TY - JOUR
T1 - Timing and synchronization of solid state pulsed power modules (SSPPM) for excimer laser applications
AU - Ness, R. M.
AU - Melcher, P. C.
AU - Saethre, R. B.
PY - 2002
Y1 - 2002
N2 - In certain applications for excimer lasers, it is critical to maintain the timing of a Solid State Pulsed Power Module (SSPPM) such that the pulsed output of the laser can be synchronized to another external event. In some cases, this synchronization must be held to times on the order of 10 ns or less. Since the operating voltage range of these magnetic modulators must vary (by up to a factor of two) in order to adjust the laser output energy, the throughput delay can also vary significantly. This timing must also be maintained over other possible laser operating conditions and scenarios, including various repetition rates, duty cycles, etc. External factors, such as cooling water temperature and flow rate, air temperature, etc. can also impact the system timing. Data will be presented detailing the contribution of each potential item in the timing sequence of these modulators as they impact the overall system timing jitter and drift. Design details will also be discussed as to how these issues are mitigated and minimized so as to reduce their effect and meet the overall system timing requirements.
AB - In certain applications for excimer lasers, it is critical to maintain the timing of a Solid State Pulsed Power Module (SSPPM) such that the pulsed output of the laser can be synchronized to another external event. In some cases, this synchronization must be held to times on the order of 10 ns or less. Since the operating voltage range of these magnetic modulators must vary (by up to a factor of two) in order to adjust the laser output energy, the throughput delay can also vary significantly. This timing must also be maintained over other possible laser operating conditions and scenarios, including various repetition rates, duty cycles, etc. External factors, such as cooling water temperature and flow rate, air temperature, etc. can also impact the system timing. Data will be presented detailing the contribution of each potential item in the timing sequence of these modulators as they impact the overall system timing jitter and drift. Design details will also be discussed as to how these issues are mitigated and minimized so as to reduce their effect and meet the overall system timing requirements.
UR - http://www.scopus.com/inward/record.url?scp=0036999111&partnerID=8YFLogxK
U2 - 10.1109/MODSYM.2002.1189531
DO - 10.1109/MODSYM.2002.1189531
M3 - Article
AN - SCOPUS:0036999111
SN - 1076-8467
SP - 525
EP - 528
JO - IEEE Conference Record of Power Modulator Symposium
JF - IEEE Conference Record of Power Modulator Symposium
ER -