G
Guest
Geophysical Condition #1: Earths Rising Base Frequency
Earth’s background base frequency, or “heartbeat,†(called Schumann Resonance, or SR) is rising dramatically. Though it varies among geographical regions, for decades the overall measurement was 7.8 cycles per second. This was once thought to be a constant; global military communications developed on this frequency. Recent reports set the rate at over 11 cycles, and climbing. Science doesn’t know why, or what to make of it.
Gregg Braden found data collected by Norwegian and Russian researchers on this; it’s not widely reported in the U.S. (The only reference to SR to be found in the Seattle Library reference section, is tied to the weather. Science acknowledges SR as a sensitive indicator of temperature variations and worldwide weather conditions. Braden believes the fluctuating SR may be a factor in the severe storms, floods, and weather of recent years.
Geophysical Condition #2: Earths Diminishing Magnetic Field
While earth’s “pulse†rate is rising, her magnetic field strength, on the other hand, is declining. According to Professor Bannerjee of the University of New Mexico, the field has lost up to half its intensity in the last 4,000 years. And because a forerunner of magnetic polar reversals is this field strength, Prof. Bannerjee believes that another reversal is due.
Braden believes that because these cyclical Shifts are associated with reversals, Earth’s geological record indicating magnetic reversals also marks previous Shifts in history…and, within the enormous time scale represented, there were quitefew of them.The Earth behaves like an enormous electric circuit. The atmosphere is actually a weak conductor and if there were no sources of charge, its existing electric charge would diffuse away in about 10 minutes. There is a ‘cavity ‘defined by the surface of the Earth and the inner edge of the ionosphere 55 kilometers up. At any moment, the total charge residing in this cavity is 500,000 Coulombs. There is a vertical current flow between the ground and the ionosphere of 1 - 3 x 10^-12 Amperes per square meter. The resistance of the atmosphere is 200 Ohms. The voltage potential is 200,000 Volts. There are about 1000 lightning storms at any given moment worldwide. Each produces .5 to 1 Ampere and these collectively account for the measured current flow in the Earth’s ‘electromagnetic’ cavity.
The Schumann Resonances are quasi standing wave electromagnetic waves that exist in this cavity. Like waves on a spring, they are not present all the time, but have to be ‘excited’ to be observed. They are not caused by anything internal to the Earth, its crust or its core.
They seem to be related to electrical activity in the atmosphere, particularly during times of intense lightning activity. They occur at several frequencies between 6 and 50 cycles per second; specifically 7.8, 14, 20, 26, 33, 39 and 45 Hertz, with a daily variation of about +/- 0 .5 Hertz. So long as the properties of Earth’s electromagnetic cavity remain about the same, these frequencies remain the same.
Presumably there is some change due to the solar sunspot cycle as the Earth’s ionosphere changes in response to the 11-year cycle of solar activity. Schumann resonances are most easily seen between 2000 and 2200 UT. Given that the earth’s atmosphere carries a charge, a current and a voltage, it is not surprising to find such electromagnetic waves.
The resonant properties of this terrestrial cavity were first predicted by the German physicist W. O. Schumann between 1952 and 1957, and first detected by Schumann and Konig in 1954. The first spectral representation of this phenomenon was prepared by Balser and Wagner in 1960. Much of the research in the last 20 years has been conducted by the Department of the Navy who investigate Extremely Low Frequency communication with submarines. For more information, see: “Handbook of Atmospheric Electrodynamics, vol. Iâ€, by Hans Volland, 1995 published by the CRC Press. Chapter 11 is entirely on Schumann Resonances and is written by Davis Campbell at the Geophysical Institute, University of Alaska, Fairbanks AK 99775. There is also a history of this research and an extensive bibliography.
Time Line & Beyond: Possible Outcomes:
1. Time will appear to speed up as we approach Zero Point. A 24 hour day will seem to be about 16 hours or less. Remember the Schumann Resonance (or “heart beat†of Mother Earth) has been 7.8 cycles for thousands of years, but has been rising since 1980. It is at about 12 cycles at present. It stops at 13 cycles.
