ATIS is typically parsed from SNOWTAM, or from METAR SPECI group (MOTNE) string. Did you...
The differences in methodologies used across the world for the reporting of runway conditions have been a longstanding cause of confusion and misinterpretation by flight crews and identified as a leading factor in multiple aircraft and accidents over the years. A majority of runway excursions occur when the runway is contaminated by water, ice, or snow. The underlying reasons for this include variations in information sharing about runway conditions, different communications methods, lack of harmonization in reporting, differences in training, or even a lack of training.
To harmonise the information sharing method and thus mitigate the safety risks related to runways, ICAO adopted a new assessment method and reporting format for runway surface conditions. This “Global Reporting Format” (GRF) must be enforced for worldwide implementation from 4 November 2021. GRF is a globally standardised language reporting format for runways surface conditions where users of the air-traffic network understand what the numbers mean and how they can interpret them. The report is developed based on a Runway Condition Assessment Matrix (RCAM).
One may ask, why should airport operators be concerned with the new reporting format? In practice, the transition to the new GRF methodology may create some tensions or potential misunderstandings between personnel carrying out runway inspections or aerodrome works, and flight crews that need to be considered carefully:
- Runway assessment will also be done in the summertime and in countries not affected by winter operations
- The Runway Condition Report in GRF is different from the previously used runway reporting
- The runway inspector’s responsibility when reporting is significantly increased
Changes in the runway condition report
The Runway Condition Report in the GRF format is characterised by two distinct features:
They are reported by using RCAM surface descriptions: the GRF, the runway inspector must report the runway conditions based on 18 types of contaminants or contaminant pairs, while in the existing method, reporting is done based on seven “basic” types of contaminants. Currently, in terms of aircraft performance data, seven “basic” contaminants are supported by aircraft manufacturers. This creates situations, where pilots are forced to convert RCAM surface description to one of the “basic” contaminant types. This is a potential safety risk and needs to be discussed with the operating airlines.
They are reported per runway third, not per runway: In the worst-case scenario, pilots may encounter SNOWTAM or ATIS containing multiple surface descriptions per the whole runway. This may create a situation, where pilots simply cannot correctly determine one single most significant contaminant to be used in aircraft performance calculation.
Another issue the runway inspector will be faced with is the decision to report is landing critical contaminant or take-off critical contaminant depending on the observation for the runway or runway third. In this context, landing, and take-off critical contaminants refer to the aircraft performance and performance calculation. Landing is based on slipperiness and take-off for contaminant type, depth, and slipperiness.
Potential solution: The RCAM table was originally designed to support runway condition assessment from the landing performance point of view. That is why RWYCC-value plays a major role in the assessment. However, RWYCC-value has no role in take-off performance. To safely cover both take-off and landing, the runway inspector should choose the RCAM contaminant having the greatest impact on take-off performance and RWYCC-value having the correct effect on landing performance. To safely cover take-off and landing, in certain runway conditions where RCAM contaminant type and its respective RWYCC-value cannot be “locked”, it may be necessary to apply a RWYCC downgrade procedure.
The increased responsibility of runway inspectors
The implementation of the GRF heavily depends on trained runway inspectors. The runway inspector’s responsibility in the application of the GRF methodology is significantly increased, in particular when runway condition code zero needs to be reported as this represents conditions in which traffic will be suspended on the respective runway. It is up to the runway inspector to decide whether the runway is available for use or not. The challenge will be to determine if airports can rely only on a subjective assessment of the runway?
Potential solution: By using a friction tester as a supporting tool, the final decision is still up to the inspector, but he can feel more comfortable choosing the runway condition code when he has an objective backup for his/her decision. Friction values are a valuable piece of information especially when assessing runway condition code upgrade or downgrade as well as assessing slippery wet runway condition during summertime. The goal is to build the best possible overall picture of runway condition by using all relevant available information.
The GRF in the summer months and in warmer climates
With the current methodology of runway condition monitoring, when a runway is contaminated by ice or snow, the runway inspectors need to determine the type, depth, and coverage of these contaminants. With the GRF, all airports must promulgate Runway Condition Reports even during the summer. In certain conditions, airports will be required to publish a SNOWTAM even during the summer, as this is the primary format that is currently available for promulgating runway conditions. This issue becomes more important in tropical areas that may not be accustomed to inspecting the runways. In certain regions, the runway conditions can change very quickly due to tropical rainfall. With the use of RCAM, the inspectors in these areas will be able to react quickly to changing conditions.
Potential solution: In countries where the airport is exposed to snow and ice, the runway inspector uses the full version of RCAM to report the runway condition. In countries where the airports are not exposed at all to snow and ice, water is considered as the only contaminant and the inspector only uses the section of RCAM related to water. In both cases, it is essential to have a periodical runway friction testing program, including conducting friction measurements with continuous friction measuring equipment such as Skiddometer BV11. This will allow the airport operator to take necessary preventative measures to remove contaminants in a timely manner. In addition, runway drainage capability should be regularly inspected and monitoring for possible standing water situations be applied.
What to expect from the GRF and how to be prepared
The implementation of the GRF will see a need for precise runway inspections and the development of standard condition reporting by airports globally. There will equally be a need to improve the effectiveness and efficiency of runway surface conditions assessments and reporting. Training, cooperation between airports on sharing lessons learned, and the use of software solutions designed for assisting in runway inspections and reporting will help airports to report runway conditions following ICAO standards.
Global Runway Reporter (GRR) software, Mobile module: Assessment of runway conditions can efficiently be handled by using the Global Runway Reporter Mobile application. GRRM software is the actual runway inspector’s tool to make runway conditions reports. The software calculates automatically RCAM contaminants and helps the inspector to select the correct RCAM code. The runway inspector reports contaminants directly from the inspection vehicle and generates consistent SNOWTAM syntax.
In our previous press releases, we explained different aspects of Global Reporting Format (GRF) regulations and the changes...
We introduce Flowchart B, which should be followed by runway inspectors during summertime. Flowchart B...
The International Civil Aviation Organization (ICAO) flowchart has been published as guidance for the runway...