:ugh: Cloud Tops = Range(ft) x (Radar Tilt Angle -1/2 Beam Width)
60
:confused: How is Beam Width determined?
Thanks

Also remember that the cloud tops (if we are talking cb:s)usually contain only ice crystals and will not be visible on wx radar as the radar beam from wx radars only reflects water dropplets.

Beam Width = 70 x λ / D
λ = wavelength
D = diameter of antenna

Try this formula

cloud height(naut miles)=range×(tilt-1.45ْ )×100
will give you clouds height in feet
1 nm=6076ft

YSB,

Most modern radars generally have 3 deg beams and as you know, using 1 in 60, 1 deg down at 10 nm = 1000' at 20nm = 2000' etc

To keep it simple I use this technique. I set the scanner tilt to -0.5 deg. so the bottom of the beam will be 2 deg down. 2 deg down at 10nm = 2000' and so all you have to do is double the range at which the return just appears to get its height difference in 100s of feet. So it just appears at 80nm it is 16,000 low.

For ludites like Buzzy, if you want to check out the radar's calibration. Say you are at 40,000' and put the antenna 10 deg down (-8.5 tilt) you should see the ground return at 40nm.

Ghost

Another method that works for me and is simple(ish)

Take your ht AGL in FL's and divide by 10 (eg FL300 over water = 30)

Paint the ground at this distance

Note the tilt (say -4deg)

Add 10deg (now +6deg)

The bottom of your beam is now parallell with the aircraft at FL300

Start tilting down untll you get a return

Say you pick up a return at 50nm at +3deg, that return is 15,000ft below you (50(x100) x 3 deg.

As previously stated you may have ice crystals well above this level which are not painting.
You don't need to know your beam width for this tech as you are using the bottom of the beam. Your beamwidth however will vary with the size of your radar dish (the bigger the dish the smaller the beamwidth)

Depending on which part of the world you fly, topping only visible moisture (visible either to the eye or the RADAR) does not guarantee topping turbulence. And, this also varies with the time of year (jet stream position) and topography.

For example, it is uncommon to experience less than moderate turbulence when topping thunder clouds while crossing the Rockies during the spring or fall (especially in the springtime) unless you have at least 5000 feet above the cloud tops. There have been reports of severe turbulence under such circumstances with as much as 10,000 feet clearance. These storm types are associated with fast moving cold fronts with a high speed jetstream above.

In contrast, flying in the tropical climates allows less restricted flight. There, topping the visible clouds by 5000 feet will normally produce no more than light turbulence.

Following the manufacturer's recommendations or your company's SOP for the use of RADAR makes good sense. Prudent RADAR tilt management is essential. And, normally, airliners are unable to 'top' turbulence. (Athough they can many times top the moisture.) Therefore, most manufacturers recommend (Boeing, Airbus, Bendix, etc.) that airliners avoid trying to top a storm, but instead, recommend diversion around the storm. Unless you're in a one of these new, high-flying business jets, you cannot regularly top turbulence.

With regard to antenna tilt, I've seen too many pilots fail to point the antenna sufficiently downward. The new generation RADAR units have the auto-tilt, and I've found these to be spot-on. (These negate the cockpit discussion regarding proper antenna tilt.)

In answering the original question, the posted responses are correct. Antenna beam width is dependent on antenna size. (Antenna gain and beam width go hand-in-hand and are inversely proportional.)

Further, unless the 'Gain' control is set to MAX, most time the tops of the clouds will not paint. Even with the control set to MAX, many storms have insufficient moisture to really show much of a return. Again, refer to the above example of springtime over the Rockies. I've seen cases where the returns were relatively weak (due to lack of moisture), but we got the $%^% beat out of us due to the convective movement.

(Please don't misunderstand what I'm saying. I don't recommend flying around with the gain control in MAX. 99% of the time, the CAL (or NORM) position is the proper setting. I just mentioned the MAX setting to illustrate how little moisture can be in these cloud tops. Again, follow the SOP, and you can go a long way to protect yourself.)

One Axiom of RADAR use: Moisture does not necessarily equal turbulence. We all learn this (OJT) at some point. :bored:


PantLoad

[quote]As previously stated you may have ice crystals well above this level which are not painting.


Agree. Read the POH for the type of radar you have. Rockwell Collins recommend use of MAX gain in cruise at high altitude to pick up the slightest echo which indicates a ice crystal top (may be well above you too) and then a combination of gain and tilt to gauge the size of the cloud. Works a treat in the Pacific region - don't know about over deserts. Either way, it is not worth the trouble of maths calculations to find cloud tops simply because of lack of reflectivity of anvils and CB tops. Old fashioned rat cunning with use of gain control is the best way to fly safe.

