Tuesday, August 20, 2013

THE OTAPS-PPS POSITION POLARITY SWITCH SIGNAL AND ACTIVE ADVANCED MANAGEMENT POSITION ADJUSTMENT SIGNAL IN ADVANCED RISK MANAGEMENT AND TRADING

On-Off-Through Vector Target Application Price Switch Signal And The OTAPS Position Polarity Switch Signal Vector And The OTAPS Position Polarity Switch Signal Vectors Fan


On-Off-Through Vector Target Application Price Switch has 

1 . The Position Cover Component, and
2.  The Position Polarity Reversal (Switch) Component, and 
3.  The Position Polarity Continuance Component.

Each Component is generated from 

1.  The OTAPS-PPS Switch Signal Vector, and/or 
2.  The OTAPS-PPS Switch Signal Vector Cluster Fan, and/or
3.  From other potential construction sources (listed below).



OTAPS-PPS "The On/Off/Through Vector Target Application Price Switch" - "The Position Polarity Switch" Signal Vector and Signal Vector Cluster Fan

The OTAPS target price position polarity switch, the OTAPS active position management signal, and the OTAPS position polarity switch signal vector and signal vector cluster, and the OTAPS position management methodology, were invented (and discovered) by advanced price theorist and behavioral economist Kevin John Bradford Wilbur.

The OTAPS Position Management System is intended as a contribution to active securities position management practitioners operating in the fields of securities and investment portfolio management and in portfolio risk management.

OTAPS is an 'acronym of abbreviation' that stands for "On-Off-Through-Vector-Target-Application-Price-Switch."  The OTAPS switch is a trade tool and position management and risk-management utility for enhancing focus instrument position value within an active risk management and responsive position management  trading regime.

Other references to the trade switch include, but are not limited to: 

OOTVTAPS:  On-Off-Through Vector Target Application Price Switch, 
OOTV:  On-Off-Through Vector Target Application Price Switch,
OOTVATPS:  On-Off-Through Vector Application Target Price Switch Straddle,
ATPSS:  On-Off-Through Vector Application Target Price Switch Straddle.
OTAPS-PPS: On-Off-Through Vector Target Application Price Switch and Position Polarity Switch Signal

Each reference, however, represent the same mathematical formula and financial construct and entity, and refers to the same applied position management and risk-management methodology and technology in which it is used and is publicly discussed.

The most popular acronym, OTAPS, was coined by the inventor of the OTAPS trend and risk-management tool and directional positioning switch, and has subsequently become the most popular and broadly used reference and name for the trade switch.  

See http://echovectorvest.blogspot.com/2012/05/on-off-through-vector-target.html.

Related references are:

OTAPS-PPSV: On-Off-Through Vector Target Application Price Switch and Position Polarity Switch Signal Vector
OTAPS-PPSEV: On-Off-Through Vector Target Application Price Switch and Position Polarity Switch Signal Extension Vector
OTAPS-PPSV: On-Off-Through Vector Target Application Price Switch and Position Polarity Switch Signal Vector Cluster

Today's relatively highly volatile and fast moving securities market, and its current historically low effective trade execution costs (commissions) is a market environment and current structure particularly favorable to the application of the OTAPS Position Management System. The system utilizes an advanced straddling technique applied at key forecast price levels at critical time junctures with respect to mined and identified historical price pattern symmetries in order to protect gains and to further optimize an actively managed securities' overall price path pattern related and realized returns.

OTAPS signal price levels are generated by the applied forecast model.  An OTAPS switch is then constructed from the OTAPS price level signal upon which the switch then becomes based during its time application.  Base switch levels are set, and often carry with them a series of related upper band and lower band accompanying price switch levels than may also be pre-programmed and additionally employable when met by the market price.  These UB and LB OTAPS switches the accompany the issued primary switch price and target application switch price level remain active also until adjusted.

HOW THE OTAPS SWITCH WORKS

The OTAPS switch is essentially an advanced 'directional and approached-sensitive' and 'flexible' two-sided price straddling mechanism that allows a position 'positivized' in a particular 'price motion direction' to be either 'turned on or tuned off' relative to the 'found price motion direction' occurring in the 'subject security', while also allowing the 'opposite polarity position' to be 'turned on or off' relative to the same price motion occurrence, or any subsequent price motion occurrence, that might move prices to and through the issued target application price switch price level.


For examples of the OTAPS switch in application see articles,

1.  Don't Fight The Fed

"...  In this market environment, we suggest the employment of active and adjustable echovector bridge-based straddling positions to manage stock market exposure to changes in the general price levels. Setting straddles at these bridge levels on their relevant time basis is an effective and opportune measure and advanced trade strategy. Such an approach is particularly well-tailored to and could prove very valuable in engaging and effectively managing these market situations going forward into the presidential elections this fall and thereafter, regardless of what the Fed may or may not say or do in the meantime.
One way to employ such a straddle would be to utilize the SPY ETF and/or the DIA ETF. By setting up an advanced trade technology (see "On-Off-Through Vector Target Price Switch")at, for example, $136 on the SPY or at $128.5 on the DIA, with appropriate dynamic triggers and stops included, such a straddle can be employed.
To perform the short side of the straddle, set a short trigger below either of these mentioned target price switch levels (e.g., $136 on the SPY and/or $128.5 on the DIA) pre-programmed as a "repeating short trigger switch" at the trigger level on reverse downtick action through the trigger price, with stops set to activate on reverse uptick up-through action. To perform the long side of the straddle, set a long trigger above either of these target price switch levels ($136 on the SPY and/or $128.5 on the DIA) pre-programmed as a "repeating long trigger switch" at the trigger level on reverse uptick action through the trigger, with stops set to activate on reverse downtick down-through action.
Now may be a very good time to employ this general market straddle and this more advanced trade technology and active position management methodology, especially when reviewing the chart of the S&P 500 over the past four years within the current presidential cycle."
2.  "Could This Be A Correction That's Coming? An EchoVector Pivot Point Perspective"

