A 7-Year 10-Meter Es Propagation Study Using PropNET - Part 4 of 5

Probability Analysis – Another Method to Predict “Es” Activity:

Due to the fact that the United States’ distribution of population and Ham activity was not equal, a better measurement practice is to apply an equal value to one single reception (PropNET capture) within a one hour period.  In other words, a single occurrence in a measured period equals the occurrence of many. The probability of an occurrence is now measured, not the actual number of captures in the period.     

Therefore, every hour documented and measured in the 7 years of data was re-applied.  If a capture occurred during the hour it was given a value of one (1).  If no capture occurred, it was given a value of zero (0).  The result is that statistical probabilities can be applied to any hour on any day that an opening could occur. The quality and quantity of the hourly opening had no bearing.  Opportunity is what is being measured, not how much was being worked.

The key factor is that opportunity will always produce results. The more opportunity existed, the better the results.

The following charts data are based on these factors:

1. The days prior to and after the Summer Solstice (June 21)
2. All 24 hours are used in the day
3. The probability measured (percent) is that on any hour of that day, we will have at least one occurrence of a 10-Meter PropNET Es capture.

The results show a very clear trend on how Es begin, increase and then decline during the season.  Daily total probability is based on that on the day measured, that on any measured hour, the occurrence of a 10-Meter Es PropNET capture occurred.  It was amazing to see the daily differences with 7 years of cumulative volume data.  The end of the Es season was difficult to identify with probability data. For most years the “median” date for captures was on 6/22 and for probability it was 6/25 a 3 day swing, but the last year it evened up.  Captures are spread evenly throughout the season, but opportunities slightly favor the second half of the season as it takes more time to drop off.  

Some probabilities can increase or decrease 20% in one day.  As in the total captures chart, the Probability Chart represented the dramatic increase in opportunities in early May. The best day for Es opportunities was June 18 and July 4, with 67% of the total hours on these dates having a capture. By May 22, the occurrence of an Es capture for any hour of the day increases to near 50%, and remains fairly consistent for most days until July 29.  One factor that draws your attention is why there are certain days less productive than others. The right skewed and tailed appearance in probability is somewhat clearer than the capture volume statistics as the season takes about 2 more weeks after the solstice to finally end.  When applying a 2^nd degree trend-line to the daily data, the coefficient of determination (R squared) is closer to the data. This trend-line has been applied to annualized data for 3 years and the coefficient of determination has improved each year.  

As in the capture charts, I averaged 3 continuous days of data around the day measured.  As in the daily charts, it was surprising how much probabilities will decline or increase in a matter of a couple of days.  Still the early seasonal increase, followed by the slow decrease the second half of the season was quite evident. Trend-lines also are very close to actual data.  

This trend is also clear when 6 consecutive days of probabilities are averaged for each measured day. Note that both the beginning and end of the Es season are clearly defined.

After measuring hourly probabilities on a daily basis, I decided to measure cumulative weekly periods to further confirm trends that I had seen in the prior charts. Also, I wished to see how probabilities of a capture changed for the actual hours within a day.  I again divided the Spring/Summer Es season into 16 weeks. I compiled 7 day segments of data for the 7 years and calculated the probability that at least one capture occurred at any given hour in this weekly period.  In 2009, I extended the measurement period by 2 weeks and reconstructed the prior 4 years.

Probability Statistics by Hour:

I was curious to find out if the probability factors would also correlate to a higher number of captures.  Probability is based on a single incident during a measured hour, not on total captures. I was very pleased to find out that the two factors did relate closely.  Only during the late afternoon were there minor shifts. This might be due to the shifts of average distances (higher) experienced during this period. The shift is negligible. Therefore, quality relates to quantity.