2. Zero Point or the Shift of the Ages has been predicted by ancient peoples (Summerians) for thousands of years. There have been many shifts including the one that always occurs every 13,000 years at each half of the 26,000 year, Procession of the Equinox. Planet X is believed to return 3657 years and transverse the Earth’s orbital precession in May 15, 2003
3. Zero Point or a flip of the magnetic poles will probably happen soon, within the next few years. It could possibly synchronize with the Earth’s four cycle biorhythm that occurs every 20 years on the 12th of August. The next occurrence is 12th August 2003. The Philadelphia Experiment and Montauk Project (secret military time travelling) both locked up to the 12th August/20 year biorhythm.
4. It is said that after Zero Point the Sun will rise in the west and set in the east, approx. Past occurrences of this change have been found in ancient records.
Interestingly, the New World Order plans to be in power by 2003. This may or may not happen, depending on many factors and agendas. Stay centered and follow your intuition.
6. The Zero Point flip will probably introduce us to the 4th dimension. Here, everything we think or desire will instantly manifest. This includes love and fear. Our INTENTION will be of utmost importance.most technology that we know will cease to operate. Possible exceptions could be technology based on so called “Zero Point†or free energy.
Our physical body is changing as we approach Zero Point. Our DNA is being “upgraded†to 12 strand. A new light body is being created. We are becoming more intuitive.
The Mayan Calendar predicted all the changes that are occurring now. They say we are going beyond technology and back to the natural cycles of nature and the Universe. By 2012 we will have entered the 5th Dimension (after the flip to the 4th Dimension at Zero Point).
All this information is not fearful. Be prepared for …
changes that will bring in the new age of light. We are going beyond money and time where fear based concepts are totally dissolved.
11. the Gregorian calendar which we use when compared to the Maya calendar shows a discrepancy of six years :
Gregorian Mayan
1994 2003
1995 2004
1996 2005
1997 2006
1998 2007
1999 2008
2000 2009
2001 2010
2002 2011
2003 2012
Gregorian Calendar
Top of Form
Bottom of Form
Date:
Time: : :
Weekday:
The Gregorian calendar was proclaimed by Pope Gregory XIII and took effect in most Catholic states in 1582, in which October 4, 1582 of the Julian calendar was followed by October 15 in the new calendar, correcting for the accumulated discrepancy between the Julian calendar and the equinox as of that date. When comparing historical dates, it's important to note that the Gregorian calendar, used universally today in Western countries and in international commerce, was adopted at different times by different countries. Britain and her colonies (including what is now the United States), did not switch to the Gregorian calendar until 1752, when Wednesday 2nd September in the Julian calendar dawned as Thursday the 14th in the Gregorian.
The Gregorian calendar is a minor correction to the Julian. In the Julian calendar every fourth year is a leap year in which February has 29, not 28 days, but in the Gregorian, years divisible by 100 are not leap years unless they are also divisible by 400. How prescient was Pope Gregory! Whatever the problems of Y2K, they won't include sloppy programming which assumes every year divisible by 4 is a leap year since 2000, unlike the previous and subsequent years divisible by 100, is a leap year. As in the Julian calendar, days are considered to begin at midnight.
The average length of a year in the Gregorian calendar is 365.2425 days compared to the actual solar tropical year (time from equinox to equinox) of 365.24219878 days, so the calendar accumulates one day of error with respect to the solar year about every 3300 years. As a purely solar calendar, no attempt is made to synchronise the start of months to the phases of the Moon. While one can't properly speak of "Gregorian dates" prior to the adoption of the calendar in 1582, the calendar can be extrapolated to prior dates. In doing so, this implementation uses the convention that the year prior to year 1 is year 0. This differs from the Julian calendar in which there is no year 0--the year before year 1 in the Julian calendar is year -1. The date December 30th, 0 in the Gregorian calendar corresponds to January 1st, 1 in the Julian calendar.