"... The stock market has been particularly resilient in its ability to come back from price down-pressure this year. This phase of the 8-year regime change cycle bodes well for the market from levels established in mid-April going into next year. A good chart of the SPX illustrating this phenomena the last 20 years can be viewed at my SeekingAlpha posts by clicking here. For this reason my general bias remains primarily positive. However, "Don't Fight The Fed" remains in force, and if the Fed begins the process of a relative de-leveraging of the markets compared to what it has been doing, it must proceed very smoothly, and very cautiously about what it takes away, and when and how. And I wouldn't want to be on the wrong side of poor market reaction.
For this reason, I think it prudent to continue to use and place dynamic, active, and adjustable straddling positions in order to lock in gains and to better manage your exposure to general market price level changes in either direction. Setting advanced management straddles at key coordinate forecast levels is a very effective and opportune approach, and an advanced trade strategy. In this article I have provided an EchoVector Pivot Points Perspective and method for effectively determining trigger level prices, settings, and adjustments. Using this approach at this time could prove very valuable in effectively managing both market risk and reward.
One way to employ such a straddle would be to utilize the DIA ETF mentioned earlier in this analysis and using the approach illustrated with the /YM Dow 30 Industrials Composite Index E-mini Futures, by setting up an advanced trade technology approach (see "On-Off-Through Vector Target Price Switch") to positioning and position management, with appropriate dynamic triggers and stops included -- for example, at $154 on the DIA.
To perform the short side of the straddle, set a short trigger below $154 on the DIA pre-programmed as a "repeating short trigger switch" at this trigger level on reverse downtick action through the trigger price, with stops set to activate on reverse uptick up-through action. To perform the long side of the straddle, set a long trigger above $154 pre-programmed as a "repeating long trigger switch" on reverse uptick action through the trigger, with stops set to activate on reverse downtick down-through action.
I would continue to closely watch the 4-year presidential cycle echovector, the 2-year congressional cycle echovector, and the annual cycle echovector for continued symmetries and confirming parallels and early divergent tells. And I would keep calculating my echovector pivot points and employing my dynamic OTAPS On-Off-Through Vector Target Price Switch triggers.
This way you won't be fighting the Fed; and will in fact be letting the Fed, and the market, help point you in the direction you 'should be facing.' If a correction is coming, you will be ready. And if it isn't, you will be ready for that as well."


"...  If you believe the time has come to re-enter the treasury long bond, I suggest using active and adjustable straddling positions to manage your exposure to general price level changes in either direction. Setting advanced management straddles at key coordinate forecast levels is an effective and opportune measure, and advanced trade strategy I think prudent to mention. Such an approach to the bond market at this time could prove very valuable at engaging and effectively managing risk and reward. 

One way to employ such a straddle would be to utilize the TLT ETF mentioned in this analysis by setting up an advanced trade technology approach (see "On-Off-Through Vector Target Price Switch") to positioning and position management, with appropriate dynamic triggers and stops included -- for example, at $106.50 on the TLT.
To perform the short side of the straddle, set a short trigger below $106.50 on the TLT pre-programmed as a "repeating short trigger switch" at this trigger level on reverse downtick action through the trigger price, with stops set to activate on reverse uptick up-through action. To perform the long side of the straddle, set a long trigger above 106.50 pre-programmed as a "repeating long trigger switch" on reverse uptick action through the trigger, with stops set to activate on reverse downtick down-through action.
I'm hoping the EchoVector Pivot Point Analysis Perspectives provided in this article help lend additional context to your potentially already broad and extensive bond market view and analysis, and that they help you to further sharpen your clarity and insight. I always recommend considering a broad range of considerations, analysis, and approaches when assessing the markets for any investment decision.


4.  Gold Charts: Warning In February Still Valid Today


"... In the present gold market environment-- and for more advanced and nimble gold market participants, when they do believe the time has come to re-enter gold-- I suggest the employment of active and adjustable straddling positions to manage exposure to general price level changes. Setting advanced management straddles at key coordinate forecast levels is an effective and opportune measure, and advanced trade strategy. Such an approach is particularly well-tailored to -- and could prove very valuable in-- engaging and effectively managing this volatile gold market going forward into fall, and beyond.
One way to employ such a straddle would be to utilize the GTU, GLD, or IAU ETFs. By setting up an advanced trade technology (see "On-Off-Through Vector Target Price Switch")-- for example, at $11.25 on the IAU or at $44.60 on the GTU, with appropriate dynamic triggers and stops included-- such a straddle can be employed.
To perform the short side of the straddle, set a short trigger below either of these mentioned target price switch levels (e.g., $11.25 on the IAU and/or $44.60 on the GTU) pre-programmed as a "repeating short trigger switch" at the trigger level on reverse downtick action through the trigger price, with stops set to activate on reverse uptick up-through action. To perform the long side of the straddle, set a long trigger above either of these the target price switch levels ($11.25 on the IAU and/or $44.60 on the GTU) pre-programmed as a "repeating long trigger switch" at the trigger level on reverse uptick action through the trigger, with stops set to activate on reverse downtick down-through action.
Now may be a very good time to employ this gold market straddle and this more advanced trade technology and active position management methodology, especially when considering the level of volatility we have just witnessed since my February warning in gold earlier this year.
Those readers who have followed this strategy since February have not only saved 20 percent on the downside, but have earned 20% more on the short side (and even more using derivatives), and are ahead of gold market buy-and-hold participants by 40% in just the base underlying GLD ETF gold instrument, all in less than a quarter...."

