Barometer and Radio Altitude Settings (EFIS) - How To Use Them

On 10 April 2010, a Tupolev Tu-154 aircraft operating Polish Air Force Flight 101 crashed near the Russian city of Smolensk, killing all 96 people on board.

The pilots were attempting to land at Smolensk North Airport — a former military airbase — in thick fog, with visibility reduced to about 500 metres (1,600 ft). The aircraft descended far below the normal approach path until it struck trees, rolled, inverted and crashed into the ground, coming to rest in a wooded area a short distance from the runway.

The terrain on approach to Smolensk airport is uneven and locally much lower than the runway level and the use of the radio altimeter would be unusual in such a location. Notwithstanding, as the aircraft approached 300 metres (980 ft), the navigator began calling out the radar altimeter's reading.

This is not standard practice for a non-precision approach, as the radio altimeter does not take into account the contour of the terrain around the airport. Standard practice would entail calling out the readings on the pressure altimeter, which is set according to atmospheric pressure and thereby references to the elevation of the actual airport.

Whatever the cause for the accident, the use of the radio altimeter was not considered to be standard practice and its use no doubt contributed to the confusion leading up to the accident.

This snippet has been used in part from a more in-depth article from Wikipedia (copyright @ Wikipedia).

737-800 electronic Flight Information System (EFIS) panel

In this article, I will explain the functionality and operation of the two rotary knobs located on the Electronic Flight Information System (EFIS) panel.

The knob on the left is the minimums selector that enables the minimums to be changed to either barometric altitude (BARO) or radio altitude (RA) . The knob on the right is the barometric reference selector that enables the barometer to be set either in inches (imperial) or hectopascals (metric).

Each knob comprises an outer and inner knob.

The outer knobs are selectors (left or right) and the inner knobs are spring-loaded, and when rotated and released, self-center with the descriptor label resetting to the horizontal position. Each of the two inner knobs can be pressed to either reset the minimums, or to change the barometer setting from QNH to standard (STD) and vice versa.

The inner knobs have two speeds: a slight turn left or right will alter the single digits, while holding the encoder left or right for a longer period of time will change the double digits, and cause the digits to change at a higher rate of speed.

Both selectors display their respective readings on the Primary Flight Display (PFD) on the Captain and First-officer side.

The radio barometric and radio altitude are sometimes referred to as the barometric altimeter and radio altimeter.

Important Definitions

Before going into greater detail, it is important to understand some terminology prior to using the barometric reference selector, in particular the terms: QNH, QFE, STD, transition altitude and transition level.

QNH and QFE

QNH and QFE are not recognised aviation acronyms, although the later is sometimes referred to as ‘field elevation’. The Q-codes were developed by the British Government immediately after the First World War to enable aviators at the time to set their altimeters against a specific reference. This ensured that all aircraft were flying at a specific altitude in relation to each other (when flying at or above a specified height from the ground).

QNH is the altimeter setting that corresponds to mean sea level (MSL) at the location that the pressure has been recorded. Therefore, if you landed on the ocean the altimeter will read zero. If QNH is set to the surrounding air pressure, the aircraft’s altimeter will read zero (or near to) on the runway (unless the runway is located below sea level. For example, Rotterdam Airport (EHRD) and Schiphol Airport Amsterdam (EHAM)).

QFE on the other hand, is the surface pressure at a set reference point (airport that you are landing or departing from). With the barometric setting set to this pressure, the aircraft’s altimeter will read zero, and at other altitudes will read the height above airfield elevation. However, it must be stressed that this barometric setting will only be accurate for that specific location (and time). If the location or pressure changes, then the setting will be incorrect.

For the most part, airline operations always use QNH and some airlines ban the use of QFE.

STD

STD is an acronym for standard pressure (also known as standard altimeter setting (SAS) and is the internationally recognised air pressure that all aircraft must use when reaching a predefined altitude. Using STD sets the aircraft’s altimeter to a pressure based on a set datum, in this case 29.92 in/1013.2 hPa (this being the air pressure at sea level in the International Standard Atmosphere (ISA)). This ensures adequate separation between aircraft as all aircraft have the same pressure set on their altimeters. Failure to reset the barometer to STD at the transition altitude/level will cause the information that is sent to the altimeter to be incorrect.

diagram SHOWING RELATIONSHIP BETWEEN TRANSITION altitude and level (© icon) (click to enlarge)

Transition Altitude

Transition altitude is a ‘fixed’ altitude used when an aircraft is departing an airport and climbing. Transition altitude is the highest altitude that an aircraft can fly with QNH set. Below the transition altitude the altimeter should be set to QNH and this setting should be changed to STD (standard pressure) when the aircraft reaches transition altitude. The STD pressure is 29.92 in/1013.2 hPa.

When an aircraft reaches the transition altitude, the altitude is referred to as a flight level (FL).

At and above the transition altitude, the local pressure has no bearing, and importance is placed upon each aircraft flying with the same barometer reference datum.

The transition altitude will differ from region to region and country to country. In Australia it is 10,000 feet, in parts of Asia 11,000 feet, and in the US 18,000 feet. In some parts of Europe the altitude changes again, and in England the transition altitude is 3,000 feet. Then again, in certain countries in Latin America it depends on terminal airspace.

The transition altitude is pre-selected from the Control Display Unit (Perf Init (1/2)/ Trans Alt).

Transition Level

Transition level is the opposite of transition altitude, and is used for aircraft descending to arrive at an airport. It occurs during the descent and is the lowest altitude that an aircraft can fly having standard pressure (STD) set. When the aircraft reaches or travels below the transition level, the barometer is changed from STD to QNH.

STD press button on the EFIS

The transition level is more often than not assigned to the aircraft by Air Traffic Control (ATC) and as such is a variable altitude level. This is because the pressure on any particular day will be different, and will not be a fixed value. Often ATC will assign a transition layer that is in between two altitudes (usually with a difference of 1000 feet).

