Systems and methods for low power magnetic field generation for atomic sensors using electro-permanent magnets

What is claimed is: 1. A method of magnetic field generation with an atomic sensor, the method comprising: laser cooling a sample of atoms in a chamber; and trapping the sample of atoms in a magneto-optical trap within the chamber by applying an atom trapping field across the sample of atoms using at least one pair of electro-permanent magnet units; wherein each electro-permanent magnet unit of the at least one pair of electro-permanent magnet units comprises: a first magnetic ring of a first magnetic material; a second magnetic ring of a second magnetic material; and a coil of magnet wire that is wrapped around one or both of the first magnetic ring and the second magnetic ring; wherein applying an atom trapping magnetic field across the sample of atoms further comprises applying a first pulse of current having a first duration and amplitude to the coil of magnetic wire, wherein the applied first pulse of current also switches each electro permanent magnet unit of the at least one pair of electro-permanent magnet units from an off state to an on state by switching a magnetic polarity of the second magnetic ring without switching a polarity of the first magnetic ring. 2. The method of claim 1 , further comprising: performing an atomic interrogation scheme on the sample of atoms while momentarily de-energizing the atom trapping magnetic field across the sample of atoms. 3. The method of claim 1 , wherein the sample of atoms comprises one of atomic Rubidium (Rb), Cesium (Cs), atomic Calcium (Ca) or atomic Ytterbium (Yb). 4. The method of claim 1 , wherein in the off state, a first magnetic field of the first magnetic ring and a second magnetic field of the second magnetic ring are oppositely polarized in order to offset each other, and wherein, in the on state, the first magnetic field of the first magnetic ring and the second magnetic field of the second magnetic ring are similarly polarized in order to add to each other. 5. The method of claim 1 , the first magnetic material having a first magnetic hardness sufficient to not change polarity in response to the first pulse of current; and the second magnetic material having a second magnetic hardness that is less than the magnetic hardness of the first magnetic material such that the second magnetic material will change its polarity in response to the first pulse of current, but wherein the second magnetic material has a hardness that is sufficient in order to not change polarity in response to the first magnetic pulse of current applied to the first magnetic ring. 6. The method of claim 1 , wherein the least one pair of electro-permanent magnet units comprises a first electro-permanent magnet unit having a first center ring hole and a second electro-permanent magnet unit having a second center ring hole; wherein the laser cooling further comprises: launching a first laser beam provided by a first laser source through the first center ring hole towards the second center ring hole, and launching a second laser beam provided by a second laser source through the second center ring hole towards the first center ring hold, wherein the first laser beam and the second laser beam are collinear with one another and intersect at the magneto-optical trap. 7. The method of claim 1 , wherein laser cooling further comprises applying a first laser beam and a second laser beam into the magneto-optical trap with each laser beam being aligned to an axis of an anti-Helmholtz magnetic field. 8. The method of claim 1 , further comprising: probing the sample of atoms in order to measure a net magnetic field; and calibrating at least a first electro-permanent magnet unit of the at least one pair of electro-permanent magnet units based on the net magnetic field measured by the probing. 9. The method of claim 8 , wherein the first electro-permanent magnet unit further comprising: at least one shim coil; and wherein calibrating at least the first electro-permanent magnet unit comprises controlling a feedback current to the at least one shim coil based on the net magnetic field measured by the probing. 10. A cold atom sensor, the cold atom sensor comprising: a vacuum chamber having a sample of atoms sealed within the vacuum chamber; at least one pair of electro-permanent magnet units arranged across the vacuum chamber, the least one pair of electro-permanent magnet units comprising a first electro-permanent magnet unit having a first center ring hole and a second electro-permanent magnet unit having a second center ring hole; a first laser source configured to launch a first laser beam through the first center ring hole and towards the second center ring hole, and a second laser source configured to launch a second laser beam through the second center ring hole and towards the first center ring hold, wherein the first laser beam and the second laser beam are collinear; wherein the first laser source and the second laser source are configured to laser cool the sample of atoms when the first laser beam and the second laser beam are energized and the first electro-permanent magnet unit and the second electro-permanent magnet unit are configured to produce an atom trapping magnetic field that holds the sample of atoms in an magneto-optical trap; wherein each electro-permanent magnet unit of the at least one pair of electro-permanent magnet units comprises: a first magnetic ring of a first magnetic material; a second magnetic ring of a second magnetic material; and a coil of magnet wire that is wrapped around one or both of the first magnetic ring and the second magnetic ring; wherein the at least one pair of electro-permanent magnet units are configured to produce the atom trapping magnetic field across the sample of atoms by applying a first pulse of current having a first duration and amplitude to the coil of magnetic wire, wherein the applied first pulse of current also switches each electro-permanent magnet unit of the at least one pair of electro-permanent magnet units from an off state to an on state by switching a magnetic polarity of the second magnetic ring without switching a polarity of the first magnetic ring. 11. The cold atom sensor of claim 10 , wherein the cold atom sensor is configured to perform an atomic interrogation on the sample of atoms while momentarily de-energizing the atom trapping magnetic field across the sample of atoms by switching a polarity of the second magnetic ring. 12. The cold atom sensor of claim 10 , wherein when switched to an off state, a first magnetic field of the first magnetic ring and a second magnetic field of the second magnetic ring are oppositely polarized in order to offset each other, and wherein when switched to an on state, the first magnetic field of the first magnetic ring and the second magnetic field of the second magnetic ring are similarly polarized in order to add to each other. 13. The cold atom sensor of claim 10 , the first magnetic material having first magnetic hardness sufficient to not change polarity in response to the first pulse of current; and the second magnetic material having a second magnetic hardness that is less than the magnetic hardness of the first magnetic material such that the second magnetic material will change its polarity in response to the first pulse of current, but wherein the second magnetic material has a hardness that is sufficient hi order to not change polarity in response to the first magnetic pulse of current applied to the first magnetic ring. 14. The cold atom sensor of now, wherein the first laser beam and the second laser beam are each aligned to an axis of the atom trapping magnetic fie