COPYRIGHT 2013.  PROTECTVEST AND ADVANCEVEST BY ECHOVECTORVEST MDPP PRECISION PIVOTS.  ALL RIGHTS RESERVED.  OTAPS IS A TRADEMARK OF PROTECTVEST AND ADVANCEVEST BY ECHOVECTORVEST MDPP PRECISION PIVOTS.

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THE ACTIVE ADVANCED POSITION MANAGEMENT OTAPS-PPS TARGET APPLICATION PRICE SWITCH SIGNAL AND POSITION POLARITY SWITCH SIGNAL VECTOR AND POSITION POLARITY SWITCH SIGNAL VECTORS CLUSTER FAN

OTAPS-PPS AND/OR OOTVTAPS:  On-Off-Through Vector Target Application Price Switch 

ACRONYM REFERENCES

OTAPS (OOTV, V-TAPS)

PPS:  Potential Position Polarity Cover And/Or Position Polarity Switch Signal Vector And Switch Signal Vector Cluster Trigger Points and And Trigger Points Schedule, And Position Polarity Switch Signal Vector and Extension Vector and Extension Vector Cluster Trigger Points Schedule.

V-TAPS: On-Off-Through Vector Target Application Price Switch Signal, Position Polarity Switch Signal Vector, and Position Polarity Switch Signal Vectors Cluster Fan (and the Position Polarity Switch Signal Vector Cluster Fan Signal Trigger Points)


PROTECTVEST AND ADVANCEVEST BY ECHOVECTORVEST MDPP PRECISION PIVOTS

DERIVING THE OTAPS-PPS

"The OTAPS-PPS Position Polarity Cover And/Or Position Polarity Switch Signal Vector Trigger Point Price"and its support and resistance trigger point constellation is primarily derived from FOUR fundamental source constructions operant within applied EchoVector Analysis and OTAPS technology.  


1. The first construction source is (a) the set of specific key active coordinate forecast echovector (CFEV) support and resistance vectors, and their identified parallel extension vectors, discovered at work within the referenced scope-relative market cycle echovector momentum vector occurring within the focus interest opportunity forecast time and price block or designated frame, or (b) the set of variant and aggregated scope-relative market cycle echovectors of similar time-lengths intersecting and occurring within the focus interest opportunity forecast time and price block or designated frame, or (c) the set of variant and aggregated scope-relative market cycle echovectors of differing time-lengths intersecting and occurring within the focus interest opportunity forecast time and price block or designated frame, or (d) any aggregates and intersects of a, b, and/or c above occurring within the focus interest opportunity forecast time and price block or designated frame, the AAFIOFT* (Applied Action Focus Interest Opportunity Forecast Time-block).   


2. The second construction source is the transposed cluster of NPP* (Nearby identified scope-relative pivot points and/or flex-points of focus interest) Extension Vectors that are identified and originate from the EBD* (EchoBackDate) and/or EBD-TPP* (EchoBackDate TimeAndPricePoint... as more precise time increment measures enable) and which are then symmetrically transposed to 'project from' the NPP's corresponding, originating, and current echovector SP* (the Referenced Echovector's Starting Reference Time/Price Point (typically found at its latest - located most to the right graphically - time/price point) and which then may also continue to further 'project into' or 'traverse' the respective focus interest opportunity otaps-pps forecast application time-frame (fio-otaps-pps-fatf) and applied forecast fiop time/price block (af fiop tpb).


3. The third construction source is the set of additional technical analysis tools and indicators that may be used in complimenting and supplementing primarily EchoVector Analysis methodology generated indicators, signals, and alerts.


4. The fourth construction source is the set of various and regular key outlook events and economics calendar stimulants, along with the potential black swan reactive determinants, that may induce additional, independent, and automatic OTAPS-PPS Switch Signal generation within the practice of effective risk management. 


All OTAPS-PPS VECTORS are vector price support and resistance bridges, which, when touched, constitute, signal, and trigger position capital gain capture, and which, when penetrated, constitute, signal, and trigger position polarity reversal action and adjustment. 


The OTAPS-PPS Open Position Polarity Cover And/Or Open Position Polarity Switch Signal and Trigger Applied Action Forecast Time-Price Block.


"Actively adjusting for optimum speed, acceleration, directionality, and leverage,  the instrument position 'captures and sails' to the varied strengths and varied directions in the powering winds of market change... to keep the course of equity growth strong, positive, straight, true, and moving ever powerfully forward."
For further information on constructing and calculating echovectors, coordinate forecast echovectors, and echovector pivot points, begin by seeing "The Simple Single-Period EchoVector Pivot Point Calculation".

"Positioning for change, staying ahead of the curve, we're keeping watch for you."


Today's relatively highly volatile and fast moving securities market, and its current historically low effective trade execution costs (commissions) is a market environment and current structure particularly favorable to the application of the OTAPS Position Management System. The system utilizes an advanced straddling technique applied at key forecast price levels at critical time junctures with respect to mined and identified historical price pattern symmetries in order to protect gains and to further optimize an actively managed securities' overall price path pattern related and realized returns.

OTAPS signal price levels are generated by the applied forecast model.  An OTAPS switch is then constructed from the OTAPS price level signal upon which the switch then becomes based during its time application.  Base switch levels are set, and often carry with them a series of related upper band and lower band accompanying price switch levels than may also be pre-programmed and additionally employable when met by the market price.  These UB and LB OTAPS switches the accompany the issued primary switch price and target application switch price level remain active also until adjusted.

HOW THE OTAPS SWITCH WORKS

The OTAPS switch is essentially an advanced 'directional and approached-sensitive' and 'flexible' two-sided price straddling mechanism that allows a position 'positivized' in a particular 'price motion direction' to be either 'turned on or tuned off' relative to the 'found price motion direction' occurring in the 'subject security', while also allowing the 'opposite polarity position' to be 'turned on or off' relative to the same price motion occurrence, or any subsequent price motion occurrence, that might move prices to and through the issued target application price switch price level.

