Matrix-controlled printhead for an electrochemical additive manufacturing system

What is claimed is: 1. A system for an electrochemical additive manufacturing system, the system comprising: an array of row traces; an array of column traces; a row driver circuit electrically coupled to the array of row traces; a column driver circuit electrically coupled to the array of column traces; a power distribution circuit; a measurement device configured to detect at least one of a voltage or a current of electrical energy; an array of deposition elements, wherein each deposition element of the array of deposition elements comprises: a corresponding deposition anode of a plurality of deposition anodes of the array of deposition elements, each deposition anode of the plurality of deposition anodes is made of an insoluble conductive material and comprises an exposed surface configured to contact an electrolyte solution of the electrochemical additive manufacturing system, wherein the plurality of deposition anodes of the array of deposition elements are electrically connected in a plurality of rows and a plurality of columns; a corresponding deposition control circuit of a plurality of deposition control circuits of the array of deposition elements, the corresponding deposition control circuit being electrically coupled to the corresponding deposition anode, a corresponding one of the array of row traces, a corresponding one of the array of column traces, and the power distribution circuit, and operable to control an amount of electrical energy flowing into the corresponding deposition anode; and a corresponding electrical sense switching circuit of a plurality of electrical sense switching circuits of the array of deposition elements, the corresponding electrical sense switching circuit being electrically coupled to the corresponding deposition anode and configured to electrically connect the corresponding deposition anode to the measurement device to detect at least one of a voltage or a current of the electrical energy flowing through the corresponding deposition anode, wherein the corresponding electrical sense switching circuit comprises a sense switching element that is modulatable between an open state, in which the corresponding deposition anode is not electrically connected to the measurement device, and a closed state, in which the corresponding deposition anode is electrically connected to the measurement device; and a controller configured to: position a surface of a cathode into aft the electrolyte solution; position the plurality of deposition anodes into the electrolyte solution such that a gap, filled with the electrolyte solution, is defined between the cathode and the plurality of deposition anodes; while transmitting electrical energy through two or more of the plurality of deposition anodes, the electrolyte solution, and the cathode, such that a quantity of a material in the electrolyte solution is deposited onto the cathode, electrically connect one of the two or more of the plurality of deposition anodes to the measurement device via the corresponding electrical sense switching circuit corresponding to the one of the two or more of the plurality of deposition anodes, such that when a first amount of the electrical energy is transmitted through the one of the two or more of the plurality of deposition anodes, a portion of the first amount of the electrical energy is transmitted to the measurement device; detect, via the measurement device, at least one of a voltage or a current of the portion of the first amount of the electrical energy; while transmitting the electrical energy through the two or more of the plurality of deposition anodes, the electrolyte solution, and the cathode, subsequent to electrically connecting the one of the two or more of the plurality of deposition anodes to the measurement device, electrically connect a second one of the two or more of the plurality of deposition anodes to the measurement device via the corresponding electrical sense switching circuit corresponding to the second one of the two or more of the plurality of deposition anodes, such that when a second amount of the electrical energy is transmitted through the second one of the two or more of the plurality of deposition anodes, a portion of the second amount of the electrical energy is transmitted to the measurement device; detect, via the measurement device, at least one of a voltage or a current of the portion of the second amount of the electrical energy; and determine a condition of a part, formed on the cathode, based on a combination of the at least one of the voltage or the current of the portion of the first amount of electrical energy, detected by the measurement device, or the at least one of the voltage or the current of the portion of the second amount of electrical energy, detected by the measurement device, by performing a thresholding operation using the at least one of the voltage or the current of the portion of the first amount of electrical energy or the at least one of the voltage or the current of the portion of the second amount of electrical energy, so that a binary image, having pixels, is generated, wherein the pixels are first pixels and second pixels, with the first pixels representing regions of higher material deposition, and the second pixels representing regions of lower material deposition. 2. The system according to claim 1 , wherein: the corresponding deposition control circuit comprises a drive switching element that is modulatable between a closed state, in which the electrical energy flows through the corresponding deposition anode, and an open state, in which the electrical energy does not flow through the corresponding deposition anode; the corresponding deposition control circuit further comprises an addressing switching element that is modulatable between a closed state, in which the drive switching element of the corresponding deposition control circuit responsively modulates into the closed state, and an open state, in which the drive switching element responsively modulates into the open state; the corresponding electrical sense switching element is automatically modulated into the closed state in response to the addressing switching element of the corresponding deposition control circuit being modulated into the closed state; and the corresponding electrical sense switching element is automatically modulated into the open state in response to the addressing switching element of the corresponding deposition control circuit being modulated into the open state. 3. The system according to claim 2 , wherein each one of the corresponding electrical sense switching element, the drive switching element of the corresponding deposition control circuit, and the addressing switching element of the corresponding deposition control circuit comprises a transistor. 4. The system according to claim 2 , wherein at least one of the corresponding electrical sense switching element, the drive switching element of the corresponding deposition control circuit, and the addressing switching element of the corresponding deposition control circuit comprises a transistor. 5. The system according to claim 1 , wherein: the corresponding electrical sense switching circuit comprises a sense line, electrically connected to the corresponding deposition anode; and the sense line of the corresponding electrical sense switching circuit of each deposition element of the array of deposition elements are electrically controlled together. 6. The system according to claim 1 , wherein the sense switching elements of at least some of the plurality of electrical sense switching circuits are independently selectively modulatable, between the open state and the closed state, relative to each other. 7. The system according to claim 1 , where