Probability by Weekly Periods:

The following charts are represented and discussed in terms of the week of the Spring/Summer Es season. When it is referenced, each week number corresponds to the following days:

Title                Begins             Ends

Week 1            25-Apr             1-May

Week 2            2-May              8-May

Week 3            9-May              15-May

Week 4            16-May            22-May

Week 5            23-May            29-May

Week 6            30-May            5-Jun

Week 7            6-Jun               12-Jun

Week 8            13-Jun             19-Jun

Week 9            20-Jun             26-Jun

Week 10          27-Jun             3-Jul

Week 11          4-Jul                10-Jul

Week 12          11-Jul              17-Jul

Week 13          18-Jul              24-Jul

Week 14          25-Jul              31-Jul

Week 15          1-Aug              7-Aug

Week 16          8-Aug              14-Aug

Week 17          15-Aug            21-Aug

Week 18          22-Aug            28-Aug

As shown in the Daily Probability figures, similar trends with the weekly capture computations did occur.  Before 2008, the peak of the Es season was the weeks beginning May 23 and May 30 (5^th and 6^th week). The final 3 years of the study strongly showed the peak at and after the Summer Solstice (8^th and 9^th Week).  On average, a slow decline begins after the 11^th week.  The chart reflects active hours each day rather that a percentage of the day open. For 7 weeks each season at least one half of the day has Es activity.

By the 5th week of the season, daylight period probabilities become consistent week to week and maintain the high probability levels. The evening and twilight periods (8 PM-6AM) will show higher amplitude rates of change before and after the solstice. The daytime period weekly probabilities changed little once the season was in full swing.

         

When the study was started, my opinion was that Es activity should form a perfectly shaped bell curve peaking at the Summer Solstice. Throughout the 5 years of this study, it was quite evident that capture totals and probability calculations once charted were showing that Es activity was somewhat right-skewed and right tailed.  In other words, Es activity once the season begins rises quickly then peaks before the Summer solstice. Activity then slowing declines for the remainder of the Es season.  The end of the Es season will occur further after the Summer Solstice than when it begins before.   

Triple-Hour Probabilities:

To better qualify these observed trends throughout the Spring/Summer Es season, I charted probabilities into three hour increments.  I first charted probabilities in 1-hour segments and found the information to be overwhelming. This approach shows the seasonal changes in Es opportunities best.
A reminder… The 9^th Week is the Summer Solstice.

6 AM – 9 AM Local Time:

The sun rises at this QTH during this measured period. Although the right-skewed trend was evident in the earliest hour during this period, overall opportunities consistently rose and peaked at the Summer Solstice. During this weekly period one can expect a 50% chance of an Es opening. Between the 5^th and 13^th weeks (5/23-7/24) there is at least a one-in-three chance of an opportunity. Note the sight increase into the 16^th week (8/8).

9 AM – 12 Noon Local Time:

This segment is the best time to work Es, and is best to call it “primetime”. By the 3^rd Week of the season (5/09) the probabilities are greater than 50% for the entire season until the 17^th week.  For 3 weeks, probability is almost 90%.  During the seven years of the study, specifics days and hours within this period have had a capture occur each year of the study.  The obvious trend shown is that once the Es season begins in earnest, it will not end until the end of August.  The 16^th week of the season is just as active as the 5^th.  Any decline in probability as the season progresses is hardly negligible until Week 17.

12 Noon – 3PM Local Time:

The probabilities during this segment also clearly indicate and confirm that Es propagation is a daytime (diurnal) phenomenon.  The probability of working 10-Meter Es is only slightly lower than the previous 3-hour period.  The pattern continues until the Sun approaches due south, the Solar Noon (1:15 PM).  The 6^th Week again is clearly the best and we also begin to notice a slight and steady decline afterwards.  The probabilities of a 10-Meter capture are at their best at the noon hour. Once the sun reaches peak elevation at solstice, a slow and steady decline occurs starting the 8^th week of the season.

3 – 6 PM Local Time:

The sun is now located further west during this period. The right-skewed and right-tailed progression of the season shows up in this segment.  The 6^th week of the season was the best until 2009 and had me believing that Es activity was peaking prior to the summer solstice. Both the 8^th and 11^th week rebounded in opportunities in the later years of the study.  The 11^th week of the season (Independence Day 7/4) it is well known by many Es enthusiasts as an extremely active week. Much of the rise could be due to an increase in the population of participants during the holiday, although many PropNET participants vacationed.