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OTAPS SIGNAL CONSTRUCTION CALCULATIONS ARE METHODOLOGICALLY GENERATED FROM 

1. EchoVector Pivot Points, absolute, Coordinate Forecast EchoVector* construction endpoints, single-period based.


2. Aggregated EchoVector Pivot Points, absolute, aggregated Coordinate Forecast Echovector construction endpoints, complex, multi-period in phase convergences of cycles in clusters. 


3. EchoVector Pivot Points, dynamic, Coordinate Forecast EchoVector construction market price intersects at slope momentum projections, specific time-point relative.


4. Coordinate Forecast EchoVectors as SRV-R (Resistance Vector) AND SRV-S (Support Vector) intersects, range-specific, and periodicity specified.


5. SRV (Support and/or Resistance Vector) intersects with key outlook time-points (ie., options expiration day, FOMC announcement day-hour-minute, earnings releases, economic calendar announcements-releases-events, scheduled special events or occurrences or their calendar echoes, overseas and/or international announcements, crisis management announcements, political economics calendar, etc.)


6. Mathematically and statistically related formula and economic-based algorithms.


7.  EchoBackDate (EBD) and/or EchoBackDateTimeAndPricePoint (EBD-TPP) symmetry transpositioned corresponding Extension Vectors and Extension Vector Clusters.


OTAPS-PPS Switch Signal Forecast Model Constructs are used in conjunction with Active Advanced Positioning and Active Advanced Position Management in Risk Management and Value Optimization Paradigms:  Risk-Management  / Value-Protection / Growth Optimization - Growth Acceleration Curve Optimization 


They are Active Advanced Management Constructs inclusive Of Key Forecast Price Pivot Points, Key Forecast Price Flex Points, Key Forecast Price Support Vectors, Key Forecast Price Resistance Vectors. 


OTAPS-PPS DIRECTIONALLY-RESPONSIVE POSITION POLARITY SWITCH COVER/STRADDLE TRIGGER PRICE/TIME POINT: Active Advanced Position Management Technology.



PROTECTVEST AND ADVANCEVEST BY ECHOVECTORVEST MDPP PRECISION PIVOTS

COPYRIGHT 2013.  PROTECTVEST AND ADVANCEVEST BY ECHOVECTORVEST MDPP PRECISION PIVOTS.  ALL RIGHTS RESERVED. OTAPS IS A TRADEMARK OF PROTECTVEST AND ADVANCEVEST BY ECHOVECTORVEST MDPP PRECISION PIVOTS.
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Active Advance Position Management and Value Optimization Methodology And Risk Management Signal, and Active Advance Position Management Trade Technology 

PROTECTVEST AND ADVANCEVEST BY ECHOVECTORVEST MDPP PRECISION PIVOTS presents the


OTAPS-PPS

On-Off-Through Vector Target Application Price Switch And Position Polarity Cover And/Or Position Polarity Switch Signal

A Recursive 3-Legged Conditional Branched-Chain Stop-Specific Trade-Trigger Position Management Order Utility Program, and Methodology, and Platform for Advanced Applications of


FNPI Full Net Portfolio Value Insurance

FNPL Full Net Portfolio Value Long
FNPS Full Net Portfolio Value Short
FNPDL Full Net Portfolio Value Double Long
FNPDS Full Net Portfolio Value Double Short
FNDDL Full Net Portfolio Value Double Double Long
FNPDDS Full Net Portfolio Value Double Double Short

FNPositionI Full Net Position Value Insurance

FNPositionL Full Net Position Value Long
FNPositionS Full Net Position Value Short
FNPositionDL Full Net Position Value Double Long
FNPositionDS Full Net Position Value Double Short
FNPositionDDL Full Net Position Value Double Double Long
FNPositionDDS Full Net Position Value Double Double Short 

FNVI Full Net Vehicle (Financial Instrument) Value Insurance

FNVL Full Net Vehicle (Financial Instrument) Value Long
FNVS Full Net Vehicle (Financial Instrument) Value Short
FNVDL Full Net Vehicle (Financial Instrument) Value Double Long
FNVDS Full Net Vehicle (Financial Instrument) Value Double Short
FNVDDL Full Net Vehicle (Financial Instrument) Value Double Double Long
FNVDDS Full Net Vehicle (Financial Instrument) Value Double Double Short  


OTAPS-PPS "The On/Off/Through Vector Target Application Price Switch" - "The Position Polarity Switch" Signal Vector and Signal Vector Cluster Fan

The OTAPS target price position polarity switch, the OTAPS active position management signal, and the OTAPS position polarity switch signal vector and signal vector cluster fan, and the OTAPS position management methodology, were invented (and discovered) by advanced price theorist and behavioral economist Kevin John Bradford Wilbur.

The OTAPS Position Management System is intended as a contribution to active securities position management practitioners operating in the fields of securities and investment portfolio management and in portfolio risk management.

OTAPS is an 'acronym of abbreviation' that stands for "On-Off-Through-Vector-Target-Application-Price-Switch."  The OTAPS switch is a trade tool and position management and risk-management utility for enhancing focus instrument position value within an active risk management and responsive position management  trading regime.

Other references to the trade switch include, but are not limited to: 

OOTVTAPS:  On-Off-Through Vector Target Application Price Switch, 
OOTV:  On-Off-Through Vector Target Application Price Switch,
OOTVATPS:  On-Off-Through Vector Application Target Price Switch Straddle,
ATPSS:  On-Off-Through Vector Application Target Price Switch Straddle.
OTAPS-PPS: On-Off-Through Vector Target Application Price Switch and Position Polarity Switch Signal

Each reference, however, represent the same mathematical formula and financial construct and entity, and refers to the same applied position management and risk-management methodology and technology in which it is used and is publicly discussed.

