Abstract: A phase digitizing system includes an analog-to-digital converter (ADC), multiple phase accumulators and a processing device. The ADC generates sample segments of digital signal waveform samples based on an analog composite input signal received in a measurement channel, the composite input signal includes a first signal having a first frequency F1 and a second signal imported from a reference channel having a second frequency F2. The processing device is coupled to the phase accumulators, and digitally processes each sample segment with outputs of the phase accumulators, and continually generates digital phase data The processing device further provides increment values to each of the phase accumulators based on the digital phase data, causing an output of a first phase accumulator to represent an instantaneous phase of the first signal, and an output of a second phase accumulator to represent an instantaneous phase of the second signal.

Abstract: An apparatus calibrates an optical downconverter configured to receive an optical input signal at a signal input and an optical reference signal at a reference input, and to provide at multiple output nodes characterizing signals for characterizing the optical input signal. The downconverter includes receivers having corresponding optical inputs and respectively providing the characterizing signals at the output nodes, and multiple optical signal paths connected between one of the signal and reference inputs and one of the optical inputs. The apparatus includes a signal analyzing unit coupled to the output nodes and configured to receive and analyze the characterizing signals, a first switch for selectively enabling the optical input signal, and a second switch for selectively enabling the reference signal.

Abstract: A network analyzer comprises: a signal source configured to supply an input signal to a device, wherein the device is configured to generate a phase reference signal; a receiver configured to receive the phase reference signal from the device and to measure a phase response of the device according to the phase reference signal; and a calibration component configured to compare the measured phase response of the device with an actual phase response of the device to identify a tracking parameter for the receiver.

Abstract: A method is provided for controlling an FM-AFM including a cantilever having a resonant frequency and an excitation system configured to oscillate the cantilever in response to a drive signal. The method includes determining latency of the excitation system; receiving a deflection signal indicating a deflection of a cantilever tip; mixing the deflection signal with a first sine signal output by a PLL indicating a frequency shift of a frequency response of the cantilever; measuring the frequency shift in response to the drive signal; determining spurious phase of the cantilever based on the determined latency, the resonant frequency of the cantilever, and the measured frequency shift; providing a second sine signal having a phase that is advanced by the determined spurious phase to preemptively compensate for subsequent spurious phase of the cantilever; and driving the excitation system using the second sine signal with an adjusted amplitude as the drive signal.

Abstract: A system for performing analog-to-digital conversion comprises a sampling unit that generates multiple digital samples from an analog input signal at each recurrence of a periodic interval, and a processing unit that combines the digital samples to produce a digital output signal. In certain embodiments, the sampling unit comprises multiple analog-to-digital converters arranged in parallel, and the processing unit comprises a digital signal processor that detects outliers in the digital samples and averages any non-outliers among the digital samples to generate the digital output signal.

Abstract: A plasma generation device includes: a substrate having a first surface and a second surface; a stripline resonant ring disposed on the first surface of the substrate, and defining a discharge gap; a pair of electrode extensions connected to the stripline resonant ring at the discharge gap; a ground plane disposed on the second surface of the substrate; a gas flow element configured to flow gas between at least one of: (1) the discharge gap, and (2) the pair of electrode extensions; and a structure disposed adjacent the substrate to form an enclosure that substantially encloses at least a region including the discharge gap and the electrode extensions, the enclosure being adapted to contain a plasma.

Abstract: A method of determining the mass-to-charge ratios of ions in a sample is disclosed. The method includes determining a data acquisition time, where the data acquisition time is a predetermined fraction of the greatest time of flight. The method also includes providing ions from a continuous beam of a sample to a time-of-flight mass analyzer at pulse intervals having a duration equal to the predetermined fraction of the greatest flight time. The method also includes measuring a peak width and a flight time value for each of the ion species in the sample after summing the data acquired during several pulse intervals and correcting the measured flight time values according to a correlation of measured peak width values with calibration data of peak width versus flight time.

Abstract: In a system and method for feature alignment in chromatographic systems, the system runs a first sample through a first separation column. The system determines a first set of features for the first sample run. The system runs a second sample through a second separation column and detects a second set of features for the second sample run. The system estimates a systematic shift in features between the first sample run through the first separation column and the second sample run through the second separation column. The system adjusts the second set of features detected for the second sample run through the second separation column based on the estimated systematic shift to obtain a third set of adjusted features.

Abstract: A method of operating a data processing system to examine a compiled program for violations of a set of rules that do not constitute violations detected by the compiler that generated the program. The method includes obtaining a restricted rule set defined in terms of rules in a decompiled representation of the program. The method also includes decompiling the compiled program to the decompiled representation of the compiled program in which the restricted rule set is defined, examining the decompiled representation of the compiled program for a violation of the restricted rule set to determine if any of the rules are violated, and providing an output indicating that one of the rules was violated.

Abstract: An atomic force microscope (AFM) system comprises a cantilever arm attached to a probe tip. The system controls a height of the cantilever arm to press the probe tip against a sample and then separate the probe tip from the sample, to detect a disturbance of the cantilever arm after the separation of the probe tip from the surface, and to engage active damping of the cantilever arm to suppress the disturbance.