6 – 9 PM Local Time:

During the latter time in this segment the Sun sets. The right skewed and right tailed probability trend is quite evident in this chart.  Seasonal trends are clearer with only the 11^th Week showing a sudden surge in probability.  This time period best displays the rise and fall of the Es season and is also the secondary diurnal peak in activity.  By the 3^rd week, probability of an Es QSO is above 50% during the time segment and remains at least that high until the 16^th week of the season.    

9 PM - Midnight Local Time:

For each hour after sunset, overall probabilities continue to decline. Other than the 11^th week surge (developed during the latter years), the decline is quite pronounced beginning the 8^th week.  The best weeks again are the 6^th, through the 11^th as the probabilities are greater than 50%.

Midnight – 6:00AM Local Time:

Probabilities of an Es QSO become much less into the twilight hours. The trends displayed are consistent; probability peaks near the Summer Solstice. Generally when opportunities occur at these hours, Es have been very intense.  Some of the best daily openings with numerous high MUF QSOs have occurred when good conditions exist at these hours.

Over the years of the study, each peak became more pronounced. The peak during the 15^th week brings up some interesting questions to why these weekly peaks occur at these early morning hours.

Hour to Hour Probabilities by Week:

The final analysis performed using probabilities was to compare the hour-to-hour trends of each week in the Spring/Summer Es season.  With the volume and sampling, we should be able to identify where changes may occur from week to week of the season. Also, if the data accumulated was reliable, did it provide consistent and reasonable results?

Three Week Periods:

The following charts are probabilities of working Es in 3-week segments from the beginning to the end of the season.  The chart clearly details that the 6 weeks prior to and then after the Summer Solstice (12 weeks total) are the best periods for Es.  The one fact that is evident is that during this 12 week period there is not much difference between them except for a slight afternoon decline in late July. 

Weeks 1 – 4:

Week 1 (4/25-5/1) starts the Es season with some limited activity in the daytime hours. In Week 2 the best opportunities are in the afternoon. Probabilities average less than 13% for Week 1 that on any hour a 10-Meter Es PropNET capture can occur.  Probabilities almost double Week 2 and will favors afternoon times.

Probabilities increase near 60% the 3^rd week and peak the 4^th week at a total of 44%. Activity for the 3rd week of the season only favors morning Es activity and typically shows a dual-diurnal pattern to be seen for other active weeks.  Most of these weekly periods showed higher probabilities in the latter years of the study.

Weeks 5 – 8:

These are the weeks approaching the Summer Solstice and historically some of the best. Probabilities between Week 4 and 8 will increase by 33% to over 58% (14 hours/day) overall.  Week 6 during local 10 AM through the 12 Noon hours have probabilities of a 10-Meter PropNET capture at or above 90% (6 out of 7 days).

Despite the high activity of the 6^th week of the season, the 7^th week (6/06) drops off during the morning hours.  Week 8 rebounds and returns to levels above Week 6 and is the most active during twilight hours and indicates that the Summer Solstice is the peak of the season.  

Weeks 9 – 12:

Week 9 (6/20) is the week than contains the Summer Solstice and is the most active of all the weeks of the season.  There is a noticeable decrease in Week 10 closely similar to the level of Week 7, then followed by a strong resurgence in Week 11.  This is the week that contains the Independence Day (July 4th) holiday and traditionally is known to be a very active week for Es propagation.  Week 12 is unusual in that it declines in afternoon and evening activity.  Most week to week declines have occurred during the morning hours.

Weeks 13 – 18:

The usual “morning decline” pattern occurs again in Week 13.  Although displaying a different hourly pattern, overall probability in Week 14 charges little. Week 15 and Week 16 also have steady afternoon declines in activity.  The declines are slight week to week and are only down by 17%.  It was a poor assumption on my part that the Es season ends by August 15.  Usually the first activity-free day does occur near or around the date, but Es activity continues until the first of September.  By continuing the data collection for two additional weeks, it is noted that activity returns to levels experienced at the beginning of the season and once again becomes truly sporadic in nature. The openings during this period are still good and might have some F2 influence.