I have seen only one way to accurately assess cloud top height in relation to your own altitude- all this lah-de-dahing with radar tilt doesn't work in real life- how do you know the little tilt knob is set right?
Our pilot clipboards used to have a tongue halfway along the top with a metal eye in them- for hanging on walls. A captain put his pencil through the eye and held the clipboard end on hanging between him and the cloud, and sighted along the top of the clipboard. Spirit level! And it works.
Bit difficult at night when the lights are on because the copilot wants to do the Telegraph crossword. I hate them. Just can't do them.

Beam width on the A320 Honeywell radar is about 3.75 degrees if I remember correctly.

Bandwidths?

Tilt Angle?

Formulae?

Huh?

Look for the flash...then avoid that bit.....works a treat, and you can still do your sudoku:ok:

how do you know the little tilt knob is set right?If you can't do the telegraph :) then i guess we shouldn't expect you to be able to do the math but:

For ludites like Buzzy, if you want to check out the radar's calibration. Say you are at 40,000' and put the antenna 10 deg down (-8.5 tilt) you should see the ground return at 40nm.That is how you know the little tilt knob is set right. Then a bit more remedial math will give you the cloud tops (liquid water).

MAX gain at altitude. -2 tilt. At 40nm, if return touches arch on radar, turn to avoid.

Occasionally it's too conservative. Much better than the alternative.

Gentlemen:

Airbus has in their series, "Getting to Grips", Flight Operations Briefing Notes entitled, "Optimum Use of the Weather RADAR." It affirms much of what has been said by you guys in this thread. :ok:

Further, Airbus also has a really nice powerpoint presentation. My old airline showed this during one of the recurrent training sessions. It was so interesting and well-presented, that most of the guys put down their newspapers and crossword puzzles to watch. :)

I don't know how to obtain this powerpoint package. I guess a call or an e-mail to Airbus would do the trick. :rolleyes:

I really enjoy these discussions...


PantLoad

The Collins WX radar uses digital drive to stepper motors on the antenna, with digital position sensors, and the tilt shown the pilot is actual tilt with respect to the horizon, regardless of any marks on the knob. The flat plate antenna has a 3 degree beam width, and no sidelobes. In case it wasn't mentioned earlier, beam width is defined as the angle of half power point off dead ahead - times two, of course.

Earlier generation radars had parabolic reflectors, typically a 6 degree beam width, and lots of sidelobes. There was usually an altitude arc from spurious ground return.

