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Jitter, timing

Linearly polarized, near-diffraction-hmited, mode-locked 1319 and 1064 nm pulse trains are generated in separate dual-head, diode-pumped resonators. Each 2-rod resonator incorporates fiber-coupled diode lasers to end-pump the rods, and features intracavity birefringence compensation. The pulses are stabilized to a 1 GHz bandwidth. Timing jitter is actively controlled to < 150 ps. Models indicate that for the mode-locked pulses, relative timing jitter of 200 ps between the lasers causes <5% reduction in SFG conversion efficiency. [Pg.233]

There are several other sources of noise that are specific to lifetime imaging. In particular, noise related to the timing jitter of... [Pg.126]

Because of the low timing-jitter (down to 25 ps) TCSPC-based systems are often equipped with a MCP-PMT at detriment of acquisition speed (<106 counts per second). On the other hand, a TG-SPC system equipped with four gates and a fast PMT (10 MHz) could be slower than a TCSPC at low count-rates (<100 kHz), because of a lower photon-economy. However, already at 1 MHz, the former would be almost three times faster and more the one order of magnitude faster at 10 MHz. [Pg.135]

The operating principle of an MCP-PM is based on electron multiplication using a continuous dynode structure of ca. 10 um diameter holes, giving a more compact and hence faster time response when compared with conventional photomultipliers. Rise-times of 150 psec and transit-time jitter (i.e., impulse response) of ca. 25 psec FWHM at 200 counts/sec noise at room temperature have been recorded with the 6 fun channel Hamamatsu R3809 MCP-PM.(87)... [Pg.404]

Tero, you should increase the frequency until it gets as high as it will still arc under compression pressure reliably. Need that to reduce timing jitter. [Pg.18]

Figure 11 The components of the timing jitter of the laser synchronized subpicosecond pulse radiolysis, crj is the length of the electron pulse (rms), c,- is the length of the probe light (rms), and ctj is the timing fluctuation (rms). Figure 11 The components of the timing jitter of the laser synchronized subpicosecond pulse radiolysis, crj is the length of the electron pulse (rms), c,- is the length of the probe light (rms), and ctj is the timing fluctuation (rms).
If there is no fluctuation of laser intensity, we have to measure /q only once. Actually, the envelope of laser pulses changes in a relatively long time range (typically from several minutes to a few tens of minutes) because of the change of environmental factors such as room temperature and coolant temperature. There is also an intensity jitter caused by factors such as the mechanical vibration of mirrors and the timing jitter of electronics. Furthermore, in our system, the laser system is located about 15 m from the beam port to prevent radiation damage to the laser system. (Later, it was moved into a clean room, which was installed in the control room to keep the room temperature constant and to keep the laser system clean. The distance is about 10 m.) Therefore it is predicted that a slight tilt of a mirror placed upstream will cause a displacement of the laser pulse at the downstream position where the photodetector is placed. [Pg.285]

The time resolution of the system was measured and found to be about 1 ns. This value was mainly dominated by the pulse width of the ion beam. In fact, because in some cases the pulse width of the ion beam and the transit time jitter of the ion have larger values caused by many factors (ion energy and species, operating conditions of the accelerator and the pulsing system, the type of beam pick up, etc.). [Pg.108]

In a LWA, the electron and laser pulses are inherently synchronized, so the time jitter sources associated with photocathode accelerators are not an issue. The ultimate time resolution should depend only upon the cross correlation between the laser and electron pulses and the physics of the electron beam interaction with the... [Pg.134]

On the Osaka University thermionic cathode L-band linac, a time resolution of two picoseconds was achieved using magnetic pulse compression and time jitter compensation systems (Fig. 13). The time jitter between the Cerenkov light from the electron beam and the laser pulse was measured shot-by-shot with a femtosecond streak camera to accurately determine the relative time of each measurement in the kinetic trace. In this way, the time jitter that would otherwise degrade the time resolution was corrected, and the remaining factor dominating the rise time was the electron-light velocity difference over the 2-mm sample depth. [Pg.143]