Next: Conclusions and Credits

A 7-Year 10-Meter Es Propagation Study Using PropNET - Part 5 of 5

Conclusions About 10-Meter Es Propagation:

In my 38 years of monitoring and working these phenomena, I have heard many theories as to their generation and occurrence. Some of these theories that have been proclaimed, I personally do not consider them to have any major effect of the trends shown in these charts.  I strongly believe that too many have tried to figure out the wonders of Es and ignore the consistencies that it is displaying.  Placing its generation of single natural and physical situations and phenomena is difficult to prove.  I hoped that this 7-Year Propagation study would dispel many single-cause theories and provide mathematical, scientific, and logical answers based on consistent patterns and trends.  

If Es were caused by a specific ionosphere or atmospheric events, consistency and patterns in the charts from the study would not occur. Much is still left to science to find the real cause.  A mathematical approach using practical data gathering practices can show the reliability and consistency of the phenomena and dispel these types of theories.

In addition, this study was not compiled in order to predict when your specific 2, 6 or 10 Meter QTH could connect to another specific QTH. It was strictly compiled to identify the best dates, times and possible directions to work them.

The Final Level of Analysis:

Now that 7 years of data was collected and PropNET participation each year was consistent and the data displayed definitive trends, there were still existed some holes day to day. Although I averaged days in my plots, most daily charts displayed peaks and valleys. It stirred up my curiosity and I decided to investigate it on a micro level. I found historically active and inactive days.

Seven years of participation has produced excellent probability data supported by capture numbers. It was proven that the higher the probability of Es, the number of captures during the occurrence is also higher. In order to define the best days of the season, I established the four levels to rank.

These were:

1. Probability (active hours of the day)
2. Intensity (high activity rates during an opening)
3. Activity (day’s total activity)
4. Overall ranking (compared to other days of the season)

Also, these factors are weight to the overall merit of the day.  Individual days and specific conditions within them are noted for the best 60 and 20 days of the season. If day is in bold blue, it is one of the best 60 days. If red, then it is one of the best 20.

This is applied to a calendar from April 25 until August 14.  The best days are focused on the Summer solstice, but it is interesting to see peak and valleys at unexpected days.

1st Quartile Spring/Summer Es Season (April 25 - May 22):

The following table displays the first 4 weeks of the Spring/Summer Es season. The incline of activity is gradual.  The first intense day is May 11. This period alerted me that there was an outside influence to Es propagation. May 22 is the only Top 20 day during the period.

April 25	April 26	April 27	April 28	April 29	April 30	May 1
May 2	May 3	May 4	May 5	May 6	May 7	May 8
May 9	May 10	May 11 TOP 60 INTENSITY ACTIVITY PROBABILITY	May 12	May 13	May 14	May 15
May 16	May 17	May 18 TOP 60 INTENSITY ACTIVITY PROBABILITY	May 19	May 20	May 21	May 22 TOP 20 INTENSITY ACTIVITY PROBABILITY

2^nd Quartile Spring/Summer Es Season (May 23- June 19):

This table confirms that Es are seasonable and its best conditions occur around the Summer Solstice. Of the best 20 days, 9 of them occur during this period. Only May 25 and June 7 fail to have any Top 20 or Top 60 results.

Only 2 days fail to make the rankings. The period from June 2 through June 19 is the best time of the season and one should focus of all their DXing activities around this time. 