A slight modification of the Gregorian calendar would make it even more precise. If you add the additional rule that years evenly divisible by 4000 are not leap years, you obtain an average solar year of 365.24225 days per year which, compared to the actual mean year of 365.24219878, is equivalent to an error of one day over a period of about 19,500 years; this is comparable to errors due to tidal braking of the rotation of the Earth.
Mayan Calendars
Top of Form
Mayan Long Count . . . . Haab: Tzolkin:
The Mayans employed three calendars
all organised as hierarchies of cycles of days of various lengths. The Long Count was the principal calendar for historical purposes, the Haab was used as the civil calendar, while the Tzolkin was the religious calendar. All of the Mayan calendars are based on serial counting of days without means for synchronising the calendar to the Sun or Moon, although the Long Count and Haab calendars contain cycles of 360 and 365 days, respectively, which are roughly comparable to the solar year. Based purely on counting days, the Long Count more closely resembles the Julian Day system and contemporary computer representations of date and time than other calendars devised in antiquity. Also distinctly modern in appearance is that days and cycles count from zero, not one as in most other calendars, which simplifies the computation of dates, and that numbers as opposed to names were used for all of the cycles.
The Long Count calendar is organised into the hierarchy of cycles shown at the left. Each of the cycles is composed of 20 of the next shorter cycle with the exception of the tun, which consists of 18 uinal of 20 days each. This results in a tun of 360 days, which maintains approximate alignment with the solar year over modest intervals--the calendar comes undone from the Sun 5 days every tun.
Cycle Composed of Total Days Years (approx.)
kin 1
uinal 20 kin 20
tun 18 uinal 360 0.986
katun 20 tun 7200 19.7
baktun 20 katun 144,000 394.3
pictun 20 baktun 2,880,000 7,885
calabtun 20 piktun 57,600,000 157,704
kinchiltun 20 calabtun 1,152,000,000 3,154,071
alautun 20 kinchiltun 23,040,000,000 63,081,429
The Mayans believed at at the conclusion of each pictun cycle of about 7,885 years the universe is destroyed and re-created. Those with apocalyptic inclinations will be relieved to observe that the present cycle will not end until Columbus Day, October 12, 4772 in the Gregorian calendar. Speaking of apocalyptic events, it's amusing to observe that the longest of the cycles in the Mayan calendar, alautun, about 63 million years, is comparable to the 65 million years since the impact which brought down the curtain on the dinosaurs--an impact which occurred near the Yucatan peninsula where, almost an alautun later, the Mayan civilisation flourished. If the universe is going to be destroyed and the end of the current pictun, there's no point in writing dates using the longer cycles, so we dispense with them here.
Dates in the Long Count calendar are written, by convention, as:
baktun . katun . tun . uinal . kin
and thus resemble present-day Internet IP addresses!
For civil purposes the Mayans used the Haab calendar in which the year was divided into 18 named periods of 20 days each, followed by five Uayeb days not considered part of any period. Dates in this calendar are written as a day number (0 to 19 for regular periods and 0 to 4 for the days of Uayeb) followed by the name of the period. This calendar has no concept of year numbers; it simply repeats at the end of the complete 365 day cycle. Consequently, it is not possible, given a date in the Haab calendar, to determine the Long Count or year in other calendars. The 365 day cycle provides better alignment with the solar year than the 360 day tun of the Long Count but, lacking a leap year mechanism, the Haab calendar shifted one day with respect to the seasons about every four years.
The Mayan religion employed the Tzolkin calendar, composed of 20 named periods of 13 days. Unlike the Haab calendar, in which the day numbers increment until the end of the period, at which time the next period name is used and the day count reset to 0, the names and numbers in the Tzolkin calendar advance in parallel. On each successive day, the day number is incremented by 1, being reset to 0 upon reaching 13, and the next in the cycle of twenty names is affixed to it. Since 13 does not evenly divide 20, there are thus a total of 260 day number and period names before the calendar repeats. As with the Haab calendar, cycles are not counted and one cannot, therefore, convert a Tzolkin date into a unique date in other calendars. The 260 day cycle formed the basis for Mayan religious events and has no relation to the solar year or lunar month. The Mayans frequently specified dates using both the Haab and Tzolkin calendars; dates of this form repeat only every 52 solar years.