Abstract: Methods, apparatus and systems for acquiring spectrometric data from analyte ions implement transient-level data acquisition and peak correction in a time-of-flight mass spectrometer. Transient spectra including analyte peaks and reference mass peaks are recorded, from which a set of averaged peak centroids of the reference masses is generated. The peaks of reference masses in each transient spectrum are compared to the averaged peak centroids. From this comparison, an appropriate correction function is applied to each transient spectrum to correct the positions of the analyte peaks in each transient spectrum. The corrected transient spectra are then summed to obtain a corrected averaged spectrum.

Abstract: A downconverter mixes a first comb spectrum with a local oscillator signal to generate a second comb spectrum in a lower frequency range. The first comb spectrum comprises frequency components separated from each other according to a frequency spacing interval, and the LO signal has a frequency offset relative to the first comb spectrum, where the frequency offset is a rational fraction of the frequency spacing interval. The second comb spectrum comprises lower and upper sideband responses corresponding to respective lower and upper sideband signals of the first comb spectrum. The lower and upper sideband responses in the second comb spectrum can be distinguished from each other based on the frequency offset.

Abstract: An inlet liner is provided for use in an inlet assembly of a chromatograph system. The inlet liner has an elongate tube that extends along a longitudinal axis and defines a bore that extends along the longitudinal axis and has an inner bore surface. At least one projection extends from the inner bore surface into the bore. Chromatograph systems are provided including the exemplary inlet liner(s). Methods are also provided for analyzing a sample containing a matrix in a chromatograph system having an inlet assembly connected to a chromatograph column. The method includes positioning an exemplary inlet liner in the inlet assembly, flowing the sample through the inlet liner, and adhering a portion of the matrix to a projection surface of at least one projection of the inlet liner.

Abstract: A control device for a sample separation apparatus, the sample separation apparatus including a first separation unit and a second separation unit downstream of the first separation unit and supplied with the fluidic sample after treatment by the first separation unit. A control device is configured for controlling the first separation unit to execute a primary separation sequence within a time interval for separating the fluidic sample into fractions, and for controlling the second separation unit to execute secondary separation sequences within the time interval for further separating the separated fractions into sub-fractions, wherein the secondary separation sequences form part of a common sample separation method defined by a common specification of the sample separation involving a set of parameters, and adjusting, over a progress of the primary separation sequence, at least one parameter according to which at least one of the plurality of secondary separation sequences is executed.

Abstract: A method is provided for performing real-time spectral analysis of a non-stationary signal. The method includes sampling the non-stationary signal, using an observation window having a length short enough to approximate a stationary signal, to provide an initial set of sampled data, buffering the initial set of sampled data to obtain multiple buffered sets of sampled data, filtering the initial set of sampled data and the buffered sets of sampled data, using corresponding filter responses, to obtain multiple filtered sets of sampled data, and performing a chirp-z-transform (CZT) of the filtered sets of sampled data to provide a set of discrete Fourier transforms (DFT) coefficients. A total signal spectrum of the non-stationary signal is reconstructed using the set of DFT coefficients.

Abstract: A sample injector (500) for injecting a fluid into a fluidic path, wherein the sample injector (500) comprises a robot arm (502) configured for moving an injection needle (506), when being connected to the robot arm (502), between a fluid container (510) containing the fluid and a seat (508) in fluid communication with the fluidic path, the injection needle (506) configured for aspirating the fluid from the fluid container (510), when the injection needle (506) has been moved to the fluid container (510), and for injecting aspirated fluid into the fluidic path, when the injection needle (506) is accommodated in the seat (508), and the seat (508) configured for accommodating the injection needle (506) and providing fluid communication with the fluidic path, wherein the robot arm (502) is configured for selectively disconnecting the injection needle (506) from the robot arm (502) when the injection needle (506) is accommodated in the seat (508), and wherein the robot arm (502) is configured for performing a fur

Abstract: A flame photometric detector (FPD) for use in a gas chromatography (GC) apparatus is described. The FPD has an emission block that is maintained in a first temperature range, and a transfer line that is maintained in a second temperature range that is greater than the first temperature range. The FPD is coupled to a light detector, such as a photomultiplier tube (PMT).

Abstract: Disclosed is a voltage-current characteristic generator that includes: a voltage source; a current source; a selector for selecting and outputting the output of either the voltage source or the current source; a sensing portion, connected to an output of the selector, for outputting the output of the selector and for sensing, and feeding back, the voltage and current of the output; and a controller for receiving the voltage and current detected by the sensing portion and for setting the subsequent outputs in the voltage source and the current source, wherein, in addition to setting the subsequent outputs, the controller evaluates an operating mode wherein the subsequent output from the selector is to be from either the voltage source or the current source.

Abstract: A method for operating a data processing system to display data related to a plurality of packets that traverse a communication link is disclosed. A copy of the packets that traverse the link is provided including a timestamp corresponding to each packet that defines a time at which the packet traversed the link. A display is generated having first and second regions. The first region includes an X-Y chart in which each packet is represented by a multi-value glyph denoting a first property related to that packet, the first property having more than two values. The second region includes a first annotation glyph for one of the packets, the first annotation glyph being located at the X-location corresponding to the timestamp for the packet. The first annotation glyph is present if that data packet has a second property.

Abstract: Described is a directional coupler for forward coupling energy from an input port to a coupling port. The directional coupler has a coupling factor and an operating frequency and an operating wavelength corresponding to the operating frequency.