May 23 TOP 60 INTENSITY ACTIVITY PROBABILITY	May 24 TOP 60 INTENSITY ACTIVITY PROBABILITY	May 25	May 26 TOP 60 INTENSITY ACTIVITY PROBABILITY	May 27 TOP 60 INTENSITY ACTIVITY PROBABILITY	May 28 TOP 20 INTENSITY ACTIVITY TOP 60 PROBABILITY	May 29 TOP 60 INTENSITY
May 30 TOP 60 ACTIVITY PROBABILITY	May 31 TOP 60 INTENSITY ACTIVITY PROBABILITY	June 1 TOP 60 INTENSITY ACTIVITY PROBABILITY	June 2 TOP 20 INTENSITY ACTIVITY PROBABILITY	June 3 TOP 20 INTENSITY ACTIVITY PROBABILITY	June 4 TOP 20 INTENSITY ACTIVITY TOP 60 PROBABILITY	June 5 TOP 20 INTENSITY ACTIVITY TOP 60 PROBABILITY
June 6 TOP 60 INTENSITY ACTIVITY PROBABILITY	June 7	June 8 TOP 60 PROBABILITY	June 9 TOP 60 INTENSITY ACTIVITY PROBABILITY	June 10 TOP 60 INTENSITY ACTIVITY PROBABILITY	June 11 TOP 60 ACTIVITY TOP 20 PROBABILITY	June 12 TOP 20 INTENSITY ACTIVITY PROBABILITY
June 13 TOP 60 INTENSITY TOP20 ACTIVITY PROBABILITY	June 14 TOP 60 INTENSITY ACTIVITY PROBABILITY	June 15 TOP 60 INTENSITY ACTIVITY PROBABILITY	June 16 TOP 20 INTENSITY ACTIVITY PROBABILITY	June 17 TOP 60 INTENSITY ACTIVITY TOP 20 PROBABILITY	June 18 TOP 20 ACTIVITY PROBABILITY TOP 60 INTENSITY	June 19 TOP 20 INTENSITY ACTIVITY TOP 60 PROBABILITY

3^rd Quartile Spring/Summer Es Season (June 20 – July 20):

As in the prior quartile, 8 of the 20 top activity days occur also in this period. Every day is ranked. The first and fourth best activity days of each Spring/Summer Es season are July 8 and June 30.

June 20 TOP 60 PROBABILITY	June 21 TOP 60 INTENSITY ACTIVITY TOP 20 PROBABILITY	June 22 TOP 60 INTENSITY ACTIVITY TOP 20 PROBABILITY	June 23 TOP 20 INTENSITY ACTIVITY PROBABILITY	June 24 TOP 60 INTENSITY ACTIVITY TOP 20 PROBABILITY	June 25 TOP 20 ACTIVITY PROBABILITY TOP 60 INTENSITY	June 26 TOP 20 ACTIVITY PROBABILITY TOP 60 INTENSITY
June 27 TOP 60 INTENSITY ACTIVITY PROBABILITY	June 28 TOP 20 INTENSITY ACTIVITY TOP 60 PROBABILITY	June 29 TOP 60 ACTIVITY PROBABILITY TOP 20 INTENSITY	June 30 TOP 20 INTENSITY ACTIVITY PROBABILITY	July 1 TOP 20 INTENSITY ACTIVITY TOP 60 PROBABILITY	July 2 TOP 60 INTENSITY ACTIVITY PROBABILITY	July 3 TOP 60 ACTIVITY PROBABILITY TOP 20 INTENSITY
July 4 TOP 60 ACTIVITY TOP 20 PROBABILITY	July 5 TOP 60 ACTIVITY PROBABILITY TOP 20 INTENSITY	July 6 TOP 60 INTENSITY ACTIVITY PROBABILITY	July 7 TOP 20 ACTIVITY PROBABILITY TOP 60 INTENSITY	July 8 TOP 20 INTENSITY ACTIVITY PROBABILITY	July 9 TOP 60 INTENSITY ACTIVITY PROBABILITY	July 10 TOP 60 PROBABILITY
July 11 TOP 60 ACTIVITY PROBABILITY	July 12 TOP 60 INTENSITY ACTIVITY	July 13 TOP 60 ACTIVITY PROBABILITY TOP 20 INTENSITY	July 14 TOP 60 INTENSITY ACTIVITY	July 15 TOP 60 ACTIVITY PROBABILITY	July 16 TOP 60 INTENSITY ACTIVITY PROBABILITY	July 17 TOP 60 INTENSITY ACTIVITY

4th Quartile Spring/Summer Es Season (July 21 – August 15):

During this period, Es begin a general decline. Still, Es activity remains active well into August. Excellent hourly openings occur on July 28 and 29.  July 29 has had a history of being one of the top 10 days of the season.  Daily lulls become more common place, but no clear end of the season appears until after August 15.  The Es season quietly ends 2 weeks after that date.