If a transition level is not assigned by ATC, the ‘fixed’ transition altitude is used (fixed meaning the altitude that has been established for that particular country. For example, Australia is 10,000 feet).

Mnemonic

To avoid confusion a basic mnemonic can be used:

Transition Altitude (going up) = Ascent (letter A associates with Ascent).

Transition Level (going down) = Lower (letter L associates with lower or descent)

Important Points:

  • At transition altitude (going up) the barometer must be changed from QNH to STD.

  • At transition level (going down) the barometer must be changed from STD to QNH.

Minimums Reference Selector Knob (BARO/MINS/RA)

The selector knob establishes whether barometric pressure or radio altitude is used as a reference point for minimums. The selector knob has three functions:

  1. The outer knob selects either barometric altitude or radio altitude.

  2. The inner knob adjusts the barometric reference height or radio altitude.

  3. By pressing the inner knob marked RST the following occurs:

  • The radio height alert is inhibited (call-out);

  • The radio altitude minimums alert display (displayed in the PFD in white) is blanked out; and,

  • The reference altitude marker on the altimeter (green carrot) is reset to zero.

If the inner knob is rotated left or right and held for longer than a few seconds, the speed that the digits change will increase to a higher speed (slew mode).

RA

Radio altitude is the actual height that the aircraft is flying over the ground (terrain). The height is measured by a transducer located on the underside of the aircraft. This height will alter depending upon whether the aircraft flies over a small hill or shallow valley. The former will decrease the height while the later will increase the height.

When the selector knob is turned to RA and the inner knob rotated, the radio altitude display can be adjusted.

BARO

The barometric altitude measures the atmospheric pressure above sea level and converts this to a height above sea level. This height is then displayed in the PFD and on the altitude tape.

When the selector knob is turned to BARO and the inner knob rotated, the barometric pressure can be adjusted.

MINS

Minimums (MINS) refers to the minimum altitude (and visibility requirements) that must be met for a flight crew to land the aircraft safely. Minimums can vary based on several factors, including the type of approach, the specific airport, weather conditions, and the pilot's qualifications. A go-around is mandatory if the requirements stipulated for the approach type are not met by the time the aircraft reaches minimums.

A future article will discuss minimums and visibility requirements in more detail.

minimums alert display (baro / 6700) and green reference altitude marker (ProSim737)

RST button

The main use of the RST button is comparatively simple: it is to remove (blank out) the minimums alert display and reference altitude marker when minimums are not used; thereby, removing non-essential information displayed on the PFD. By pressing the RST button the Baro and RA displays are blanked out (removed).

Barometric Reference Selector Knob (IN/HPA)

The barometric reference selector knob changes the barometer altitude setting that is used by the avionics as a reference point. It has three functions:

  1. The outer knob selects inches (IN) or hectopascals (HPA).

  2. The inner knob enables the barometric altitude reference on the altitude tape to be changed.

  3. If the inner knob marked STD is pressed, the preselected barometer reference can then be changed. Pressing the knob will display the letters STD on the PFD.

  4. By pressing the inner knob marked STD, the following occurs:

  • The standard barometric setting of 29.92 in/1013.2 hPa is selected;

  • If STD has already been selected (and is displayed) it opens the lower window beneath STD to enable the barometric setting to be changed (STD will be coloured green and the reference characters will be displayed in white); or,

  • If there is no pre-selected barometric reference, the display will show the last value before STD was selected

The inner knob has two speeds: a slight turn left or right will alter the single digits, while holding the encoder left or right for a longer period of time will change the double digits, and cause the digits to change at a higher rate of speed (slew mode).

Important Point:

• Pressing the STD button switches between QNH and standard air pressure.

Colours

The barometer reference display on the PFD is displayed in one of three colours: green, white, and amber.

Green: The display will be coloured green when the aircraft is on the ground, or when STD has been pressed on the barometer reference selector.

White: When the inner knob of the barometer reference selector is pressed (STD), the reference characters (in the lower right window of the PFD) will be displayed in white.

Amber (boxed): Indicates the aircraft is climbing above the transition altitude, or if STD is displayed, the aircraft is descending below the transition altitude. Amber is a caution alert, and if displayed, action should be taken to rectify the situation by pressing the button marked STD on the barometer reference selector.

The altitude at which the amber caution is displayed is determined by the transition height that has been set in the CDU.

Safety Feature

By default the reference will always display (29.92 in/1013.2 hPa). This is a safety feature that has been designed into the system. If a random QNH setting was allowed, for example the last QNH used, there is a possibility that the crew will not notice the incorrect setting. A crew at the beginning of a flight tends to notice the 29.92 in/1013.2 hPa reading as it is what they expect to be displayed.

Which To Use – BARO or RA

It’s not unusual for trainee pilots to become confused concerning whether BARO or RA is used for minimums. I think much of this confusion is generated from web references which try to make the topic more in-depth to what it actually is. Certainly, the different approach types can be confusing, as can the various visibility requirements, but not when to use BARO or RA.

The decision to use barometric or radio altitude as a minimums reference is determined by the type of approach that is being flown, and the information published on the approach chart for the runway in question.

Radio Altitude (RA) is typically used for CAT II/III approaches and those that have a published RA stated on the approach chart (note that most CAT III subsets are flown with autoland).

With regard to CAT III approaches, where a specified failure occurs, the radio altitude is used to indicate the alert height. The alert height is the height above the runway at which an approach must be aborted and a missed approach initiated. The alert height for all Boeing aircraft is 200 feet AGL.

Barometric Altitude is used for CAT I and Non Precision Approaches (NPA). For example, GLS, ILS, IAN, VOR & RNAV approaches.

Simply stated, always use barometric altitude unless the minimums on the approach chart states to use radio altitude (RA).