The most popular acronym, OTAPS, was coined by the inventor of the OTAPS trend and risk-management tool and directional positioning switch, and has subsequently become the most popular and broadly used reference and name for the trade switch.  

See http://echovectorvest.blogspot.com/2012/05/on-off-through-vector-target.html.

Related references are:

OTAPS-PPSV: On-Off-Through Vector Target Application Price Switch and Position Polarity Switch Signal Vector
OTAPS-PPSEV: On-Off-Through Vector Target Application Price Switch and Position Polarity Switch Signal Extension Vector
OTAPS-PPSV: On-Off-Through Vector Target Application Price Switch and Position Polarity Switch Signal Vector Cluster

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Monday, May 27, 2013

Introduction to EchoVector Pivot Points

Also See "EchoVector Analysis: Topics In EchoVector Analysis"   

COPYRIGHT 2013 ECHOVECTORVEST



EchoVector Theory and EchoVector Analysis are a price pattern impact theory and a technical analysis methodology and approach postulated, created, and invented by Kevin John Bradford Wilbur.


EchoVector Analysis is also presented as a behavioral economic application and securities analysis tool in price pattern theory and in price pattern behavior, study, and forecasting, and in price speculation.

EchoVector Pivot Points are a further technical analysis tool and application within EchoVector Analysis, derived from EchoVector Theory in practice.

EchoVector Theory and EchoVector Analysis assert that a securities prior price patterns may influence its present and future price patterns.  Present and future price patterns may then, in part, be considered as 'echoing' these prior price patterns to some identifiable and measurable degree.

EchoVector Theory and EchoVector Analysis also assert that these influences may be observable, identifiable, and measurable in price pattern behavior and price pattern history, and potentially observable in future price pattern formation, and potentially efficacious in future price pattern forecasting, to some measure or degree.

EchoVector Analysis is also used to forecast and project potential price Pivot Points (referred to as PPP's --potential pivot points, or EVPP's --EchoVector Pivot Points) and future support and resistance echovectors (SREV's) for a security from a starting reference price at a starting reference time, based on the securities prior price pattern within a given and significant and definable cyclical time frame.

EchoVector Pivot Points and EchoVector Support and Resistance Vectors are fundamental components of EchoVector Analysis. EchoVector SREV's are constructed from key components in the EchoVector Pivot Point Calculation. EchoVector SREV's are defined and calculated and also referred to as Coordinate Forecast EchoVectors (CFEV's) to the initial EchoVector (XEV) calculation and construction, where X designates not only the time length of the EchoVector XEV, but also the time length of XEV's CFEVs.  The EchoVector Pivot Points are found as the endpoints of XEV's CFEVs' calculations and the CFEVs' constructions.

The EchoVector Pivot Point Calculation is a fundamentally different and more advanced calculation than the traditional pivot point calculation.

The EchoVector Pivot Point Calculation differs from traditional pivot point calculation by reflecting this given and specified cyclical price pattern length and reference, and its significance and information, in the echovector pivot point's calculation. This cyclical price pattern and reference is included in the calculations and constructions of the echovector and its respective coordinate forecast echovectors, as well as in the calculation of the related echovector pivot points.

While a traditional pivot point calculation may use simple price averages of prior price highs, lows and closes to calculate its set of support and resistance levels, the echovector pivot point calculation begins with any starting time and price point and respective cyclical time frame reference X, and then identifies the corresponding “Echo-Back-Date-Time-And-Price-Point” within this cyclical time frame reference coordinate to the starting reference price and time point A.  It then calculates the echovector (XEV) generated by the starting reference time/price point and the echo-back-time-point, and includes the pre-determined and pre-defined accompanying constellation of “Coordinate Forecast EchoVector” origins derived from the prior price pattern evidenced around the echo-back-time-point within a certain pre-selected and specified range (time and/or price version) that occurred within the particular referenced cyclical time-frame and period X.  Security I's EchoVector Pivot Point constructions then calculate and project the scope relative echovector pivot points that follow A, and the support and resistance levels determined by the ensuing coordinate forecast echovectors and their selected range definition inclusion, relative to the cyclical time-frame X, and to XEV's slope.

EchoVector Pivot Points are therefore advanced and fluid calculations of projected and coordinate support and resistance levels following the starting reference price and time point A (endpoint) of the subject focus echovector, levels which are derived from ascending, descending and/or lateral coordinate support and resistance forecast echovectors calculated from particular range defined starting times and price points, related to the price points and time points of proximate scale and scope and the relative pivoting action that had followed the focus echovector's echo-back-time-point B within, and relative to, the focus echovector's starting time-point and price-point, and the echovector's given and specified cyclically-based focus interest time-span X, and the echovector's slope relative momentum measures.

The Support and Resistance Vectors, referred to as the Coordinate Forecast Echovectors, are used to generate the EchoVector Pivot Points.

The coordinate forecast echovectors originate in a predefined range C of price pivots O's that occurred proximate to the echo-back-time-point B within the given cyclical time frame X of the starting reference price A.  

The coordinate forecast echovectors reflect the price momentum relationship of the starting reference point price and the echo-back-time-point in their calculation and in the calculation of the echovector pivot points.

In these respects, an echovector pivot point may be considered a price level of particular significance in the technical analysis of a security or financial market that may be usable by trader's as a forecasting indicator of a securities (or future market's) time and price vector influenced cyclical price movements.

EchoVector pivot points and their related support and resistance levels also have the calculation advantage of being able to be calculated on the basis of short-term, intermediate-term, or longer-term time frames within varied cyclical price references and 'elected or posited echo-characteristic based' time-spans.

Defining the EchoVector (EV) of Time Length X (for price/time point A
(at market trade print price p and at time point t) of security I
(investment) with Echo-Back-Time-Point A,t-X, p-N.