Earth’s background base frequency, or “heartbeat,†(called Schumann Resonance, or SR) is rising dramatically. Though it varies among geographical regions, for decades the overall measurement was 7.8 cycles per second. This was once thought to be a constant; global military communications developed on this frequency. Recent reports set the rate at over 11 cycles, and climbing. Science doesn’t know why, or what to make of it.
Gregg Braden found data collected by Norwegian and Russian researchers on this; it’s not widely reported in the U.S. (The only reference to SR to be found in the Seattle Library reference section, is tied to the weather. Science acknowledges SR as a sensitive indicator of temperature variations and worldwide weather conditions. Braden believes the fluctuating SR may be a factor in the severe storms, floods, and weather of recent years.
Geophysical Condition #2: Earths Diminishing Magnetic Field
While earth’s “pulse†rate is rising, her magnetic field strength, on the other hand, is declining. According to Professor Bannerjee of the University of New Mexico, the field has lost up to half its intensity in the last 4,000 years. And because a forerunner of magnetic polar reversals is this field strength, Prof. Bannerjee believes that another reversal is due.
Braden believes that because these cyclical Shifts are associated with reversals, Earth’s geological record indicating magnetic reversals also marks previous Shifts in history…and, within the enormous time scale represented, there were quitefew of them.The Earth behaves like an enormous electric circuit. The atmosphere is actually a weak conductor and if there were no sources of charge, its existing electric charge would diffuse away in about 10 minutes. There is a ‘cavity ‘defined by the surface of the Earth and the inner edge of the ionosphere 55 kilometers up. At any moment, the total charge residing in this cavity is 500,000 Coulombs. There is a vertical current flow between the ground and the ionosphere of 1 - 3 x 10^-12 Amperes per square meter. The resistance of the atmosphere is 200 Ohms. The voltage potential is 200,000 Volts. There are about 1000 lightning storms at any given moment worldwide. Each produces .5 to 1 Ampere and these collectively account for the measured current flow in the Earth’s ‘electromagnetic’ cavity.
The Schumann Resonances are quasi standing wave electromagnetic waves that exist in this cavity. Like waves on a spring, they are not present all the time, but have to be ‘excited’ to be observed. They are not caused by anything internal to the Earth, its crust or its core.
They seem to be related to electrical activity in the atmosphere, particularly during times of intense lightning activity. They occur at several frequencies between 6 and 50 cycles per second; specifically 7.8, 14, 20, 26, 33, 39 and 45 Hertz, with a daily variation of about +/- 0 .5 Hertz. So long as the properties of Earth’s electromagnetic cavity remain about the same, these frequencies remain the same.
Presumably there is some change due to the solar sunspot cycle as the Earth’s ionosphere changes in response to the 11-year cycle of solar activity. Schumann resonances are most easily seen between 2000 and 2200 UT. Given that the earth’s atmosphere carries a charge, a current and a voltage, it is not surprising to find such electromagnetic waves.
The resonant properties of this terrestrial cavity were first predicted by the German physicist W. O. Schumann between 1952 and 1957, and first detected by Schumann and Konig in 1954. The first spectral representation of this phenomenon was prepared by Balser and Wagner in 1960. Much of the research in the last 20 years has been conducted by the Department of the Navy who investigate Extremely Low Frequency communication with submarines. For more information, see: “Handbook of Atmospheric Electrodynamics, vol. Iâ€, by Hans Volland, 1995 published by the CRC Press. Chapter 11 is entirely on Schumann Resonances and is written by Davis Campbell at the Geophysical Institute, University of Alaska, Fairbanks AK 99775. There is also a history of this research and an extensive bibliography.
Time Line & Beyond: Possible Outcomes:
1. Time will appear to speed up as we approach Zero Point. A 24 hour day will seem to be about 16 hours or less. Remember the Schumann Resonance (or “heart beat†of Mother Earth) has been 7.8 cycles for thousands of years, but has been rising since 1980. It is at about 12 cycles at present. It stops at 13 cycles.