Important Point:

  • Except for visual landings when minimums are not used, the minimums height, and whether it is BARO or RA, will be annotated on the approach chart for the approach type and airport. In some instances, at specific airports the airline may have a policy dictating whether BARO or RA is used. The pilot does not have a personal preference.

The below video, taken inside the flight deck of a 737-800 aircraft shows the operation of the barometric and radio altitude selector knobs.

 

Operation of Barometric and Radio Altitude selector knobs (OEM 737-800). Courtesy Shrike 200

 

Final Call

The correct use of the minimums and barometric reference selectors is important, in so far as their importance comes into being when landing in inclement weather, as demonstrated in the accident of Polish Air Force Flight 101.

The most important points are to consult the approach chart to determine whether BARO or RA is used, and to change the barometric pressure reading when the aircraft reaches transition altitude, and to remember that if a transition level has not been assigned by ATC, to use the established transition altitude for that particular country.

  • This article has been proof read for accuracy by a third party.

MCP and EFIS By SimWorld - Review

Mode Control Panel (MCP) by SimWorld.  The image looks impressive and the looks do not deceive as this MCP has many advantages over other panels. (promotional photograph © SimWorld

This article will review and evaluate the Mode Control Panel (MCP) and Electronic Flight Instrument System (EFIS) produced by SimWorld in Poland.  It will also briefly examine the use of the CANBUS controller system (SimBox). 

The MCP will be discussed first followed by the EFIS and CANBUS system.  Where some areas overlap they will be discussed together.  I use the word panel to denote either the MCP or EFIS.  Also, OEM is an acronym for Original Equipment Manufacturer (aka real aircraft part).  

This review is not endorsed by SimWorld and is entirely my view based on first-hand experience using the MCP and EFIS.  

Background

The mainstay for several years has been the MCP and EFIS produced by CP Flight in Italy.  For the most part, these panels have delivered consistent and reliable performance, despite their rather dated design and engineering.  

However, there are several distinct differences in aesthetics and functionality between the CP Flight units and OEM counterparts.  Furthermore, many CP Flight panels had connection problems caused by the nature of how the MCP was connected to the server computer (using a virtual communication port).  

Reason for Updating MCP and EFIS

Until updating to the SimWorld MCP and EFIS, I had used the panels manufactured by CP Flight (2015 Pro USB interface model), but technology is not idle.  The use of high-end CNC machines and electronics has enabled many parts to me made, that are in many respects indiscernible from the real item.

Initially, I attempted to find OEM panels.  Although the older non-Collins style MCP could be found, it wasn’t possible to find the newer Collins unit at an affordable price.   

SimWorld provides, at the time of writing, the closest resemblance to the OEM panels.  Furthermore, the use of the CANBUS enables trouble-free connection.

Pre-Sale

The MCP and EFIS are not inexpensive; add to this Government import charges and UPS freight and you have spent a considerable sum of money.   With an increased price comes the expectation of higher quality, reliability, robustness, and attention to detail; let’s examine how SimWorld shapes up to this maxim.

The SimWorld website provides considerable information, including photographs and a video demonstrating the MCP and EFIS.  Although imagery can save a thousand words, questions usually need to be asked.   Filip and Piotr spent considerable time answering my specific queries and e-mails were replied to in a timely manner.   Their customer focus has been top shelf in every respect.

Aesthetics, Manufacture and Detail - MCP

The Mode Control Panel (MCP) and Electronic Flight Instrument System (EFIS) are the main avionics panels used in a simulator, and most enthusiasts strive to replicate the appearance and functionality of these panels as closely as possible to the those in the real aircraft.  

Quick List – Main Advantages (SimWorld MCP):

(i)         1:1 in comparison to the OEM MCP;

(ii)         Correct Boeing-grey colour;

(iii)        Screws located in the correct location on the front panel;

(iv)        Flight Director thumb stops;

(v)         Use of externally protected printed circuit boards (PCBs);

(vi)        Motorised autothrottle arming switch with automatic release to off;

(vii)       Ambient sensor (2017 MCP model, not functional);

(viii)      Does not use seven-segmented displays;

(ix)       Ability to accurately display +- and other specialist fonts;

(x)        Push to engage annunciators are backlit in green (when depressed) and are separate to the colour of the backlighting;

(xi)       Integrated backlighting uses a built-in PCB for reliable dimming control;

(xii)      Correct styled knobs made from painted aluminum;

(xiii)     Correct smoky-coloured display windows positioned in frames identical to the OEM MCP;

(xiv)     Functionality that replicates the OEM MCP (depends on avionics suite used); and,

(xv)      Use of commercial grade rotary encoders.

External casing removed showing multiple Printed Circuit Boards

Internal Components

The components for the MCP and EFIS panels are for the most part machine-made; however, the components are assembled by hand on a market-demand basis.   To ensure production repeatability, SimWorld use a number of printed circuit boards (PCBs) sandwiched together to provide core functionality.

A PCB contains numerous ‘tracks and pads’, that are used for input and output devices, memory chips and processors, and various electrical components such as resistors and capacitors.  An advantage of using PCBs is that troubleshooting can be done via a tethered computer, and if a problem is detected, a board can easily be replaced.  This is because, theoretically, each PCB for each panel is identical in design, layout and population.

System Logic and Functionality

The MCP and EFIS are a hardware-user interface that has been designed from the outset to provide full flexibility in relation to functionality.   However, although the panels may have the appropriate hardware in place, the logic to enable the functionality to operate is supplied by the avionics suite in use (for example, ProSim-AR).  

MCP Light Plate

The light plate has been professionally made and the various pre-cut holes (cut-outs) are well finished.  The laser-engraved lettering on the light plate is precise, evenly cut, and does not differ across the unit.  Additionally, the colour of the paint is the correct Boeing gray and does not differ in hue between the MCP and EFIS light plates.

The manufacture of a light plate is quite involved, and an individual plate or batch will take on average 3 days to complete.   Prior to cutting, several thin layers of paint are applied to the light plate.  A laser is then used to engrave the required letters down to the white-coloured base layer.  The base layer is transparent to light, and when backlit, the lettering can easily be read.