S Start Point
EVSF of Length (time-frame) X

The EchoVector "X-EV" of Security (Investment) "I" Measured from Market
Trade Time-Point/Print-Price Point, Starting Point, "A"

Definition: The EchoVector

"For any base security I at price/time point A, A having real market transaction and exchange recorded print price p at exchange of record print time t, then EchoVector XEV of security I and of time length (cycle length) X with ending time/price point A would be designated and described as (I, Apt, XEV); EchoVector XEV's end point is (I, Apt) and EchoVector XEV's starting point is (I, Ap-N, t-X), where N is the found exchange recorded print price difference between A and the Echo-Back-Date-Time-And-Price-Point of A, being (A, p-N, t-X) of Echo-Back-Time-Length X (being Echo- Period Cycle Length X).

A, p-n, t-X shall be called B (or B of I), being the EBDTPP (Echo-Back-Date-Time-And-Price-Point)*, or EBD (Echo-Back-Date)*, or EBTP (Echo-Back-Time-Point) of A of I. 


N = the difference of p at A and p at B (B being the 'echo-back-date-time-and-price-point of A found at (A, p-N, t-X.)

And security I (I, Apt, XEV) shall have an echo-back-time-point (EBTP) of At-X (or I-A-EBTP of At-X; or echo-back-date (EBD) I-A-EBD of At-X): t often displayed on a chart measured and referenced in discrete d measurement length units (often OHLC or candlestick widthed and lengthed units[often bars or blocks]), such as 1-minute, 5-minute, 15-minute, 30-minute, hourly, 2-hour, 4-hour, 6-hour, 8-hour, daily, weekly, etc."

Significant "Non-Intraday Single-Exchange" EchoVector Time Period Lengths, or EchoVector Echo-Cycle Period lengths, occur as follows. (X is the time or cycle length of the EchoVector Period, the EP, the "XEV")


Asian Market Echo
European Market Echo
24-Hour Echo
2-Day Echo
3-Day Echo
Weekly Echo
Bi-Weekly Echo
Monthly Echo
Bi-Monthly Echo
Quarterly Echo
Bi-Quarterly Echo
3-Quarter Echo
Annual Echo
15-Month Echo
18-Month Echo
2-Year Congressional Cycle Echo
4-Year Presidential Cycle and mid-Regime Cycle Echo
5-Year FRB Cycle Echo
6-Year (Tri-Congressional Cycle) Echo
8-Year Regime Change Cycle Echo
10-Year Decennial Cycle Echo
16-Year Bi-Regime Change Cycle Echo (Nativity echo)
32-Year Quad-Regime Change Cycle Echo (Maturity Echo)

Shorter, Intra-day market EchoVectors are readily calculable, as well
are longer-term study echovectors.

Calculating the Coordinate Forecast EchoVector and The Coordinated
Potential Pivot Price Point and Coordinated Potential Pivot Time-point

Definition: The Coordinate Forecast EchoVector: (CFEV)

For any EV of X base length (time frame, or time length, or cycle
period), such as lengths intra-day, daily, 3-day, weekly, bi-weekly,
monthly, bi-monthly, quarterly, bi-quarterly, annual, bi-annual,
presidential cycle, or regime change cycle, (and with lengths measured
in incremental -often OHLC- units such as minutes, hours, days, weeks,
or, shorter or longer unit) constructed for security I from starting EV
reference point A with print price point p at time point t (Apt) and
EBTP or EBD A-Length X at print price p (t-X), Coordinate Forecast
EchoVectors (CFEVs) can be constructed having the same slope and lengths (phase adjusted) as XEV of A of I.

Coordinate Forecast EchoVectors and their starting points shall have the
following relationships to A of I and B of I, or EchoVector XEV-BA of I.

Base Construction Versions For the CFEV:
A. Time-Frame Distance Versions
B. Price Distance Versions
C. Model PreSet Value Distance Versions

Versions: 1,2,3,4,5,6

A. CFEV Starting Point Construction: Time-Frame Distance Based Versions

1. Absolute Time Distance Based (Within Select Range) From B, Selected
2. Percent X Time Distance Based (Within Select Range) From B, Selected

B. CFEV Starting Point Construction: Price Distant Based Versions

3. Absolute Price Distance Based (Within Select Focus Interest Range,
Extension) From B, Selected
4. Percent Price Distance Based (Within Select Range Focus Interest)
From B, Selected

C. PreSet Value Distance Based CFEV Starting Point Construction
Definitions*

5. PreSet Absolute Time Distance Based (Range Specified)
6. Preset Percent X Time Distance Based (Range Specified)

*The EchoVectoVEST MDPP Precision Pivots Forecast Model And Alert
Paradigm primarily utilizes specifically defined values of 5. and 6. above
in its CFEV Constellation Illustrations and Highlights for specified
focus interest opportunity securities and their projected forward focus
interest opportunity time-periods and price points. Example CFEV
constructions that follow will utilize these constructions unless noted
otherwise.

The CFEVs found relevant and proximate to BA on the basis of one of the 
above 6 relationships shall be called EchoVector XEV BA's CFEV
Constellation, Base 1, 2, 3, 4, 5, or 6.


ADDITIONAL CONTEXTING NOTES

COORDINATE FORECAST ECHOVECTOR PIVOT POINT NOTATION

The CFEV PPPs correlate to A, B, and O, and are referred to as Ps or PP's --pivot points or potential pivots (or PPPs --projected pivot points or potential pivot points or price pivot points), or flex points.

They are 'forecast-ed' and 'focus interest' coordinate to A, B and O support, resistance, or flex points, derived from the CFEV's found originating within Range C from the 'scope relevant' pivots occurring there.  These 'EchoVector and Coordinate Forecast EchoVectors-based Pivot Points' constitute trade position opportunitities, refererred to as Focus Interest Opportunity Points (or Pivots), FIOPs, or simply as OPs (opportunities or options) or POPs (potential opportunities or options) or PPPOPs (potential pivot point opportunities or options).

