To acquire a mass spectrum for a wide mass range, a normal analysis execution controlling unit controls components to repeatedly perform measurement while changing setting m/z by a predetermined m/z at a time, and a mass spectrum summarizing processing unit summarizes data pieces each obtained by each time of measurement to generate the mass spectrum. Radio-frequency voltage applied to an ion guide and the like is changed based on the setting m/z. The radio-frequency voltage for the setting m/z is determined using a table in which a relationship between a position on an axis between upper and lower limits of the mass range and the radio-frequency voltage is substantially the same regardless of the mass range.

A traveling wave multipole comprising two or more pairs of segmented electrodes arranged around a central axis; and a voltage supply. The voltage supply configured to supply the segments of each pair of electrodes with a different RF and DC potential; and match RF and DC potentials with a location of an ion of target m/z moving through the traveling wave multipole such that as the ion travels along the multipole the ion experiences the same RF and DC potentials while another ion of a second target m/z concurrently experiences a different RF and DC potentials at another location within the traveling wave multipole.

The invention generally relates to systems and methods for separating ions at about or above atmospheric pressure. In certain embodiments, the invention provides systems that include an ionization source that generates ions and an ion trap. The ion trap is maintained at about or above atmospheric pressure and includes a plurality of electrodes and at least one inlet configured to receive a gas flow and at least one outlet. The system is configured such that a combination of a gas flow and one or more electric fields produced by the electrodes separates the ions based on mass-to-charge ratio and sends the separated ions through the at least one outlet of the ion trap.

The invention generally relates to logical operations in mass spectrometry. The system comprising a mass spectrometer comprising one or more ion traps; and a central processing unit (CPU), and storage coupled to the CPU for storing instructions that when executed by the CPU cause the system to apply one or more scan functions to the one or more ion traps, the scan functions being combine together.

A mass spectrometer includes an ion source configured to ionize a sample to produce ions; a mass analyzer configured to separate the ions based on their mass-to-charge ratio; a detector configured to detect ions; an ion optics component configured to direct ions along at least part of the path from the ion source to the mass analyzer to the detector; and a controller. The controller is configured to switch the source at a first time from a first polarity source voltage to a second polarity source voltage; and switch the detector or the ion optics component at a second time from a first voltage to a second voltage, the second time being offset from the first time, the first voltage being the first polarity detector voltage or the first polarity ion optics voltage and the second voltage being the second polarity detector voltage or the second polarity ion optics voltage.

A data acquisition method in a mass spectrometer includes a. providing an ion source to generate precursor ions; b. feeding the precursor ions into a first mass analyzer that selects one mass window such that the precursor ions located outside the mass window pass through the first mass analyzer and the precursor ions located within the mass window cannot pass through the first mass analyzer; c. feeding the precursor ions passing through the first mass analyzer into a collision cell for collisional dissociation, to generate product ions; d. feeding the product ions into a second mass analyzer for mass analysis and recording a spectrum; and e. repeating Steps b-d. Each time when Step b is repeatedly performed, the selected mass window does not overlap with all the mass windows previously selected. After all the mass windows in a mass range are selected, the repetition is stopped.

A method of operating a quadrupole device is disclosed that comprises operating the quadrupole device in a first mode of operation, passing ions into the quadrupole device while the quadrupole device is operated in the first mode of operation, and then operating the quadrupole device in a second mode of operation. Operating the quadrupole device in the second mode of operation comprises applying one or more drive voltages to the quadrupole device, and operating the quadrupole device in the first mode of operation comprises applying one or more reduced drive voltages or not applying one or more drive voltages to the quadrupole device.

A tuning system may acquire, from a mass spectrometer during a batch of one or more analytical runs performed with the mass spectrometer, tune data associated with an operating characteristic of the mass spectrometer. The tuning system may determine, based on the tune data, a value of an operating parameter configured to adjust the operating characteristic of the mass spectrometer and set the operating parameter to the determined value.

A method of operating a quadrupole device is disclosed. The method comprises applying a main drive voltage to the quadrupole device and applying three or more auxiliary drive voltages to the quadrupole device. The three or more auxiliary drive voltages correspond to two or more pairs of X-band or Y-band auxiliary drive voltages.

A method of operating a quadrupole device is disclosed. The method comprises operating the quadrupole device in a first mode of operation, wherein ions within a first mass to charge ratio range are selected and/or transmitted by the quadrupole device, and operating the quadrupole device in a second mode of operation, wherein ions within a second different mass to charge ratio range are selected and/or transmitted by the quadrupole device. In the first mode of operation, the quadrupole device is operated in a normal mode of operation wherein a main drive voltage is applied to the quadrupole device, or in a first X-band or Y-band mode of operation wherein a main drive voltage and two or more auxiliary drive voltages are applied to the quadrupole device. In the second mode of operation, the quadrupole device is operated in a second X-band or Y-band mode of operation wherein a main drive voltage and two or more auxiliary drive voltages are applied to the quadrupole device.