FORECASTING THE INTENSITY OF UPPER LEVEL AND ASSOCIATED SURFACE FEATURES

ISOTHERM-CONTOUR RELATIONSHIP.— Little movement will occur if the isotherms and contours are symmetrical (no advection). Lows will intensify and retrogress if cold air advection occurs to the west and fill and progress eastward if warm air advection occurs to the west. FORECASTING THE INTENSITY OF UPPER LEVEL AND ASSOCIATED SURFACE FEATURES Many of the same considerations used in the movement of closed centers aloft may also apply to forecasting their intensity. Extrapolation and the use of time differentials aid in forecasting the change and magnitude of increases and decreases. Again, rise and fall indications must be used in conjunction with advection considerations, divergence indications, and other previously discussed factors. Intensity Forecasting Principles (Highs) The following text discusses how atmospheric conditions affect the forecasted intensity of high pressure systems. l Highs undergo little or no change in intensity when isotherms and contours are symmetrical . Highs intensify when warm air advection occurs on the west side of the high. . Highs weaken when cold air advection occurs on the west side of the high. . Blocking highs usually intensify during westward movement and weaken during eastward movement. . Convergence and height rises occur in the downstream trough when high-speed winds with a strong gradient approach low-speed winds with an anticyclonic weak gradient. This is often the case in ridges where the west side contains the high-speed winds; the ridge intensifies due to this accumulation of mass. This situation has also been termed overshooting. This situation can be detected at the 500-hPa level, but the 300-hPa level is better suited because it is the addition or removal of mass at higher levels that determines the height of the 500-hPa contours. . Rise and fall centers on the time differential chart indicate the changes in intensity, both sign (increasing, decreasing) and magnitude of change, if any, in decimeters. The magnitude of the height rises or falls can be adjusted if other indications reveal that a slowing down or a speeding up of the processes is occurring, and expected to continue. Intensity Forecasting Principles (Lows) The following text discusses how atmospheric conditions affect the forecasted intensity of low-pressure systems. l Lows and cutoff lows deepen when cold air advection occurs on the west side of the trough. . Lows fill when warm air advection occurs on the west side of the low. . Lows fill when a jet maximum rounds the southern periphery of the low. . Lows fill when the jet maximum is on the east side of the low, if another jet max does not follow. . Lows deepen when the jet max remains on the west side of the low, provided the jet max to the west of the low is not preceded by another on the southern periphery or eastern periphery of the low, for this indicates no change in intensity. l The 24-hour rise and fall centers aid in extrapolating both the change and the magnitude of falls in moving lows. Again, these rise and fall indications must be considered along with advection factors, divergence indications, and the indications of the contour-isotherm relationships. FORECASTING THE FORMATION OF UPPER LEVEL AND ASSOCIATED SURFACE FEATURES The following text deals with the formation of upper level and associated surface features, and how atmospheric features affect them. Formation Forecasting Principles (Highs) The following are atmospheric condition indicators that are relevant to the formation of highs. l Cold air masses of polar and Arctic origin generally give no indication of the formation of highs at the 500-hPa level or higher, as these airmasses normally do not extend to this level. . The shallow anticyclones of polar or Arctic origin give indications of their genesis primarily on the 2-8