Projecting The SRV PPs Of A of I from B to A to EVBA to O to CFEV-OPP, (Given V {Version}, Range C, and EV-TimeLength X, XEV)

EV-TLX (EchoVector Time Length X, XEV)

V = Version N (Selected)
RC = Range C (Selected)

Forward PP (Derived from O occurring in Construction Version N Range C After B)

Back PP (Derived from O occurring in Construction Version N Range C Before B)

Up PP (Derived from O occurring in Construction Version N Range C Above B)

Down PP (Derived from O occurring in Construction Version N Range C Below B)

The FIOP CFEV price origins O will occur above or below the EBTP B.

As any CFEV origin, O, occurring within Range C, occurs above or below EBTP B, so therefore will the correlate PP of CFEV O-PP relating to XEV occur above or below A.

As all FIOP CFEV origin prices occur above and/or below B, all PPPs of CFEV POPP will correspondingly occur above and/or below A.

PPPs will be designated S1 S2 and S3 and R1 R2 and R3, as they occur in extension O, and depending on applied V and Range C and the resulting time distance and/or price distance given by V, and the directional pivots of record and  relative scale reference occuring subsequent to O (up-wave, down-wave, sideways, flex-point)

S = Support
R = Resistance

Definition: The Coordinate Forecast EchoVector: (CFEV)

For any EV of X base length (time frame, or time length, or cycle period), such as lengths intra-day, daily, 3-day, weekly, bi-weekly, monthly, bi-monthly, quarterly, b-quarterly, annual, bi-annual, presidential cycle, or regime change cycle, (and with lengths measured in incremental -often OHLC-  units such as minutes, hours, days, weeks, or, shorter or longer unit) constructed for security I from starting EV reference point A with print price point p at time point t (Apt) and EBTP or EBD A-Length X at print price p (t-X), Coordinate Forecast EchoVectors (CFEVs) can be constructed having the same slope and lengths (phase adjusted) as XEV of A of I.

Coordinate Forecast EchoVectors and their starting points shall have the
following relationships to A of I and B of I, or EchoVector XEV-BA of I.

Base Construction Versions For the CFEV:
A. Time-Frame Distance Versions
B. Price Distance Versions
C. Model Pre-set Value Distance Versions

Versions: 1,2,3,4,5,6

A. CFEV Starting Point Construction: Time-Frame Distance Based Versions
1. Absolute Time Distance Based (Within Select Range) From B, Select
2. Percent X Time Distance Based (Within Select Range) From B, Select

B. CFEV Starting Point Construction: Price Distant Based Versions
3. Absolute Price Distance Based (Within Select Focus Interest Range,
Extension) From B, Select
4. Percent Price Distance Based (Within Select Range Focus Interest)
From B, Select

C. Pre-set Value Distance Based CFEV Starting Point Construction
Definitions*
5. Pre-set Absolute Time Distance Based (Range Specified)
6. Pre-set Percent X Time Distance Based (Range Specified)

*The EchoVectoVEST MDPP Precision Pivots Forecast Model And Alert
Paradigm primarily utilizes specifically refined values of 5. and 6. above
in its CFEV Constellation Illustrations and Highlights for specified
focus interest opportunity securities and their projected forward focus
interest opportunity time-periods and price points. Example CFEV
constructions that follow will utilize these constructions unless noted
otherwise.

Defining, Calculating, Constructing and Generating the Coordinate
Forecast EchoVectors

SUMMARY NOTIONS

EBD is the Echo-BackDate

EBD-T is the Echo-BakeDateTime

EBTP is the Echo-Back-Time-Point with print price found to be p-N.

EBD-TI is the Echo-BackDateTimeIncrement, or EBDT-ITMU incremental time
measurement unit, or imu or mu, or d for designated unit (EBDT-MU, or
EBDT-U, or EBDT-d)

(EX.: minute, 5min, 15min, hourly, 2-hour, 4-hour, daily weekly,
monthly, etc.)

EBTP is also often referred to as the XEV EBPP, or the Echo-Back-Price-Point
of XEV

L is length of the Echo-Period (EP); or X, being the time-length and
cycle length of the EchoVector EV.  XEV or LEV

Primary Model Focus Interest EP or Echo-Period Lengths, or EchoVector
Time Frame or Cycle Time Period Lengths, X

AMEV                                       Asian Market Echo (t, open, lunchtime, close, etc.)
EMEV                                                     European Market Echo
24HEV                                                    1day, 24hour Echo
48HEV                                                    2day Echo
72HEV                                                    3day Echo
WEV                                                        weekly Echo
2WEV                                                      biweekly Echo
MEV                                                         monthly Echo
2MEV                                                       bimonthly Echo
QEV                                                         quarterly Echo
2QEV                                                       biquarterly Echo
3QEV                                                      3quarter Echo
AEV                                                         annual Echo
15MEV OR 5QEV, ETC                       15month Echo
6QEV ETC                                             18month Echo
2AEC OR CCEV 2year                         Congressional Cycle Echo
4AEV OR PCEV 4year                          Presidential Cycle and mid-Regime Cycle Echo
5AEV OR FRBEV 5year                        FRB Cycle Echo
6AEV OR 3CCEV 6year                        (Tri-Congressional Cycle) Echo
RCCEV OR 2PCEV OR 4CCEV ETC  8year Regime Change Cycle Echo

10year Decennial Cycle Echo
16year Bi-Regime Change Cycle Echo (Nascent Echo)
32year Quad-Regime Change Cycle Echo (Maturity Echo)

The Starting Date, time and price point of the EV: The Stp, or Apt, or
A, or SDTPP-A, or EV origin point O.

A is The Sdtp, the summation and reference origin date, time and price
point (Starting time and price point of reference for XEV BA).