2. Zero Point or the Shift of the Ages has been predicted by ancient peoples (Summerians) for thousands of years. There have been many shifts including the one that always occurs every 13,000 years at each half of the 26,000 year, Procession of the Equinox. Planet X is believed to return 3657 years and transverse the Earth’s orbital precession in May 15, 2003
3. Zero Point or a flip of the magnetic poles will probably happen soon, within the next few years. It could possibly synchronize with the Earth’s four cycle biorhythm that occurs every 20 years on the 12th of August. The next occurrence is 12th August 2003. The Philadelphia Experiment and Montauk Project (secret military time travelling) both locked up to the 12th August/20 year biorhythm.
4. It is said that after Zero Point the Sun will rise in the west and set in the east, approx. Past occurrences of this change have been found in ancient records.
Interestingly, the New World Order plans to be in power by 2003. This may or may not happen, depending on many factors and agendas. Stay centered and follow your intuition.
6. The Zero Point flip will probably introduce us to the 4th dimension. Here, everything we think or desire will instantly manifest. This includes love and fear. Our INTENTION will be of utmost importance.most technology that we know will cease to operate. Possible exceptions could be technology based on so called “Zero Point†or free energy.
Our physical body is changing as we approach Zero Point. Our DNA is being “upgraded†to 12 strand. A new light body is being created. We are becoming more intuitive.
The Mayan Calendar predicted all the changes that are occurring now. They say we are going beyond technology and back to the natural cycles of nature and the Universe. By 2012 we will have entered the 5th Dimension (after the flip to the 4th Dimension at Zero Point).
All this information is not fearful. Be prepared for …
changes that will bring in the new age of light. We are going beyond money and time where fear based concepts are totally dissolved.
11. the Gregorian calendar which we use when compared to the Maya calendar shows a discrepancy of six years :
Gregorian Mayan
1994 2003
1995 2004
1996 2005
1997 2006
1998 2007
1999 2008
2000 2009
2001 2010
2002 2011
2003 2012
Gregorian Calendar
Top of Form
Bottom of Form
Date:
Time: : :
Weekday:
The Gregorian calendar was proclaimed by Pope Gregory XIII and took effect in most Catholic states in 1582, in which October 4, 1582 of the Julian calendar was followed by October 15 in the new calendar, correcting for the accumulated discrepancy between the Julian calendar and the equinox as of that date. When comparing historical dates, it's important to note that the Gregorian calendar, used universally today in Western countries and in international commerce, was adopted at different times by different countries. Britain and her colonies (including what is now the United States), did not switch to the Gregorian calendar until 1752, when Wednesday 2nd September in the Julian calendar dawned as Thursday the 14th in the Gregorian.
The Gregorian calendar is a minor correction to the Julian. In the Julian calendar every fourth year is a leap year in which February has 29, not 28 days, but in the Gregorian, years divisible by 100 are not leap years unless they are also divisible by 400. How prescient was Pope Gregory! Whatever the problems of Y2K, they won't include sloppy programming which assumes every year divisible by 4 is a leap year since 2000, unlike the previous and subsequent years divisible by 100, is a leap year. As in the Julian calendar, days are considered to begin at midnight.
The average length of a year in the Gregorian calendar is 365.2425 days compared to the actual solar tropical year (time from equinox to equinox) of 365.24219878 days, so the calendar accumulates one day of error with respect to the solar year about every 3300 years. As a purely solar calendar, no attempt is made to synchronise the start of months to the phases of the Moon. While one can't properly speak of "Gregorian dates" prior to the adoption of the calendar in 1582, the calendar can be extrapolated to prior dates. In doing so, this implementation uses the convention that the year prior to year 1 is year 0. This differs from the Julian calendar in which there is no year 0--the year before year 1 in the Julian calendar is year -1. The date December 30th, 0 in the Gregorian calendar corresponds to January 1st, 1 in the Julian calendar.
A slight modification of the Gregorian calendar would make it even more precise. If you add the additional rule that years evenly divisible by 4000 are not leap years, you obtain an average solar year of 365.24225 days per year which, compared to the actual mean year of 365.24219878, is equivalent to an error of one day over a period of about 19,500 years; this is comparable to errors due to tidal braking of the rotation of the Earth.