SimWorld use the same technology (or very close to it), that is used to manufacture the OEM light plate.

Exterior Casing

The light plate is attached to a series of printed circuit boards (PCBs).  The PCBs and electronics are protected by a 1 mm thick exterior casing.  The casing is made from aluminum and measures 3 inches in depth perpendicular to the front of the light plate.  The casing is powder coated and coloured black.

On the rear of the panel is a female 12 Volt DC power connector, and a connection for the plug that connects the MCP to the CANBUS system.

Detail of heading knob and bank selector pointer.  Note the detail in the window bezel and the well defined laser engraving on the lightplate

Knobs

The appearance and colour of the knobs is very similar to the OEM knobs.  Each knob, with the exception of the vertical speed wheel, is made from machine-cut aluminum and is the correct colour.  The knobs are well finished with no sharp edges, or left over metal from the milling process.   One or two metal set screws secure each knob to the shaft of the rotary encoder.

The heading knob incorporates a functional bank selector pointer (made from plastic), and the vertical speed wheel is produced from high grade molded plastic.  There are no injection holes in the plastic and the end finish passes scrutiny.

The knobs are tactile (feel solid to touch) and when rotated generate a well-defined audible click (similar to the OEM knobs on the MCP).  

Rotary Encoders

Not all rotary encoders are made equal: a high-end encoder is constructed to an exacting standard predominately using metallic components.  To rotate such an encoder requires a mild effort; there is resistance – it isn’t difficult, but you can’t move it left or right with a flip of a finger.   

In comparison, hobbyist-style encoders are considerably cheaper to purchase, are made to a less exacting standard and usually have a shaft and body produced from plastic.  The encoders are easy to rotate and can also wear out prematurely with extended use.

SimWorld use quality Swiss made rotary encoders, rather than using low quality encoders from China.  Each encoder has a cylindrical metal shaft.  A metal shaft is important as a plastic shaft can wear prematurely, in addition to becoming damaged from overzealous tightening of set screws (which hold the knob in place).

I have been told that military specification (MilSpec) encoders are available, however, SimWorld use these encoders only for high-end commercial simulators.

Resistance When Rotating Knobs - Comparison With OEM Honeywell and Collins MCP

Resistance when rotating the knobs will depend on the MCP model.  The knobs on the older Honeywell models are very easy to rotate - A finger with just a ‘tad’ of pressure will move the knobs, however, the newer Collins model has more resistance, but the knobs are still very easy to rotate with minimal force.   As one First Officer stated: ‘You can definitely hear a soft click as you move the encoders - especially on the Honeywell models’.

By comparison, the resistance felt when rotating the knobs on the SimWorld MCP, although difficult to quantify, is similar to the resistance felt when rotating the knobs on the OEM MCP – It is realistic and does not feel ‘toy like’.  

The stray light is at the interface where the exterior casing joins the lightplate.  This area is covered by the MIP when the panel is mounted

Backlighting

The backlighting is controlled by a number of 5 Volt light emitting diodes (LEDs).  Each LED has been strategically located in the light plate to ensure even coverage and intensity of light.  

However, the MCP does exhibit slight light bleed along the join between the light plate and the protective casing.  This is not a problem as when the MCP is mounted into the MIP, the stray light is not noticeable.  If necessary, cloth tape can be placed over the join to eliminate any stray light.

Backlight Dimming - Dimmer Interface Card (DIC)

The MCP and Captain-side EFIS can be dimmed together, while The First Officer EFIS is capable of being dimmed independent of the Captain side EFIS.  This is how it occurs in the real aircraft.

To enable the panel backlighting to be dimmed, SimWorld have used a dedicated PCB (DIC).  The use of a PCB ensures that dimming is reliable, accurate, and highly controllable.   The PCB is standalone, is roughly the size of two credit cards and can be mounted anywhere.

The DIC is connected to the CANBUS system via the custom wiring harness and then to the appropriate potentiometer that controls panel backlighting.   Panel backlighting can be dimmed from off to any brightness level.  

To enable dimming, a potentiometer must be wired to the PCB (DIC).  

Power

The MCP requires 12 Volt power, while the backlighting uses 5 Volt power that is connected to the DIC.

MCP Annunciators

The annunciators are not glorified micro-switches, but are push on/off buttons that when depressed emit an audible click.  The resistance felt as the button is pressed, is slightly less than the pressure required to engage an OEM annunciator.  The square push button and frame is made from plastic, and the cylindrical shaft that the button connects with is made from metal.  

SimWorld have replicated each of the square-shaped buttons exceptionally well, and for the most part their external appearance is identical to the OEM counterpart.

Each annunciator is connected to the primary MCP PCB, thus eliminating the use of wires.  If an annunciator is broken during the course of its life, replacement is relatively straightforward and involves soldering the connection of the replacement annunciator to the PCB.

Status Checkerboard and Legend

Each annunciator on the MCP comprises a square push button, a rectangular-shaped checkerboard, and a legend.

The checkerboard is made by engraving a number of holes that, when the annunciator is pressed, enables green-coloured light to be transmitted through the checkerboard.  The checkerboard is similar to the OEM panel and has the same number of engraved holes.

Each annunciator has a legend that uses multi layer technology (proprietary to SimWorld).  Multi layer technology is what enables the backlighting of the checkerboard and legend to be a different colour.  The name of each annunciator (speed, VNAV, N1, etc.) has been engraved into the legend.   

The detail of the annunciators is very good and the jagged appearance of the lettering only becomes apparent when they are backlit.  The backlight intensity is set to 100%

Unfortunately, the engraved letters are not as defined as you would expect; the lettering is slightly jagged in appearance (enlarge above image). 

