Abstract: A method is provided for detecting geophysical anomalies. Electrical energy is capacitively accumulated with a charging circuit until a breakdown voltage of a switch is reached. Thereafter, the accumulated electrical energy is discharged by passing a discharge current through a transmitter antenna to transmit an electromagnetic pulse into a geophysical region. This technique allows an increase in the strength of an electromagnetic sounding signal, while simultaneously reducing energy consumption, and thereby also permitting smaller weights and dimensions for the power supply.

Abstract: A method is provided for detecting geophysical anomalies. Electrical energy is capacitively accumulated with a charging circuit until a breakdown voltage of a switch is reached. Thereafter, the accumulated electrical energy is discharged by passing a discharge current through a transmitter antenna to transmit an electromagnetic pulse into a geophysical region. This technique allows an increase in the strength of an electromagnetic sounding signal, while simultaneously reducing energy consumption, and thereby also permitting smaller weights and dimensions for the power supply.

Abstract: A method for amplifying optical signals without dependence of output signal intensity on an input-signal phase is provided. This method is based on nonlinear interaction of three phase-synchronized modes in one core of a waveguide. The method may be realized by passing the above-mentioned signals through an optical element with a waveguide (200) having pulse interaction and propagation portions (205 and 207) which receive impulses in first and second coherent waveguide modes which cause a nonlinear interaction between the first and second waveguide modes and generate a third waveguide mode. This third mode is phase-synchronized with the first and second waveguide modes. The method may be realized in optical amplifiers, switches, as well as logical optical AND gates, OR gates, etc.