Fig. 13. Schematic of high time-resolution pulse radiolysis equipped with a magnetic pulse compression and time jitter compensation system at ISIR, Osaka University. An example of the rise time of the hydrated electron signal at 780 nm is shown. Fig. 13. Schematic of high time-resolution pulse radiolysis equipped with a magnetic pulse compression and time jitter compensation system at ISIR, Osaka University. An example of the rise time of the hydrated electron signal at 780 nm is shown.
Access to subpicosecond electron pulses has already been achieved at Osaka University by a new double-decker accelerator concept. In order to reduce the time jitter for the detection of the optical absorption signals in pulse radiolysis studies, the light pulse used for the pump-probe system is Cerenkov emission which is produced in the same cell by a synchronized second electron beam and is concomitant with the electron path. The distance between the axes of the two beams is 1.6 mm. The pulse durations of these electron pulses, which are both produced by delayed beams issued from the same laser, are 430 + 25 fs and 510 20 fs, respectively, and the charge per pulse is 0.65 nC. An electron bunch of 100 fs and 0.17 nC has already been generated. [Pg.152]

Due to the finite width of the lamp pulse (2-5 ns) and the time jitter in the detection system (voltage discriminators, TAC, photomultiplier tube) the experimental decay F(tj) is a convolution of the instrument response function and the tme decay curve... [Pg.93]

The present limitatkins in time resolution for the time-correlated photon counting technique are due to the time jitter in the detection electronics and the transit time spread in the photomultqjlier tube ( 500 ps). Mth future improvements in these components and using cw mode-locked lasers as an excitation source, deconvolution of fluorescence lifetimes to a few tens of picoseconds oidd be achieved. Alter-... [Pg.105]

For all X-ray diffraction results, we assumed an X-ray beam of 8 keV photon energy with a sin2-pulse shape, and a half-width of 100 fs, which should roughly correspond to the situation at the Linear Coherent Light Source (LCLS) including timing jitter [6]. [Pg.204]

The effective resolution of a TCSPC experiment is characterised by its instrument response function (IRF). The IRF contains the pulse shape of the light source used, the temporal dispersion in the optical system, the transit time spread in the detector, and the timing jitter in the recording electronics. With ultrashort laser pulses, the IRF width at half-maximum for TCSPC is typically 25 to 60 ps for microchannel-plate (MCP) PMTs [4, 211, 547], and 150 to 250 ps for conventional short-time PMTs. The IRF width of inexpensive standard PMTs is normally... [Pg.22]

Of course, a simple leading edge discriminator cannot be used to trigger on such pulses. The amplitude jitter would introduce a timing jitter of the order of the pulse rise time (Fig. 4.1, left). In practice the timing jitter is even larger because any discriminator has an intrinsic delay that depends on the signal slope speed and the amount of overdrive. [Pg.47]

In most TCSPC modules, rate counters complement the CFDs in the photon pulse and reference charmels of TCSPC devices. The CFDs of the photon channel and the reference charmel are often different. The photon ehannel is designed for lowest amplitude-induced timing jitter and the reference ehannel for highest trigger rate. Some TCSPC devices do not use a CFD in the referenee charmel at all and rely instead on the stability of the reference pulses. [Pg.49]

Most FCS setups therefore use single photon avalanehe photodiodes [323,424], usually SPCM-AQR detectors from Perkin Elmer [408]. These deteetors have a quantum efficiency that reaches 80% at 800 nm. However, single photon APDs often have a timing delay and transit time jitter dependent on wavelength and count rate. The changes can be of the order of 1 ns. Recording a fluorescence decay curve under this condition delivers questionable results. [Pg.184]

Of special interest for time-correlated single photon counting are the linear fo-cused dynodes, which give fast single electron response and low transit-time jitter, and the fine mesh and metal channel types, which offer position sensitivity when used with an array of anodes. Moreover, PMTs with fine-mesh and metal channel dynodes can be made extremely small, which results in low transit time, low transit-time jitter, and a fast single-electron response. [Pg.214]

See other pages where Jitter, timing is mentioned: [Pg.263]    [Pg.110]    [Pg.119]    [Pg.120]    [Pg.122]    [Pg.127]    [Pg.133]    [Pg.436]    [Pg.283]    [Pg.5]    [Pg.885]    [Pg.223]    [Pg.457]    [Pg.310]    [Pg.18]    [Pg.48]    [Pg.48]    [Pg.123]    [Pg.129]    [Pg.348]    [Pg.18]    [Pg.34]    [Pg.335]    [Pg.24]    [Pg.24]    [Pg.47]    [Pg.47]    [Pg.60]    [Pg.174]    [Pg.206]   
See also in sourсe #XX -- [ Pg.119 , Pg.120 , Pg.122 ]



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Jitter

Pulse timing jitter

Time jitter compensation

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