This is noticeable only when observed very close-up; from a normal distance (seated) this is barely noticeable and therefore, not really an issue.   However, the ability of the legend to transmit light evenly through the cut-out lettering is noticeable as the jagged appearance causes the names to appear slightly ‘furry’ (brighter or dimmer) depending upon the amount of light that can travel through the lettering, and your viewing position.

The annunciator legends and the checkerboard, are illuminated by strategically-placed LEDs.  

Window Bezels and Liquid Crystal Displays (LCDs)

The two main differences that separate an OEM MCP from a reproduction MCP are the design and appearance of the bezels that surround the display window, and how the actual characters (digits) are displayed.

SimWorld have used a black-coloured bezel that surrounds each of the display windows.  The bezel is identical to the bezels in the OEM MCP, and the join between the bezel and the display frame is seamless.

Equally, the use of custom-made Liquid Crystal Displays (LCDs), with each display backlit by one LED, is what causes SimWorld’s design to stand-out above its competition.  

The checkerboard is identical in appearance across all annunciators.  Note the ambient sensor and + character in the vertical speed window.  Also the very slight difference in the illumination of the + sign  Backlightng is set ~50% intensity

The combined use of LCDs and LEDs enables each character (digit) to be displayed in the correct shape, colour and size.  This is in addition to displaying the specific characters used in the speed window (under and overspeed conditions) and the +- symbols displayed in the vertical speed window.

Although appearing rudimentary, this is similar to how the OEM displays are illuminated.  To my knowledge, all other manufacturers of reproduction MCPs use seven-segmented displays.

While the use of this type of display is a positive step forward, it is not without its negatives; if the LEDS are incorrectly positioned, or the throw of light is not even across the rear of the LCD, then the characters will not be evenly lit.  This may cause some of the characters in a display to be brighter or dimmer (hot or cold spot).

To counter against this, quality assurance (QA) must be exceptionally thorough.  I will discuss QA later in this article.

Backlighting at full intensity is excellent

LCD Brightness

As discussed earlier, each LCD is backlit by a single LED (this is how the characters (digits) are illuminated).

The brightness of the digits is linked to the intensity of the backlight dimming.  Therefore, as backlighting is dimmed, the brightness of the LEDs behind each LCD is lowered.   Although this is exactly how dimming operates in the real aircraft, I find that during the day in bright conditions, with the backlighting turned off, it’s difficult to read the digits as their intensity is not very bright.  At night and in low light conditions this is not an issue as the digits can easily be read. 

A solution to this issue is for SimWorld to enable an alternate method (although not as done in the real aircraft) to allow the brightness of the LEDs to be independent of backlighting.

Autothorttle (A/T)

The A/T toggle, controlled by a solenoid-release mechanism, resembles the OEM toggle.

The system logic SimWorld use in the toggle is slightly different to other reproduction MCPs, in that the toggle can only be engaged when certain conditions are met (system logic).

If the correct conditions are not met, then the toggle cannot be engaged; the toggle will not stay in the engaged position (up) but flick back to the disengaged position (down).  Be aware that for this functionality to operate, the avionics suite in use must also have this capability.

Captain-side EFIS panel with backlighting at full intensity.  The lightplate is well made and the laser engraving is well defined enabling even illumination of backlighting accross the panel.  The BARO STD knob has purposely been left slightly left of center.  When the BARO knob is released it will spring back to the central position

Electronic Flight Instrument System (EFIS)

Disregarding OEM panels, the SimWorld EFIS is probably the best on the market (at the time of writing).   Each EFIS replicates its OEM counterpart in both appearance and functionality, and is the correct size (1:1).

Two noticeable positives are the concave-designed push in/out function buttons on the lower portion of the unit, and the use of independent duel rotaries that are centrally spring-loaded.  

Quick List – Main Advantages (SimWorld EFIS):

(i)      Correct size and dimensions (1:1);

(ii)     Use of externally protected printed circuit boards (PCB);

(iii)    Correct Boeing-grey colour;

(iv)    Accurate aluminum knobs with set screws;

(v)     Independent backlighting between Captain-side and F/O side EFIS units;

(vi)    Two speed rotary encoders which auto-center (BARO and MINS);

(vii)   Well defined laser-cut lettering on light plate; and,

(viii)  Concave-designed push buttons.

First Officer side EFIS.  Knob length, functionality and detail are as per the real aircraft as is concave function buttons and well defined lettering and even backlighting across the lightplate

Manufacture and Detail - EFIS

The EFIS has been manufactured and assembled in a similar way to the MCP.  The EFIS panels are 1:1, are the correct shaded grey colour, include the appropriate screws located in the correct location, and have the correct styled knobs.  As with the MCP, the EFIS use printed circuit boards which are then protected by an exterior aluminium casing.

EFIS Light Plate, Backlight Dimming and Exterior Casing

The laser-cut lettering on the light plate is crisp and sharp, and when the EFIS is backlit the light is evenly spread at the same intensity across the panel. 

Both EFIS panels are dimmed through the same dimmer interface card (DIC) used for the MCP, however, the F/O EFIS panel can be dimmed separately to the Captain-side panel (as it is done in the real aircraft).  

The protective casing that each EFIS resides measures 5 inches in depth perpendicular to the light plate.   On the rear of the unit is a female 5-volt DC power connector, and a connection for the plug that connects the EFIS to the CANBUS system.

First Officer side EFIS.  The lettering and black disc is well made.  The metal set screw that attaches the upper knob to the dual rotary can be observed.  The upper knob is self centering

Knobs

The manufacture of the knobs is similar to the knobs used on the MCP, with the exception that a centrally-placed disc has been laser engraved to enable the function name to be backlit.  The lettering on the discs is crisp and sharp.  The knobs are held securely to the rotary shaft by two metal set-screws.  

The pointer (black & white line) on the function selector knob is a transfer that has been glued to the outside of the knob.  The adhesive has been solidly applied and I doubt the transfer will come loose.

Rotary Encoders

The rotary encoders are similar to those used in the MCP and have a metal cylindrical shaft.  Each of the encoders is a double encoder meaning that it has dual functionality.

