Holding Pattern Computer 4+

with wind correction & timing

Aviation Mobile Apps, LLC.

Designed for iPad

    • 4.4 • 21 Ratings
    • £11.99

Screenshots

Description

Fly with Confidence: Holding Pattern App

Elevate your flying skills with Version 3.0 of the Holding Pattern App, meticulously crafted by aerospace experts. Ideal for both new and experienced pilots, this app turns complex flight maneuvers into simple, intuitive instructions.

Navigate the skies with precision using our turn-by-turn guidance for Direct, Teardrop, and Parallel entries and holds, ensuring perfect alignment with your flight path. Our patented technology analyzes wind patterns and flight dynamics to provide real-time, actionable directions that adapt to your needs, from bank limits to wind adjustments.

Version 3.0 introduces the only High-Precision Entry (HPE) system integrated with advanced Holding Pattern Solution (HPS) and EFC algorithms. Tested in real aircraft and simulators, including a 747-400 and a 747-400 Level D simulator, this update minimizes pilot workload and maximizes path accuracy. Experience our innovative Hybrid Parallel/Teardrop entry method to manage airspace efficiently, even in strong winds.

Each feature is designed with safety in mind, from individual data input screens that enhance focus to comprehensive guides and resources for in-depth learning. The new update also includes improved dialog boxes for crucial data input and seamless integration into your flight routine, ensuring you stay within FAA-regulated airspace.

With the Holding Pattern App, excellence in flying isn’t just a goal—it’s your new reality. Ready to transform your flying experience? Download now and visit HoldingPattern.com for more information.

What’s New

Version 3.0.2

This update includes bug fixes and performance enhancements.

Ratings and Reviews

4.4 out of 5
21 Ratings

21 Ratings

WalthamFlyer ,

Brilliant

I use this app whenever I am flying or practicing IFR approaches. Saves all the mental arithmetic.

Pilot Bradders ,

Brilliant app!!

Great app, very nice design and great to use, however I’m confused why I’m not getting the x3 max drift on outbound? Some answers are close but not spot on. For instance one example I tried was: MAX DRIFT = 60/120kts x 15kts wind = 7.5* 7.5 x 3 = 22.5 (23*) Hold inbound CRS 269 Outbound CRS 089

WIND 150/15KTS 89* + 23 = 112* (app computes 105*)

I had a response from Les providing a full explanation and used the app while trying a hold and worked perfectly will fully recommended to anyone! Thanks Les!

Developer Response ,

Sorry for the delay in getting back to you, but the Apple reply was down for about 5 days.
The answer to your questions are given below.

(1) Inbound WCA (IWCA) is given by Sin(IWCA)=(Vwind/VTAS)*Sin(alpha), where alpha is the wind angle relative to the inbound course. Since your inbound course 269 degrees, and the wind is coming from 150 degrees, the value of alpha is 119 degrees on the non-holding side (standard turns). The value of the windspeed ratio is 15/120=0.125. Thus, the value of the IWCA is 6.28 degrees, which is rounded off to 6 deg in the App. Thus, the inbound course would be 263 degrees. Note that in this case the wind is providing a tail wind component. The App shows a negative value, i.e. -6 since the IWCA is pointing toward the non-holding side.

(2) You indicate that you are confused why you are not getting a factor of 3 between the IWCA and the outbound WCA (OWCA). The reason you are not getting 3 is the factor of 3 is a good approximation in two limits. The first being the weak wind case (windspeed ratio less than 0.05), and the second being when the relative wind angle is between 70 and 95 degrees from the inbound course. In this case, the wind is 119 degrees from the inbound course. The value the App computes the OWCA as -16 degrees (again, rounded off to the nearest degree). Therefore, the outbound heading would be 105 degrees.It should be pointed out that the ratio of the OWCA/IWCA on a tailwind component will always be bounded between the value 1 and 3. Wheareas, with a headwind component, the value of the ratio of the OWCA/IWCA is bounded between 3 and (3-wsr)/(1-3*wsr), where wsr=Vwind/VTAS. When the wsr gets close to 1/3, the ratio of the OWCA/IWCA can get large. For example when the wsr=0.3 with a headwind component, the ratio of the OWCA/IWCA is bounded between 3 and 27.
This debunks nearly all the information on timing and wind correction in the holding pattern for the last 50-60 years.