July 18 TOP 60 ACTIVITY PROBABILITY	July 19 TOP 60 PROBABILITY	July 20 TOP 60 PROBABILITY	July 21	July 22	July 23	July 24 TOP 60 PROBABILITY
July 25 TOP 60 PROBABILITY	July 26 TOP 60 INTENSITY ACTIVITY	July 27 TOP 60 INTENSITY ACTIVITY PROBABILITY	July 28 TOP 60 ACTIVITY TOP 20 INTENSITY	July 29 TOP 20 INTENSITY ACTIVITY TOP 60 PROBABILITY	July 30	July 31
August 1	August 2 TOP 60 INTENSITY	August 3	August 4 TOP 60 INTENSITY ACTIVITY PROBABILITY	August 5	August 6	August 7
August 8	August 9	August 10 TOP 60 INTENSITY	August 11	August 12 TOP 60 INTENSITY	August 13	August 14

Questions and Answers:

“Is Es propagation truly a seasonal occurrence?”

The answer derived from this study is definitely yes. The season begins within days of April 25 and progressively increases up to May 6, at which time it is in full swing and remains totally active until at least August 15.  There is still a good chance that activity continues till the end of August. From the study, the season begins 8 weeks prior to the Summer Solstice and ends around 10 weeks after it.

“Since it has been determined to be seasonal, is activity evenly distributed around the Summer Solstice?”

After three years, I thought it was not. After 5 years of the study the trend-lines show it is. The best part of the Es season is concentrated in the first half (8 weeks long) in a 4-week segment and one should make as much effort as one can during that period.  Es are great from the 3^rd week through the 6^th week (May 9 – June 5). Some years it might calm down slightly for two weeks around the solstice, but it in no way does it mean that the season is over.  It is still very active during that lull.  Once we arrive at Independence Day (July 4th), the season picks up again and it is not until around August 1 that a real decline is noticed.  The season does not actually end until sometimes between August 15 and September 1. Statistically and graphically it has a slight right-skewed distribution of opportunities, still the median points of captures and opportunities rested near the Summer Solstice. 

“It appears that one works most of their QSOs during the afternoon and evening hours. Is this the best time to work Es?”

No it is not. It appears this way only because most Hams are active late in the afternoon and evenings. The absolute best hours are from after sunrise till the actual Solar Noon hour. On weekends and days off from work, make every effort during the season to work Es during these hours.  The late afternoon hours are also very good. The distances covered (DX) are also better, but opportunities decline once the sun has set.  Es are mostly diurnal (daytime phenomena). Es do occur in the late evening and early morning hours. When they do, it is a very special event. Enjoy it and make use of the opening. 

“Do Es favor specific directions at certain times?”

Yes it does, and it has to do with the location of the sun. It appears that you follow the sun in order to apply where it is best. As the sun rises, the best conditions tend to be towards the North and East. Gradually, as the sun is high over the horizon, southern paths improve.  Once the sun has moved beyond Solar Noon, western paths become better than eastern ones.  Therefore, the tendency is that openings appear in the east and north first and then will develop towards the south and the west later on.  The process starts over again in the afternoon as was displayed in the dual peak diurnal. Once the sun is setting, northern and western paths will decline in activity at a slower rate while southerly and easterly ones may drop off quickly.

“Can one predict when it is the best time to work real DX locations on Es?”

Yes…..

1. If the DX location is primarily east of you… Concentrate your efforts towards the DX station as your Sun has risen and then once again as the Sun’s Grey Line approaches the eastern DX locale.