The Sdtp is an actual' market price trade point print,' being an exchange
actual buy/sell trade occurrence 'print' posted as taking place at the
specific referenced time and price.

XEV BA is the "Echo" vector from ebtp (EchoBackTimePoint B) to sdtp
(Summation-Date-Time PricePoint).

A is considered as having 'echo characteristic relationship' in some
definable or designate-able form, manner, or degree a 'parameter
relationship contiguity,' to B, the EBTP, on some dimension.

The notion of 'similar' or 'contiguous' on some measure, parameter,
index, dimension, aspect or reference is implied and/or is axiomatic.
Likeness in quality, time, space, context, origin, or relation... to
some degree or measure is axiomatic to the methodology.

FIO EV: focus interest opportunity echovector

The FIOP (focus or forecast interest opportunity point (or period, or pivot).  It is derived from the S-dtp, that is, from A.

From the constellation of 'scope relative' prior and following pivot point highs and lows occurring within Range C (elect Version 1 to 6), the applied CFEV Constellation Range, the CFEV or PPV EBTP origins are derived.

In some citations Delta EV BA is "delta'd" to EchoVector EV AB and is referenced to have A as the echovector time and price point 'antecedent,' (the echo-back-date and/or echo-back-time-point and/or echo-back-date-time-point) and B as XEV's Construction beginning or starting price and time point reference, or starting dtpS, B; that is, as the EchoVector's starting price and starting time point of reference, being the EV's origin.

Also definition-ally derived from XEV AB are the CFEVs, the Coordinate Forecast EchoVectors, also having EchoVector AB length X and  EchoVector AB slope m (for momentum, or slope w for wave), and having Echo-Back-Date-Time-And-Price-Point A as the "CFEV Constellation Base Point," or "Origin," from which the Key Immediate Coordinate Forecast EchoVectors, the Focus Interest Opportunity PPVs (Potential Pivot Vectors), or SRV Constellation (Support/Resistance, or Flex-point Vector Constellation Projections) are, by specified relation (Versions 1 to 6), derived.

In EchoVector AB, A is the Echo-Back-Date-Time-And-Price-Point, and B is the starting reference, and the echovector 'originating' time and price point, or its 'origin.'

From the constellation of 'scope relative' prior and following pivot point highs and lows occurring within Range C (elect Version 1 to 6), the applied CFEV Constellation Range, the CFEV or PPV EBTP origins are derived.  These origins are referred to as O...  OSP1, OSP2, OSP3, ORP1, ORP2, ORP3, etc.

O IS FOR CFEV ORIGIN
S IS FOR SUPPORT
R FOR RESISTANCE
P FOR PIVOT OR FLEX POINT

These CFEV origins O are identified as the scope-relative wave point pivot price point highs and lows occurring before and after THE ECHOBACKDATETIMEANDPRICEPOINT B in XEV BA occurring within Range C (Range C is, again, specified by specific time length distance backward and forward from B by percentage of X from B, or by (within)
absolute time-length distance from B, or by (within) percent of B price distance from B, or by (within) absolute price length distance (N) from B; or by percent N from B, or by stochastically-related 'Modeling process determined' (and then preset in distance --absolute or percent-- from B designated; B being the EBDTPP of A.

These Range C subsumed wave point pivot highs and lows constitute the CFEV Focus Interest Origin Points (FIOPs O), from which the relative CFEV are derived, and from which the Focus Interest Opportunity SRV PP Constellation Set is derived (FIOP PPPs).
These CFEV origin points, O's, relate to the EBTP of A, being B, and to (occuring within) the Base Construction Version and Range C of the CFEV, and the Range and Version's mathematical definition.

From these CFEV origin points (correlated to B by V), and from EV-AB attributes, being of the samelength and slope, the CFEVs are derived, as are the CFEV PPPs, the FIOP PPs.

ADDITIONAL COORDINATE FORECAST ECHOVECTOR GENERATED ECHOVECTOR PIVOT POINT NOTATION

The CFEV PPPs correlate to A, B, and O, and are referred to as Ps or PP's
--pivot points or potential pivots (or PPPs --projected pivot points or
potential pivot points), or flex points.

They are 'forecast-ed' and 'focus interest' coordinate to A, B and O
support, resistance, or flex points, derived from the CFEV's found
originating within Range C from the 'scope relevant' pivots occuring
there.  These EchoVector and their coordinate forecast EchoVector based
Pivot Points constitute trade position opportunities, referred to as
Focus Interest Opportunity Points (or Pivots), FIOPs, or simply as OPs
(opportunities or options) or POPs (potential opportunities or options).

Projecting The SRV PPs Of A of I from A to B to EVAB to O to CFEV-OPP,
(Given V, Range C, and EVTLX, XEV)

EVTL (EchoVector Time Length X)

Forward PP (Derived from O occurring in Range C After B).
Back PP (Derived from O occurring in Range C Before B)
Up PP (Derived from O occurring in Range C Above B)
Down PP (Derived from O occurring in Range C Below B)

The FIOP CFEV price origins O will occur above or below the EBTP B.

As any CFEV origin, O, occurring within Range C, occurs above or below
EBTP B, so therefore will the correlate PP of CFEV OPP occur above or
below A.

As all FIOP CFEV origin prices occur above and/or below B, all PPPs of
CFEV POPP will correspondingly occur above and/or below A.

PPPs will be designated S1 S2 and S3 and R1 R2 and R3, as they occur in
proximity to O, B, and A, depending on applied V and Range C specifications, and the resulting time distance and/or price distance given by V (Version), and the directional pivots of O (up-wave, down-wave, sideways flex-point)

COPYRIGHT 2013 ECHOVECTORVEST

Also See "EchoVector Analysis: Topics In EchoVector Analysis"   COPYRIGHT 2013 ECHOVECTORVEST