Mayan Calendars
Top of Form
Mayan Long Count . . . . Haab: Tzolkin:
The Mayans employed three calendars
all organised as hierarchies of cycles of days of various lengths. The Long Count was the principal calendar for historical purposes, the Haab was used as the civil calendar, while the Tzolkin was the religious calendar. All of the Mayan calendars are based on serial counting of days without means for synchronising the calendar to the Sun or Moon, although the Long Count and Haab calendars contain cycles of 360 and 365 days, respectively, which are roughly comparable to the solar year. Based purely on counting days, the Long Count more closely resembles the Julian Day system and contemporary computer representations of date and time than other calendars devised in antiquity. Also distinctly modern in appearance is that days and cycles count from zero, not one as in most other calendars, which simplifies the computation of dates, and that numbers as opposed to names were used for all of the cycles.
The Long Count calendar is organised into the hierarchy of cycles shown at the left. Each of the cycles is composed of 20 of the next shorter cycle with the exception of the tun, which consists of 18 uinal of 20 days each. This results in a tun of 360 days, which maintains approximate alignment with the solar year over modest intervals--the calendar comes undone from the Sun 5 days every tun.
Cycle Composed of Total Days Years (approx.)
kin 1
uinal 20 kin 20
tun 18 uinal 360 0.986
katun 20 tun 7200 19.7
baktun 20 katun 144,000 394.3
pictun 20 baktun 2,880,000 7,885
calabtun 20 piktun 57,600,000 157,704
kinchiltun 20 calabtun 1,152,000,000 3,154,071
alautun 20 kinchiltun 23,040,000,000 63,081,429
The Mayans believed at at the conclusion of each pictun cycle of about 7,885 years the universe is destroyed and re-created. Those with apocalyptic inclinations will be relieved to observe that the present cycle will not end until Columbus Day, October 12, 4772 in the Gregorian calendar. Speaking of apocalyptic events, it's amusing to observe that the longest of the cycles in the Mayan calendar, alautun, about 63 million years, is comparable to the 65 million years since the impact which brought down the curtain on the dinosaurs--an impact which occurred near the Yucatan peninsula where, almost an alautun later, the Mayan civilisation flourished. If the universe is going to be destroyed and the end of the current pictun, there's no point in writing dates using the longer cycles, so we dispense with them here.
Dates in the Long Count calendar are written, by convention, as:
baktun . katun . tun . uinal . kin
and thus resemble present-day Internet IP addresses!
For civil purposes the Mayans used the Haab calendar in which the year was divided into 18 named periods of 20 days each, followed by five Uayeb days not considered part of any period. Dates in this calendar are written as a day number (0 to 19 for regular periods and 0 to 4 for the days of Uayeb) followed by the name of the period. This calendar has no concept of year numbers; it simply repeats at the end of the complete 365 day cycle. Consequently, it is not possible, given a date in the Haab calendar, to determine the Long Count or year in other calendars. The 365 day cycle provides better alignment with the solar year than the 360 day tun of the Long Count but, lacking a leap year mechanism, the Haab calendar shifted one day with respect to the seasons about every four years.
The Mayan religion employed the Tzolkin calendar, composed of 20 named periods of 13 days. Unlike the Haab calendar, in which the day numbers increment until the end of the period, at which time the next period name is used and the day count reset to 0, the names and numbers in the Tzolkin calendar advance in parallel. On each successive day, the day number is incremented by 1, being reset to 0 upon reaching 13, and the next in the cycle of twenty names is affixed to it. Since 13 does not evenly divide 20, there are thus a total of 260 day number and period names before the calendar repeats. As with the Haab calendar, cycles are not counted and one cannot, therefore, convert a Tzolkin date into a unique date in other calendars. The 260 day cycle formed the basis for Mayan religious events and has no relation to the solar year or lunar month. The Mayans frequently specified dates using both the Haab and Tzolkin calendars; dates of this form repeat only every 52 solar years.