2. If the DX location is west of you …Concentrate your efforts towards the western DX station as their Sun rises and then once again as your Sun sets.

3. For Northern and Southern DX paths ….Concentrate your efforts along the suns Grey Line as it leaves or approaches both locations.

This approach appears to produce better results.

“Do severe weather systems and the Jet Stream have any affects on Es propagation?”

Predominately it is small to absolutely none.  An opening due to thunderstorms is very remote.

A weather system may influence Es propagation between two specific points (experienced here a few times), but I found it difficult to correlate its influence over the entire creation of the phenomena.  This study covered over 800 days of the Spring and Summer season, over a 7-year period. Of the entire seasonal total, I could only determine that an extremely small percentage of PropNET captures had anything to do with weather systems.  In these 7 years, 4 of them were drought years with very little jet stream wind flow and little electrically active weather to speak of.  If weather was the primary influence, the hourly charts would have represented trends indicative to weather affects. They clearly failed to do so. For 5 of the 7 years of the study, the morning daylight period was clearly the best times for Es propagation. Severe weather is a late afternoon, early evening occurrence. Captures in all 7 years never displayed the highest activity in the afternoon and only equaled in two.  In addition, Es would have also occurred at high levels in many other times of the season with varying levels. The study does not show that as is shown by its clear absence of captures in early April and much less than intense when it was open.

“Are there any other possible external influences that might affect Es?”

Probably meteors increase the probability of Es.  

These were the actual daily captures of record for the 7 years of the study.

This is the potential meteor shower rates per hour for each day during the Es season.

Source: DL5BAC’s The Meteor Scatter Predictor Program (TMSP)

It was not perfect for all peaks of meteor activity, but many of the spikes in captures during the 7 years coincide along them. Meteor influence was brought to my attention at the end of the season when there was an increase in Es activity on July 29-30, August 2 and August 13-14 when one would think that activity should have been very limited.

“What might cause the overall lull in activity and probability during the weeks around the Summer Solstice?”  

The high angle of the Sun during this period might have an affect on Mid-Latitude Es.  The Nighttime probabilities actually peak during the solstice, therefore it points towards the peak during this period. Maybe the heat radiated off the earth, in addition to the high sun angle deters ionization of the Es layer to some extent. The final three years were minimum solar activity years. The lull was much less pronounced during this time.     

“Is the term “Sporadic” a proper identification of the Es propagation phenomena?”

The description of the Physics for Es is correct, but as for a phenomenon it is absolutely not.

At the 2011 Central States VHF Society convention, James Kennedy-W6MIO/KH6 described the “E” layer and patches that reflect signals as being sporadic. But during the Spring and Summer those patches are visible as you look around and above the horizon.

The Houghton Mifflin Dictionary defines “Sporadic” as:

1. Occurring at irregular intervals; having no pattern or order in time.
2. Appearing singly or at widely scattered localities, as a plant or disease.
3. Isolated; unique: a sporadic example

The 7 years of the study and the resulting charts show that Es display no such conditions of being Sporadic.

Therefore, we should use the opposite term, “Periodic”.

“Periodic” is defined as:

1. Having or marked by repeated cycles.
2. Happening or appearing at regular intervals.
3. Recurring or reappearing from time to time; intermittent.

Periodic appears to be a much better adjective used to describe Spring/Summer Es propagation.  As for Es being called “sporadic”, I think it still gives them a very bad rap.

Glossary

Afternoon Active - Most occur in the afternoon daylight hours.

Morning Active – Most occur in the morning daylight hours.

Averaging Data – It was used to smooth out peaks and lulls between actual days and better concentrate data gathered for hourly statistics.  Solar Indices are displayed in running averages. It did not change the actual totals if the data displayed was accumulated.

Diurnal -  Webster’s Dictionary defines this term as:

Recurring every day, occurring in the daytime, or opening during the day and closing at night.

Dual Peaked Diurnal – Two peaks of activity occur in the daylight hours.