Specialist Functionality - BARO and MINS Buttons

The barometric pressure (BARO) and radio altitude/pressure (minimums) function exactly as those in the real aircraft.  The outer knobs are left and right select and the inner knobs are spring-loaded rotary encoders. When the inner knobs are rotated and released they self-center with the label resetting to the horizontal position.  The inner knobs also have a momentary push function (push to reset and push to change barometer to STD).

Each knob has two speeds: a slight turn left or right turn will alter the single digits, while holding the encoder left or right for a longer period of time will change the double digits, and cause the digits to change at a higher rate of speed.   

The below video, taken inside the flight deck of a B73-800 aircraft shows the operation of the OEM BARO and MINS (courtesy Shrike 200).  The SimWorld BARO and MINS knobs operate the same way.

 
 

Concave-shaped Function Buttons

The function buttons on the EFIS are concave in shape and made from plastic (this differs to the rubberized buttons seen on several OEM EFIS panels).  Each button has the name of the function engraved into the button.  The engraved letters are crisp and sharp and when the panel is backlit, the letters are evenly illuminated without hot or cold spots.  

Each button’s mechanism is made from plastic, and while the use of plastic is understandable, metal probably would increase the mechanism’s service life.  

Minor Problem - Sticky EFIS Button

A minor issue developed after installation of the EFIS into the bracket.  Two function buttons when pressed, would not automatically reset themselves (click in and click out).  The problem only presented when the panel was mounted into the bracket faceplate.

After carefully examining the bracket and protective casing, it was found that when the EFIS was mounted into the MIP, the casing was compressed against the button.  This caused the button to remain pushed in.

The problem was resolved by slightly bending the aluminum external casing so that it did not rub against the button’s mechanism. 

Functionality

The functionality of the EFIS is identical to the OEM EFIS.

SimWorld propriety bracket to mount MCP and EFIS into the SimWorld MIP.  The bracket is solid and very well made

MCP and EFIS Bracket

SimWorld provide a sturdy bracket that is used to mount the MCP and EFIS panels to the Main Instrument Panel (MIP).

The bracket consists of a front faceplate and a rigid bracket framework.  Both items are made from 1 mm thick, black-coloured, powder coated aluminum.  The faceplate is precut to allow fitment of the MCP and EFIS.  The framework provides stability to stop the EFIS panels from wobbling in the precut hole.  

Mounting The Bracket To The MIP

The bracket is designed to be used with SimWorld’s propriety MIP, however, the bracket can be used with other MIPs.  Take note that, depending upon which MIP is used, the bracket/MIP may need to be modified.

I retrofitted the bracket to a Flight Deck Solutions (FDS) MIP which was not without its problems. 

Problems Retrofitting The Bracket to the FDS MIP

The FDS MIP, the distance between the Captain-side and F/O-side glarewings did not allow enough room to enable the bracket faceplate to be fitted; the bracket was approximately 1 mm too long, and the bracket framework was too deep to easily slide into the recess of the FDS MIP.

These shortcomings were rectified by shaving away a small portion of the inner side of each glarewing.  This enabled the bracket faceplate to fit snugly between the glarewings.  

To use the bracket framework (which is quite deep), the internal structure of the FDS MIP has to be cutaway, an act that may affect the structure of the MIP.  Therefore, the framework was discarded and only the bracket faceplate was used.  

Without the framework to provide stability, the EFIS panels wobbled somewhat in the bracket faceplate.  To stop the EFIS from wobbling, small wedges made from wood were fabricated and installed between the EFIS and the inside edge of each glarewing.  Once the wedges were installed, the EFIS did not wobble.  The MCP is secured to the bracket faceplate by four screws which inhibits any movement.

A facsimile of the piece of metal that covers the underneath portion of the MCP was made from thin metal, painted black, and the appropriate screws added.

T-taps can damage wires causing connection issues, so should be viewed as a temporary set-up

Wiring Harness

SimWorld supply a high quality wiring lumen that consists of four colour-coded wires with connectors.  The wires connect to the MCP and EFIS, and then to a 5 and 12 Volt power supply, dimming interface card (DIC), and the CANBUS system.  The power connections are standard push pull plugs and the wires that connect the MCP and EFIS with CANBUS use wire tap connectors (T-taps).   The length of supplied wire approximately 12 feet and SimWorld provide a basic wiring diagram.

Wire Connectors

The use of wire tap connectors (wire chomper), although very convenient, should probably be looked at only as an initial connection when testing the panels.  For a more permanent connection, soldering the wires is preferable.  Soldering will remove the possibility of any troublesome connection.  

Let me explain,  the act of pressing the wire into this slotted metal piece bludgeons the wire. The concept behind this is fine – it’s supposed to strip back the insulation on the wire to make contact with the wire itself. The problem is that there is no guarantee that you won’t accidentally catch some of the wire in this process and tear some of the individual wire strands.  Additionally, if the insulation is broken over a wire, there is a possibility of corrosion (oxidation) occurring.  

Power plug and CANBUS connector.  Each panel is connected to CANBUS by one of these connectors, and then to the dimming interface card

Push-Pull Power Plugs

Although the use of a push/pull power plug is standard to many appliances, the connection is not tight.  If pressure is applied to the power cable, it is easy for the plug to become dislodged and loose connection with the MCP or EFIS.  

On a simulator with motion control, vibration could cause the plug to be dislodged.  An easy matter to rectify, the security of this connection should be improved in future designs.

CANBUS Controller System

The CANBUS system (also called Simbox or CAN controller) enables communication between the server computer and the MCP (and specific SimWorld panels) and is a vital part of the SimWorld architecture.

CAN is an acronym for Controller Area Network and is a bus standard designed to allow micro controllers and devices to communicate with each other.  Simply put, CANBUS translates the CANBUS signal, allowing for control and communication through the computer.

