Line locator with accurate horizontal displacement detection
First Claim
1. A line locator for locating an elongated concealed conductor that emits a magnetic field at an operating frequency, comprising:
- an input circuit including a left sensor, a right sensor and a convolution amplifier coupled to the left sensor and the right sensor, the left sensor and the right sensor detecting the magnetic field;
a single channel signal processing circuit coupled to the input circuit and outputting a left/right signal, wherein the signal processing circuit includes a filter coupled to receive the output signal from the input circuit;
a phase detector coupled to the filter, the phase detector receiving a PHREF signal from a PHREF source; and
at least one AGC amplifier coupled between the filter and the phase detector, the AGC amplifier receiving an AGC signal from an AGC source; and
wherein the convolution amplifier provides an output signal to the signal processing circuit that is proportional to a convolution of an output signal of the left sensor and an output signal from the right sensor.
2 Assignments
0 Petitions
Accused Products
Abstract
A line locator having the capability of determining the horizontal position with respect to a line is described. The line locator includes a left sensor and a right sensor of any orientation. The left sensor and the right sensor are coupled to a convolution amplifier that amplifies the sum of the output signals from the left sensor and the right sensor. The detection circuitry includes automatic gain control amplification where the automatic gain control signal is obtained digitally from a digital controller. In addition, the detection circuitry includes phase detection circuitry where the phase reference signal is obtained from an external transmitter that is coupled to the line. In addition, the AGC signal and the phase reference signal may both be obtained by processing output signals from magnetic field detectors in the line locator.
125 Citations
26 Claims
-
1. A line locator for locating an elongated concealed conductor that emits a magnetic field at an operating frequency, comprising:
-
an input circuit including a left sensor, a right sensor and a convolution amplifier coupled to the left sensor and the right sensor, the left sensor and the right sensor detecting the magnetic field;
a single channel signal processing circuit coupled to the input circuit and outputting a left/right signal, wherein the signal processing circuit includes a filter coupled to receive the output signal from the input circuit;
a phase detector coupled to the filter, the phase detector receiving a PHREF signal from a PHREF source; and
at least one AGC amplifier coupled between the filter and the phase detector, the AGC amplifier receiving an AGC signal from an AGC source; and
wherein the convolution amplifier provides an output signal to the signal processing circuit that is proportional to a convolution of an output signal of the left sensor and an output signal from the right sensor. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18)
a sensor; a filter coupled to receive the output signal from the sensor; and
a zero-crossing detector coupled to receive an output signal from the filter and that outputs an output signal comprising a pulse train having a frequency equal to that of an input signal to the zero-crossing detector.
-
-
9. The line locator of claim 8, further including a mixer coupled to receive an output signal from the filter, the mixer adding a LO FREQ signal with the output signal from the filter and outputting a signal having a frequency equal to an IF frequency;
- and
wherein the output signal has a frequency equal to the IF frequency.
- and
-
10. The line locator of claim 1, wherein the PHREF source includes
a receiver that receives a signal from an external, transmitter, the external transmitter providing an active frequency to the elongated concealed conductor; - wherein
the receiver outputs the PHREF signal in response to the signal received from the external transmitter.
- wherein
-
11. The line locator of claim 1, wherein the AGC source includes
a sensor; -
a filter coupled to receive an output signal from the sensor;
at least one AGC amplifier; and
an AGC generator coupled to receive an output signal from the filter that provides an AGC signal to the AGC amplifier to keep the output signal from the filter a constant.
-
-
12. The line locator of claim 1, further including
a top sensor; -
a bottom sensor; and
a bottom/top processing circuit coupled to receive signals from the top sensor and the bottom sensor, the processing circuit providing a field strength signal in response to signals from either of top sensor or the bottom sensor.
-
-
13. The line locator of claim 12, wherein the processing circuit further provides a PHREF signal.
-
14. The line locator of claim 12, wherein the processing circuit further provides an AGC signal.
-
15. The line locator of claim 12, wherein the processing circuit includes
a reference channel coupled to the top sensor, the reference channel providing an AGC signal; - and
an observed channel coupled to the bottom sensor, the observed channel providing a field strength signal.
- and
-
16. The line locator of claim 12, further including a microprocessor controller coupled to receives and displays the left/right signal and the field strength signal.
-
17. The line locator of claim 16, wherein the microprocessor controller further computes the depth of the elongated concealed conductor.
-
18. The line locator of claim 16, wherein the microprocessor controller further computes a calibrated lateral displacement of the line locator with respect to the elongated concealed conductor.
-
19. A method of detecting a concealed conductor that emits a magnetic field at an operating frequency, comprising:
-
convoluting the output signals from a left sensor and a right sensor to generate a convoluted signal, the left sensor and the right sensor sensing the magnetic field;
filtering the convoluted signal with a band-pass filter having center frequency equal to the operating frequency;
generating a PHREF signal; and
phase detecting the filtered convoluted signal using the PHREF signal in order to generate a left/right signal. - View Dependent Claims (20, 21, 22, 23, 24, 25, 26)
generating an AGC signal; amplifying the convoluted signal and the filtered convoluted signal with an AGC amplifier, the AGC amplifier having a gain determined by the AGC signal.
-
-
23. The method of claim 22, wherein generating the AGC signal includes;
-
measuring the field strength from a center sensor; and
calculating the AGC signal in a microprocessor controller based on the field strength.
-
-
24. The method of claim 22, wherein generating the AGC signal includes:
-
measuring a field strength using a reference sensor in a reference channel, the reference channel including at least one AGC amplifier;
comparing the field strength with a reference field strength to determine the AGC signal.
-
-
25. The method of claim 19, wherein generating the PHREF signal includes:
-
receiving a signal from a transmitter, the transmitter being coupled to the concealed conductor and exciting the concealed conductor into emitting the magnetic field of the operating frequency;
converting the signal from the transmitter to the PHREF signal.
-
-
26. The method of claim 19, wherein generating the PHREF signal includes:
-
detecting a magnetic field signal with a center sensor;
mixing the magnetic field signal with a LO FREQ signal;
filtering the mixed magnetic field signal with an IF filter; and
producing the PHREF signal with a zero crossing detector.
-
Specification