The details are in the technical paper. The user guide also shows a few examples of using the factor of 3 as the initial guess for the first circuit and compares it with the exact solution of the holding pattern.

If you need any additional information, send me an email at lgtech@roadrunner.com

Regards

Les Glatt

tom94777 ,

FAA ONLY!

Does not work for uk holds. Should be a warning here

Developer Response ,

The current version of the Holding Pattern APP for both ICAO and FAA methods of flying the holding pattern is identical when using the Along-Track-Distance (ATD) rather than time. The Holding Pattern APP solves for the exact RNAV Turn Point, which is a function of TAS, turn rate, wind speed, wind direction, and ATD. DME Turn Points are replaced by RNAV Turn Points. This allows all aircraft flying different indicated airspeeds and altitudes in the holding pattern to intercept the holding radial at the same ATD.
The difference between ICAO and FAA holding patterns relate to the time issue. FAA specifies required inbound time, while ICAO specifies required outbound time. The only limit on the FAA method in order to intercept the holding radial at the correct inbound time while using a constant bank angle is the ratio of the windspeed to the TAS (i.e., the windspeed ratio) normal to the holding radial must be less than 1. In the ICAO method of specifying the outbound time, there is a significantly lower limit on the windspeed ratio normal to the holding radial. This limit is a function of the turn rate and the required outbound time. For example, in the case of a standard rate turn and a one-minute outbound leg, the maximum windspeed ratio normal to the holding radial is 1/3. Any value greater than 1/3 will not allow the aircraft to re-intercept the holding radial with a constant bank angle. Most avionics boxes use a variable bank angle to try to intercept the holding radial. This will work when the wind is coming from the non-holding side. In this case, shallowing the bank angle will allow the aircraft to re-intercept the holding radial. However, if the wind is coming from the holding side and the aircraft is bank limited, the aircraft will always overshoot the holding radial. Thus, it is impossible to intercept the holding radial under these conditions. Again, this does not occur in the FAA method since there is always a unique solution to the RNAV Turn Point Problem. We call this solution HPS (Holding Pattern Solution). The first paper on HPS was published in 2018. The Holding Pattern APP uses the HPS analysis.
There are other benefits of using the FAA method for flying the holding pattern, one of which is called High Precision Entry (HPE). In HPS, the aircraft is assumed to enter the hold along the holding radial. In HPE, an additional parameter is incorporated in the analysis, which is the heading of the aircraft tracking inbound to the holding fix. Here the solution of the RNAV Turn Point allows the aircraft to smoothly blend into the HPS ground track, and thus allows the aircraft to re-intercept the holding radial satisfying either the required inbound time or ATD. This capability will be incorporated in the next update of the Holding Pattern APP. The methodology used in the Holding Pattern APP can significantly reduce the holding pattern protected airspace, as well as reducing Pilot workload in the cockpit for both entering and flying the hold.
A dialog has been opened with the FAA to convince ICAO of the benefits of switching over to the HPS/HPE methodology. If ICAO converts to the HPS/HPE method of flying the holding pattern, they can still use their current maximum IAS holding speeds versus altitude tables, since HPS/HPE only requires the TAS, turn rate, windspeed, wind direction, and either inbound time or ATD.

App Privacy

The developer, Aviation Mobile Apps, LLC., indicated that the app’s privacy practices may include handling of data as described below. For more information, see the developer’s privacy policy.

Data Not Collected

The developer does not collect any data from this app.

Privacy practices may vary based on, for example, the features you use or your age. Learn More

Supports

  • Family Sharing

    Up to six family members can use this app with Family Sharing enabled.

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