.1% of the maximum telemetry error rate. 10. The method of claim 4 , further comprising: prior to setting the low cutoff frequency to said different value, increasing the low cutoff frequency from an initial value until the measured telemetry error rate exceeds the maximum telemetry error rate. 11. The method of claim 10 , wherein, when the low cutoff frequency is set to said different value, the maximum telemetry error rate exceeds the measured telemetry error rate by a predetermined threshold. 12. The method of claim 11 , wherein the predetermined threshold is 0.1% of the maximum telemetry error rate. 13. The method of claim 4 , wherein using the EM signal booster to process EM telemetry signals comprises filtering and amplifying said EM telemetry signals. 14. The method of claim 4 , wherein the maximum telemetry error rate is set based on factors selected from the group consisting of minimum vertical data resolution and statistical analysis of accuracy of formation data versus an amount of data discarded due to error. 15. A logging system, comprising: a drill string, positioned in a wellbore, that houses a measurement device to obtain downhole measurements and that further houses a first telemetry transceiver to communicate the downhole measurements; and a surface system housing a second telemetry transceiver to receive the downhole measurements from the first telemetry transceiver, said second telemetry transceiver comprising a bandpass filter, a first amplifier coupled to the bandpass filter to amplify a filtered signal from the bandpass filter, and a second amplifier coupled to the first amplifier to further amplify the filtered signal from the band pass filter, wherein the bandpass filter includes a high pass filter and a low pass filter coupled to the high pass filter, and wherein the bandpass filter further includes a low cutoff frequency and a high cutoff frequency, both cutoff frequencies being independently adjustable, wherein the high cutoff frequency is independently adjusted to within a first threshold value above a minimum high cutoff frequency and the low cutoff frequency is independently adjusted to within a second threshold value below a maximum low cutoff frequency. 16. The logging system of claim 15 , wherein the amplifier is to invert the phase of a downhole measurement signal received by the second telemetry transceiver. 17. The logging system of claim 15 , wherein the amplifier comprises a bipolar junction transistor. 18. The logging system of claim 15 , wherein, within the second telemetry transceiver, the bandpass filter and the amplifier are positioned upstream of a telemetry demodulator.