Long Term Monitoring. The WCD will provide long term monitoring of installed BMPs. The amount and frequency of monitoring will be as directed by the WD Administrator and board, based on the individual BMP installed.
Long Term Monitoring. Periodic monitoring of the well network is performed to characterize the Northwest Plume and help determine the effectiveness of system performance. The monitoring frequency is summarized in Section 4.6. Xxxxx generally are located upgradient of the EWs or peripheral to the system where TCE concentrations generally are not expected to fluctuate significantly as a result of system operation. EWs are sampled quarterly at sampling ports under normal operating conditions.
Long Term Monitoring. 1. NMED signed a Joint Funding Agreement with the U.S. Geological Survey to install four sondes in the Animas and San Xxxx Xxxxxx to provide continuous water-quality measurements. Real time data from the sondes are available from the USGS website (xxxxx://xxxxxxxxxx.xxxx.xxx/).
Long Term Monitoring. The FHLBNY Member Financial Institution and the Sponsor shall each perform their respective long term monitoring obligations set forth in the Plan and AHP Requirements. The FHLBNY Member Financial Institution and the Sponsor shall each further perform such other reporting as may be required by the AHP Requirements, or as may otherwise be requested by the FHLBNY.
Long Term Monitoring. Periodic monitoring of the well network is performed to characterize the Northeast Plume and help determine the effectiveness of system performance. Revisions to future monitoring frequency may be proposed to the FFA parties for discussion and concurrence. If the parties agree to change the monitoring frequency; then the agreement will be documented in an errata to the approved Northeast Plume O&M Plan and other applicable documents. EWs are sampled monthly at sampling ports under normal operating conditions.
Long Term Monitoring. CSS will identify and provide long term monitoring of individuals with clinical and situational complexities in order to help avert crisis reactions, provide strategies for service entry changing needs, and prevent multiple transfers within the system. Approximately seventy five (75) individuals will be targeted for long term monitoring.
Long Term Monitoring. The Executive Secretary remarked on the potential for collaboration between Russia, France, Georgia and other countries interested in developing EWS, as there is an increasing need for such technology. He reminded about the importance of narrowing the gap between scientific research and implementation by civil protection and decision- makers of national authorities. Directors were encouraged to transmit such significant results to the relevant ministries. (Link to presentation). GREECE: X. Xxxxx (European Centre for Forest Fires - ECFF) X. Xxxxx presented the 2019 activities recollecting a year of intense fires and prolonged drought in Greece. Countries such as Norway, Sweden, Scotland also experienced wildfires which resulted in the prolonged distribution of smoke harmful to the respiratory system, adversely affected wildlife and biodiversity as well as increasing pollution as far as Athens. In the light of this, ECFF established a project on Fine and ultrafine particles from forest fires in Central Evia, Greece to seek ways to protect the population against exposure to toxic smoke inhalation, especially vulnerable groups. X. Xxxxx presented a case study entitled Challenges and lessons learned from past major environmental disasters due to technological or wildland urban interface fire incidents was published in the 2019 edition of the Global Assessment Report. X. Xxxxx also participated in the Workshop in Baku with a presentation entitled Coping with disaster risks focusing on vulnerable people as well as the Joint meeting of the groups of experts on protected areas held on 3-4 October in Trondheim, Norway, as part of ECFF’s dissemination and networking strategy. (Link to presentation). GREECE: X. Xxxx (European Centre on Prevention and Forecasting of Earthquakes - ECPFE)
Long Term Monitoring. Once an active landslide is identified at a site and repeated activity in the future has to be anticipated, long-term monitoring may be necessary. Long-term monitoring is required to i) implement an early warning system; ii) to check the effectiveness of the stabilization or other remedial measures and, last but not least; iii) to validate the kinematic model formulated for the landslide. The most suitable remote sensing techniques for long-term monitoring are ground based techniques such as GB-InSAR, terrestrial LiDAR and ground based non-metric cameras (cf. Table 1). These techniques are applicable in many cases but most suitable for slow (to moderately slow) moving landslides. GB-InSAR, as any other radar interferometric technique, is not suitable for to monitor rapid landslides; this is due to the possible ambiguity of the signal (as it was mentioned in the section Detection of new landslides). Displacements given by SAR sensors require calibration using in-situ measurements, i.e. displacements obtained directly on the landslide (e.g. inclinometric, GPS, surveying or extensometric displacements). Once the calibration is made, GB-InSAR is very useful for monitoring (slow) landslides due to the following reasons: a) it has a high accuracy (0.3 mm), b) a high range (2 km, up to 5 km in special cases), c) a high temporal resolution (5 minutes), which makes it suitable for early-warning and, d) under favourable conditions th advantage that it provides areal information. The latter is the techniques main advantage in relation to in-situ monitoring techniques. As a shortcoming, the measured displacements are primarily the projection of the 3D value on the direction to the sensor, the so-called ‘line of sight (LOL) displacement’. Terrestrial LiDAR (or Terrestrial Laser Scanning) has a coarser temporal resolution than the GB-InSAR, because the acquisition and the post-processing of LiDAR data (aligning, filtering, etc.) requires at least several hours. Typical revisiting period is several months. The main advantages of the technique are: high resolution, good accuracy (centimetre level), large coverage on steep slopes, 3D information, and high flexibility (i.e., easy set-up and portability). Some limitations of TLS are its relatively low maximum range (usually < 700 m) and the requirement of a direct visibility (optical line of sight). However, very recently, the first long-range scanners (up to 3 km) have been released. The above characteristics make TLS very ...
Long Term Monitoring. The WCD will provide long term monitoring of installed BMPs. The amount and frequency of monitoring will be as directed by the Administrator, based on the individual BMP installed. 2023- 40 hours @ $42/hour = $1,680 2023- 40 hours @ $44/hour = $1,760 Task 3 Total = $3,440
Long Term Monitoring. IKU places irrecoverable but enforceable claims under long-term monitoring at its discretion, and arranges sporadic collection measures, credit-rating checks, address investigations, insolvency register applications, bankruptcy discharge checks etc. The long-term monitoring lasts until the entire claim has been settled, but until no later than the debtor’s bankruptcy discharge or the statute of limitations. IKU is entitled to reject client orders to undertake long-term monitoring.