The CAN controller system (printed circuit board) resides in a ribbed-aluminum case with two connectors at each end of the case; one side connects with the computer via a standard USB cable while the other side connects, via a specialist connection, to the wiring harness, and then to the MCP and EFIS panels.  The CAN controller does not require a dedicated power supply.

CANBUS module.  Made from aluminium and housing a Printed Circuit Board (PCB), the CAN controller is what connects the MCP and EFIS tot he server computer.  During all trials, CANBUS performed flawlessly with no drop outs, lags or failures

CANBUS is small and light enough that it can be mounted anywhere between the MIP and server computer.  I have the CANBUS unit secured to the rear of the MIP via a Velcro strap.

Connection and Drivers

CANBUS does not require any drivers to operate as it’s detected by ProSim-AR when the software is turned on.  Connection is immediate, and whatever configuration is needed is done automatically through Windows the first time CANBUS in connected to the computer.  

There should not be any connection or communication issues provided you have checked (ticked) the enable SimWorld drivers within the configuration/drivers tab of the ProSim737 software.  

Compatibility

At the time of writing, CANBUS is compatible with ProSim-AR (plug and fly).  A dedicated driver for iFly and PMDG is under development.  Prior to purchase, I would seek the advice of SimWorld to whether CANBUS is compatible with the avionics suite you are using.

Reliability of CANBUS

In one word - 'perfect'.   I have not had the MCP, EFIS or CANBUS disconnect during a flight simulator session.  This is using FSX and ProSim-AR (version 1.49).  As a test, I disconnected the CAN controller during a flight, then reconnected it.  The flight was not disrupted and the re-connection occurred effortlessly.

Robustness and Service Life

The life and serviceability of a product has a direct relationship to how the product is used (or abused) and the duration of use.   Modern electronics are very forgiving, and electronic problems (if any) usually develop soon after an item begins its service life.  If problems are not detected after first use, then it is not unusual for an item to have a considerable service life.

Some of the more common problems that occur with reproduction panels include; failing encoders, damaged plastic encoder shafts, worn out set screws, slippage of knobs, and faulty switches and buttons.  Additionally, knobs may wear out with use, and paint on the lightplate may chip.  

SimWorld have countered potential problems by using printed circuit boards, commercial metal encoders, aluminum knobs, metal set-screws, and by replicated, as much as possible the same processes used in the manufacture of OEM light plates.  

The above said, it's wise to remember that reproduction panels rarely replicate the robustness and exacting standards of an OEM product; therefore, they should be treated with respect and with care.   I expect that in time the paint on knobs will chip and wear thin with use - this is normal wear and tear.  I don't mind this 'wear and tear' look as it is very seldom you a knob that is shiny new - unless the aircraft is new.

Quality Assurance (QA), Customer Service, and My Experience

Put bluntly, when anything is done by hand there must be a very high level of Quality Assurance (QA) to ensure that design specifications and tolerances are met.  QA can be an expensive process as time is needed to inspect each individual panel and then, if imperfections are noted, make required alterations/repairs.

There is a direct relationship between the price that an items costs and the amount and level of QA that is performed.  You would not expect an inexpensive item mass-produced in China to have high QA – and it doesn’t, which is why many Chinese-produced products fail after a short period of time or have obvious defects.   However, if you are purchasing a high-end product with a high price tag then the expectation is that this product will meet specification, will not have problems, and be sold with an excellent warranty and support.

SimWorld realize that enthusiasts demand quality and strive to meet this requirement.  However, not everything passes muster first time around and sometimes products are released that are not quite up-to-standard.   Whenever this occurs the reputation of the company is tested.

To ensure transparency, I have documented the issues below not to provide negative criticism of SimWorld, but to highlight their dedicated customer support and strong company ethics.  

My Experience

The first MCP and EFIS sent to me from SimWorld did not meet my expectations and had several issues.  Namely:  

(i)     Uneven brightness of the characters (digits) across the five LCDs with some characters presenting as hot spots;

(ii)     Rotary encoders cross-referencing values;

(iii)    A/T arming toggle not locking into the arm position (UP position);

(iv)    Crooked LCD in the course display window; and,

(v)     The light plate on the EFIS was not mounted parallel to the backing plate (crooked).

I contacted SimWorld and they requested that I return the panels to Poland (at their expense) for repair.  

The problems experienced were caused by:

(i)     The positioning of the LED behind the LCD was slightly off center.  This was rectified;

(ii)    The rotary encoders were faulty and had been tracked to a bad batch released from the manufacturer.  They were replaced;  

(iii)   The autothrottle toggle was not aligned correctly with the magnetic plate mounted behind the light plate. This was fixed by moving the toggle very slightly to the left;

(iv)    The crooked LCD was straightened.  As the LCDs are mounted by hand, careful attention must be paid to ensuring they are straight; and,

(v)     The misalignment of the F/O EFIS panel was rectified by making it straight against the backing plate.  

Repaired MCP and EFIS

Unfortunately, following receipt of the repaired MCP, the Captain-side course display would not illuminate.

Piotr at SimWorld organized for my computer to be tethered to their technician’s laptop to enable bench testing.   Unfortunately, the technician could not determine what was causing the problem, but thought it may be a faulty capacitor.  

Rather than attempt to repair the MCP again, Filip arranged for a replacement MCP panel to be sent to me by UPS.  

Replacement MCP Panel

The replacement MCP, by chance, was the newer panel manufactured in 2017.  I have not had any problems with the replacement 2017 model MCP and EFIS.  Both panels function flawlessly and the attention to detail on the panels is beyond reproach.  

Warranty and After-Sales Service

The MCP and EFIS is covered by 12-month unconditional warranty.

The after-sales service and warranty cannot be bettered, and I cannot stress the advantages of dealing with a company that treats its customers with respect and places customer service as a priority.  

