ABSTRACT
The aim of this study was the analysis of reliability and day-to-day-variability of power (PMLSS), blood lactate concentration (BLCMLSS) and heart rate (HRMLSS) in maximal lactate- steady-state during cycle ergometry. 32 male subjects (25±3 years, 180±7 cm, 76±8 kg) have undergone several constant-load-tests lasting 30 min to determine 4 PMLSS. During the test, blood-samples were taken from the earlobe after 4, 8,10, 14, 18, 22, 26 und 30 min for detecting the BLCMLSS. PMLSS was defined as the highest workload that can be maintained without accumulation of BLC by more than 0.05 mmol/l/min during the last 20 min. Mean PMLSS was 244±45 W, according to 75% of VO2max. Mean of BLCMLSS was 5.3±1.5 mmol/l/min, mean of HRMLSS was 166±10 1/min. The coefficient of variability (CV) was calculated for PMLSS, BLCMLSS and HRMLSS with 3%, 16.6% and 6.3%, respectively. The Intra-Class-Coefficient for PMLSS, BLCMLSS and for HRMLSS was determined with 0.98 (p≤0.001), 0.71 (p≤0.001), 0.92 (p≤0.001) respectively. PMLSS and HRMLSS are characterized by a low day-to-day variability that is comparable with results of different lactate threshold concepts. In comparison to PMLSS, BLCMLSS shows a greater day-to-day-variability.
Subject(s)
Anaerobic Threshold/physiology , Exercise Test/methods , Heart Rate/physiology , Lactic Acid/blood , Muscle Strength/physiology , Adult , Biomarkers/blood , Humans , Linear Models , Male , Reproducibility of ResultsABSTRACT
We report an investigation of laser frequency stabilization using a whispering gallery mode resonator that is temperature stabilized by a dual-mode technique. This dual-mode technique has yielded mode volume temperature instabilities at the nK level, suggesting that high frequency stability may also be reached. Here, we experimentally and theoretically investigate the dynamics of such a system and the important factors affecting the achievable frequency stability. We calculate that the dual-mode technique can reduce the effective fractional temperature coefficient of the reference system to 3.6×10â»8 K⻹ within the temperature feedback bandwidth. We demonstrate a 1560 nm laser stabilized to 1.3×10⻹² at 1 s and 1.1×10⻹° at 1000 s, corresponding to a long-term drift of 21 kHz/hr.
ABSTRACT
Temperature measurement with nano-Kelvin resolution is demonstrated at room temperature, based on the thermal dependence of an optical crystal anisotropy in a high quality whispering gallery mode resonator. As the resonator's TE and TM modes frequencies have different temperature coefficients, their differential shift provides a sensitive measurement of the temperature variation, which is used for active stabilization of the temperature.