An ink impact point correction apparatus for automatically measuring and correcting an impact point of ink using a pattern on a substrate, on which a coordinate system is displayed, and a substrate treating system including the same are provided. The ink impact point correction apparatus includes a recognition unit for acquiring information on the impact point of ink at a plurality of points located on a substrate; and a correction unit for correcting a position of an ink discharge point on the substrate based on the information on the impact point, wherein a coordinate pattern in the form of a coordinate system is formed at the plurality of points.

A liquid discharge control device includes an adhesion state detector and circuitry. The adhesion state detector detects an adhesion state of a droplet adhering to a medium being conveyed. The droplet is discharged from a liquid discharge device. The circuitry controls a discharge operation of the liquid discharge device based on an operation parameter, determines a difference between the adhesion state of the droplet and a reference adhesion state of the droplet on the medium being conveyed, and updates the operation parameter based on a determination result.

A drive waveform acquisition unit that acquires a drive waveform, a drive voltage generation unit that generates the drive voltage, a jetting frequency setting unit that sets a jetting frequency on the basis of drop velocity information representing a relationship between the jetting frequency and a drop velocity in a single-shot, and a drive voltage supply unit that supplies the drive voltage to the jetting head are included. The jetting frequency setting unit sets a jetting frequency at which the drop velocity is a second velocity equal to or less than a first velocity in the drop velocity information as the jetting frequency of the jetting head.

A magnetic-ink reading device includes a housing and a conveyor in the housing. A medium inlet and outlet port for inserting and pulling out a medium printed using magnetic ink are in the housing. The conveyor conveys the medium along a conveying path. The magnetic-ink reading device includes a magnetizing mechanism configured to magnetize the magnetic ink of the medium on the conveying path and a magnetism detection head disposed near the magnetizing mechanism and configured to read magnetism of the magnetized magnetic ink. The magnetic-ink reading device includes a reversing mechanism provided on the medium inlet and outlet port side of the conveying path and configured to reverse front and rear surfaces of the medium on a reversing path on an inside. The reversing mechanism includes a retraction path for temporarily retracting the medium when the magnetism of the medium is read by the magnetism detection head.

A liquid discharge method of discharging a liquid from a nozzle of a liquid discharge head by applying a drive pulse to a drive element of the liquid discharge head includes an acquisition step of acquiring a recording condition, and a driving step of applying the drive pulse to the drive element. The drive pulse includes a first potential, a second potential different from the first potential, and a third potential different from the first potential and the second potential. The second potential is to be applied after the first potential, and the third potential is to be applied after the second potential. In the liquid discharge method, in the driving step, the drive pulse in which a time of the second potential varies depending on the recording condition acquired in the acquisition step is applied to the drive element.

A liquid discharge method of discharging a liquid from a nozzle of a liquid discharge head by applying a drive pulse to a drive element of the liquid discharge head includes an acquisition step of acquiring a recording condition, and a driving step of applying the drive pulse to the drive element. The drive pulse includes a first potential, a second potential different from the first potential, and a third potential different from the first potential and the second potential. The second potential is to be applied after the first potential, and the third potential is to be applied after the second potential. In the liquid discharge method, in the driving step, the drive pulse in which a time of the third potential varies depending on the recording condition acquired in the acquisition step is applied to the drive element.

In an embodiment, a method for controlling a printer is provided. The method includes: receiving a set of parameters associated with a printer by a computing device, wherein the printer is depositing ink on a substrate to generate a line; measuring a width of the line by the computing device; receiving a duty cycle associated with the printer by the computing device; using the received duty cycle, the set of parameters, and a model, estimating one or more unknown parameters of the set of parameters by the computing device; receiving a desired width of the line by the computing device; and if the desired width is not the same as the measured width: adjusting the duty cycle associated with the printer based on the set of parameters and the model so that the measured width is closer to the desired width by the computing device.

A printing system is disclosed. The printing system includes at least one physical memory device to store ink model logic and one or more processors coupled with the at least one physical memory device to execute the ink model logic to generate first ink model parameter data for a first print medium based on first ink deposition data for a second print medium and first optical density measurement data for the first print medium.

The apparatus and methods include moving an optical fiber over a fiber path that includes a marking location at which resides a marking unit that dispenses an ink-jet stream. A centering method is performed whereby the optical fiber is incrementally moved in a lateral direction through the path of the ink-stream and the mark number density of marks formed on the optical fiber is measured along with the optical fiber position. A process window is defined by the range of lateral fiber positions over which a target mark number density is formed on a consistent basis. A controller calculates an optimum fiber path position and stores it memory for future reference while also moving the fiber path to the optimum position. The initially wet ink marks are dried and the fiber coated with a transparent protective overcoat to form a coated and marked optical fiber.

A droplet measurement method is described. The droplet measurement method may include discharging a droplet on a substrate, scanning the droplet by moving a scanning unit, and calculating a volume of the droplet by using the thicknesses of the portions of the droplet. The scanning unit may include optical scanners arranged in multiple directions, storing thicknesses of portions of the droplet scanned by the scanning unit.