In relation to the issues I had with the MCP and EFIS, SimWorld responded to my e-mails within 24 hours, followed up on my questions, provided reasons for the problem, and kept me updated with regard to repairs and/or replacement.   The after-sales service and support provided to me has been exemplary.  

Negatives - MCP and EFIS

It’s difficult to find any major negatives.  However, if pressed they are:

(i)    During the day, the digits displayed in the LCDs are difficult to read if the backlighting is dimmed 100%;

(ii)    The power connection on the rear of the MCP and EFIS is not secure.  If any pressure is applied to a cable, then it’s very easy for the connector to become dislodged from the panel;

(iii)    The laser cutting on the annunciator legends (Speed, V/S, RNAV, etc.) could be more precise (this really is not an issue unless you inspect your panel with a macro lens); and,

(iv)    The non-use of D-shaped shafts on the rotary encoders.  If used, this would minimise the chance of any knob slipping on the shaft of an encoder.

(v)   The brightness of the digits displayed in the LCD's, although more or less even across all characters, does show slight intensity differences.  This is caused by the positioning of the LED that sits behind each LCD. 

Pictures and Videos

I have not included many photographs in an attempt to keep the footprint of the article to a reasonable size. 

I have posted several 'very average' photographs in this gallery in an attempt to show you the appearance of the panels.  Promotional images and videos are fine, but they are always professionally made to show the product in its best light.  You will also see a few images of OEM panels in the gallery to compare.

Below are three professionally made videos courtesy of SimWorld.

The panels displayed in the video accurately reflect the appearance, detail and functionality of the MCP and EFIS.  Equally, CANBUS is as straightforwrd to connect as shown in the video.

 
 
 
 
 
 

Photography

A quick word about photography.  Detailed and close-up photographs will always show unwanted blemishes.  The better the lens the more blemishes will become obvious.  It's important to remember that you do not fly the simulator looking through a magnifying loop, but view panels from a moderate distance.  Even OEM panels show inconsistencies when viewed with a macro lens :)

Titbits

This article has taken several months to complete.  Originally it was three times the length and it's taken some time to condense the information to a length that is readable without it being bound in a book!

Final Call

The price paid to own the SimWorld MCP and EFIS is not inexpensive, however, it is nowhere near the price demanded of a OEM Collins panel, or a panel used in a commercial simulator trainer.

SimWorld's use of liquid crystal displays in lieu of seven-segmented displays, the resistance felt when turning the various knobs that closely match the OEM panels, and the close attention paid to detail: for example, the small tabs beside the Flight Director switches, detailed display bezels, ambient sensor, and realistic push to reset barometer and minimums knobs, is what separates this MCP and EFIS from its competition. 

If you want the appearance of the MCP and EFIS to be as close as possible to the OEM equivalent, and want accurate functionality, then you should not discount the panels produced by SimWorld.

Flight Testing The SimWorld MCP and EFIS

SimWorld MCP retrofitted into a Flight Deck Solutions (FDS) MIP.  Initial impressions exceed expectations, especially when comparing the appearance of the MCP to the OEM item

I have been using the Mode Control Panel (MCP) and Electronic Flight Instrument System (EFIS) produced by CP Flight.  These units have been the mainstay in the flight simulation community for several years and for the most part they are robust, reliable, and more or less look similar to the OEM units. 

Recently, other companies have begun to manufacture MCP and EFIS units to replicate the real aircraft part as closely as possible in both appearance and functionality. 

SimWorld, located in Poland is a relatively new company that is making great leaps forward designing and manufacturing reproduction 737 Next Generation panels and other components.  One of SimWorld's premier items is their 'plug and play' MCP and EFIS.

I am currently in possession of a SimWorld MCP and two EFIS units.  These units have been retrofitted into a Flight Deck Solutions (FDS) MIP and flight testing has begun.  In due course a detailed review will be published.  I also will be, at the same time, reviewing the CANBUS system that SimWorld use to connect their various panels to the computer and Flight Simulator.

To test and evaluate the unit will take some time as the protocols I use are very thorough.  In the next few months (depending upon time) I should have enough data to enable a detailed review to be written.  The review will address at the minimum the following:

  • Manufacturing technique (materials, painting, lazer cutting, etc);

  • Accuracy and scale to the OEM MCP/EFIS

  • Robustness and longevity;

  • Functionality to OEM unit;

  • Quality assurance;

  • SimWorld pre-sales and after-sales support;

  • Reliability and consistency in operation; and,

  • An overview of the CANBUS system.

Note that I have no affiliation with SimWorld, or any other manufacturer.  This review will be a balanced opinion based on my use and the use and opinion of other users of the MCP and EFIS unit.

Glossary

  • EFIS - Electronic Flight Instrument System.

  • MCP - Mode Control Panel.

  • MIP - Main Instrument Panel.

  • OEM - Original Equipment Manufacturer (aka real aircraft parts).

Update

UPDATE 07-03-2017 by FLAPS 2 APPROACH: There have been a few problems that needed to be sorted out on the MCP that was sent to me for evaluation.  After considerable testing by myself and SimWorld, it was determined the problem stemmed from a number of unreliable potentiometers.  These potentiometers were part of a bad batch delivered by the supplier.  Filip at SimWorld decided the best option was to manufacture a new MCP and this has only just been received via UPS.

Interestingly, the replacement MCP has a number of improvements over the old-style model which includes the use of Swiss-made commercial-grade potentiometers.

Over the next few weeks I will flight test the new-style MCP and document the results in a separate post.

Update

on 2017-04-07 07:02 by FLAPS 2 APPROACH

UPDATE 07-04-2017 by FLAPS 2 APPROACH: Finally, after considerable flight testing and editing a review which was very long, the final review of the SimWorld MCP and EFIS has been published.   I hope it answers the questions that many have been asking me in private messages and e-mails.

And to answer the question to whether I am impressed with the panels and will be keeping them in my simulator - Yes I will be - unless an OEM Collins panel appears at a reasonable price :)