Es Propagation – The bending of radio waves in the ionosphere at frequencies from approximately 10 – 230 MHz (25-50 MHz most common) by what is known as the E-Layer of the ionosphere (50-80 miles).  Due to its lack of its predictability, it is often referred to as “Sporadic Es”.  It is also known as “Short-Skip” because it propagates at shorter distances than normal F2 layer propagation at high frequencies.

Median – American Heritage Dictionary defines this term as:

Relating to, located in, or extending towards the middle

Probability Analysis – Based on the premise that one event occurs for a given time period. In the study, a single capture in an hour would have the same value at 100.

Right Skewed – Statistics term used to describe charted data.  If most of the data volume is located to the left of center, it is considered right-skewed.

Right Tailed - Statistics term used to describe charted data. If the chartered data declines at a slower rate and time than it first rises, it is considered right tailed.

SE-Prop – DOS and Windows program developed by Jim Roop - K9SE that displays probable E-Cloud location and MUF between two stations.

Summer Solstice – It is the day that the Sun is directly over the Tropic of Cancer (approximately 23.5° North latitude).  It is the highest elevation that the Sun will appear in the Northern Hemisphere. It marks the Winter Solstice in the Southern Hemisphere. When the same condition occurs in the Southern Hemisphere over the Tropic of Capricorn (approximately 23.5° South latitude), it is the Summer Solstice for the southern hemisphere and the Winter Solstice for the northern hemisphere.

Solar Noon Hour – The actual time (hour measured) that the Sun is due south. During Central Daylight Time it occurs at 13:18 or 1:18 PM at grid square EM12ju.

Digisonde – A device that measures the values of returned high frequency radio signals transmitted and received in order to determine ionospheric layer altitudes. The University of Massachusetts Lowell Millstone Hill Digisonde is best known.

W6ELProp – Windows computer program developed by Sheldon C. Shallon, W6EL used for predicting ionospheric (sky-wave) propagation between any two locations on the earth on frequencies between 3 and 30 MHz. Earlier DOS versions were known as MINIPROP and MINIPROP Plus.

A Never-Ending Thank You to the PropNET Organization……..

Rank    Call                 Grid Square      Distance     Captures                        

1           WD4RBX       EM84NN            1338             11724                               

2           WB8ILI           EN82OQ            1669             9234                                 

3           K8VGL           EM69UT            1245             7322                                 

4           K4RKM          EM85VF             1406             6995                                 

5           W4JKL           EM84AK            1238             5026                                 

6           AD4RX           EL88OD             1475             4443                                 

7           KC9MEG       EN52TI               1310             3106                                 

8           KD5LWU       DM57RI              1145             2955                                 
9           K4EPS           EL86UW            1579             2887                                 

10         N7YG             DM42NF            1282             2828                                 

11         K1MEA          DM33TP            1412             1821                                 

12         KI4EIZ            EM63KN            941               1770                                 

13         NZ9Z              EN64BD            1492             1716                                 

14         NM4V             FM06NR            1748             1655                                 

15         N4LR              EM73QN            1172             1626                                 

16         KF9KV           EN52ET             1291             1249                                 

17         N4PSN          EM84KP            1319             1245                                 

18         KC0EFC        EM28OX            715               1004                                 

19         KI0GU            EN35HF             1413             974                                   
20         KF6XA           DM13JO            1859             936                                   
21         W2EV             FN03XD             2026             932                                   

22         WN4AMO      EL98CW            1532             861                                   

23         W6CGH         DM13BR            1920             735                                   

24         N8QLT           EN82HL             1617             707                                   

25         N0OBG          EM48RO            877               705                                   

26         KC6QJO        DM05KH            2035             701

27         W3GYK          EM85VF            1409             620

28         W3NRG         DM12JQ            1867             568

29         WN3C            FM19QC            1975             539

30         AB0TJ            DN60CN            1277             514

31         WB8SKP       EM56WR           933              509

32         KP3FT           FK68QA             3467             502

 73s Art Jackson KA5DWI