GB

Antenna Tilt:
The Key Radar Control
Tilt management skills are critical to using
airborne radar properly, but first you
must understand the academics.
by Archie Trammell
We in aviation have known since first flight that a poor attitude-an incorrect mind set can kill. Not quite so ob-vious, however, is that someone else's faulty attitude may cause your accident. We now have a crystal clear example that the latter can be true.
In its investigation of the Delta Lockheed L-1011 crash in a thunder-storm at Dallas/Fort Worth Airport in Au-gust 1985, the NTSB in-terviewed Delta's sys-tems manager for train-mg, who said, .... .with any airborne radar de-vice, written instruc-tions and classroom ac-ademics are highly in-adequate.... It's largely something that has to be learned by experience."
The NTSB let the statement go un-challenged in its report on the accident, but we must not.
To let it be said that classroom in-struction in the fundamentals of radar need not precede knob twiddling is to leave a dangerous attitude uncorrected. Such a belief is no different than think-ing that the only way to teach a captain how to use a flight director is to load the airplane with 200 unsuspecting souls and dispatch him into an area of 200-and-a-quarter weather. Moreover, the statement is totally contrary to his-torical experience. It says that each suc-ceeding generation of pilots must start from zero and learn from his or her own mistakes, never benefiting from radar operating techniques and meth-ods worked out by others in thousands of hours. The truth is that without a background in the basics, no amount of trial and error will teach you how to use an airborne radar.
It's also revealing of the abilities of the Delta systems manager himself, who has not learned the first funda-mental about airborne radar operation. He doesn't understand tilt manage-ment, the prerequisite to all other radar skills. If he did, he would have never said in a follow-on statement to the NTSB interviewer, "The primary use of this type of radar, or any airborne radar with which I have any experience, is enroute weather avoidance. When you get into the approach environ-ment.. to get any useful work out of the radar, you have to do an awful lot of playing with the antenna tilt, and [since] you are also very close to the ground...you get a lot of ground re-turn. So, it's least useful in the ap-proach phase of the flight."
About 20 minutes of radar ground school-of "classroom academics"-will prove him totally wrong. Setting up a radar so that ground retums are eliminated from the display is nothing more than applied sixth-grade geometry and fourth-grade mathematics.
Let's examine just two of the "academic" facts and see how they might have prevented the Delta 191 acci-dent-if they had been passed on to the crew in a ground school.
Incidentally, these facts are not new. They were discovered by Captain Robert N. Buck of TWA during World War II and proven by the original Project Rough Rider pilot, Jim Cook of Dallas, in hundreds of thunder-storm penetrations be-tween 1953 and the present.
Fact one is that a ra-dar, which is an acro-nym for radio detection and ranging, detects and displays to the pilot on his indicator those objects-and those objects only-that are swept by the radar beam.
That beam is a narrow cone ranging from three to 10 degrees in diameter. It sweeps in a plane relative to the earth, selected by the pilot with an antenna tilt control.
The pilot, therefore, has total control of whether ground returns are detected and displayed. All a pilot has to do is select a tilt setting that results in the swept area being above all ground ob-jects. Ideally, the tilt should be set so that the bottom edge of the conical beam sweeps on a plane parallel to the surface of the earth, as in Figure 1.
With the bottom of the beam sweep-ing on a plane parallel to the surface of the earth, only those objects that ex-tend upward through the altitude of the aircraft are detected and displayed. Thus, at terminal-area altitudes (any al-titude below 15,000 feet), only tall threatening weather is displayed; ground returns are eliminated from the display.
Fortunately, setting the tilt to the proper position is very simple to do. First, adjust the tilt control until the bottom edge of the beam is sweeping along the ground on the 20-nm arc
You can easily identify where the bottom of the beam intersects the earth. From the bottom of the beam outward the radar indicator will be filled solid with a band of returns all across the swept sector; from the bottom of the beam inward the radar indicator will be blank (see Figure 2).
Next, divide your altitude in thou-sands of feet agl by two. Finally, note the tilt setting with the bottom of the beam sweeping on the 20-nm arc, then increase tilt by a number of degrees equal to the calculation. (Example: You are at 12,000 feet agl; 12 divided by two equals six. With the bottom of your beam sweeping on the 20-nm arc, the tilt index is at minus four degrees, let's say. If so, raise tilt to a setting of plus two degrees-minus four plus six equals a positive tw~and the bottom of your beam is now sweeping an area from 12,000 feet agl upward. Anything depicted on your radar indicator is an object with a height greater than 12,000 feet agl.)
Had the Delta 191 crew been aware of this procedure (we call it TIP, for threat identification procedure), they would have known that significant weather was on or near the approach to DFW Runway 17L at least 14 minutes before impact.
At 1751:19 hours (impact was at 1805:55), the second officer saw rain ahead. At 1752, just 41 seconds later, the aircraft was descending through about 12,000 feet agi, headed almost directly toward the airport, which was about 40 nm away. At 1752:00 TIP would have revealed a contouring cell at the 35-nm range dectly between them and the airport.
At 1756:00, when the aircraft was at 7,000 feet, 25 nm from the airport and headed direcdy toward it, TIP would have revealed a contouring cell at the 23-nm range. The crew would have known a storm was in progress on or very near the final approach course at least six minutes before flying into it.
"The Magic Radar Formula"
Had the Delta crew run a height evaluation procedure (HEP) on the storm at 1756:00, they would have known it was exceedingly hazardous for a terminal operation.
To understand how HEP works, one must first become familiar with what we refer to as "the magic radar formula," which is the basis for all ra-dar tilt-management procedures, tricks and shortcuts.
Since the radar beam is angular (a cone with a width measured in de-grees) and tilt management is strictly an angular manipulation of that beam, one must have a method for converting degrees into feet; namely, distance times 100 equals feet per degree at that distance.
The dimension across a degree changes constantly as the distance from the origin increases-your radar anten-na being the origin in this case. To de-termine how much the beam is shifted up or down per degree at a certain dis-tance, put two zeros behind the dis-tance in nautical miles and you have the answer in feet. At 10 nm, for exam-ple, one degree is 1,000 feet (10 fol-lowed by two zeros). At 20 nm, one de-gree is 2,000 feet across, at 37 nm, one degree is 3,700 feet across and so forth.
The formula isn't as accurate as trig-onometry, but a pilot doesn't have time for trig during an approach. The formula is more accurate than your tilt control, however, which has a degree or more of variance in it under the best of conditions.
Incidentally, you can use that formula to prove why TIP works. You can also use it to modify TIP to better suit the situation. At high altitudes (above 15,000 feet agl) put the bottom of your beam on the 40-nm arc and di-vide your altitude agl by four rather than two.
At 32,000 feet agi, for instance, 32 di-vided by four equals eight. Put the bot-tom of your beam on the ground at 40 nm, raise tilt eight degrees and the bot-tom of your beam is level to the earth at an altitude of 32,000 feet agl. (We can ignore the fact that the earth is round as long as the distance of interest is 60 nm or less.)
Why does raising the bottom of your
beam eight degrees place it parallel to the surface of the earth? Because at 40 nm, each degree raises the bottom of the beam 4,000 feet and 4,000 feet times eight equals 32,000 feet. If the bottom of your beam is on the ground 40 nm ahead and you raise it eight de-grees, the bottom of your beam at a point 40 nm ahead will now be at the same altitude as your antenna; there-fore, the bottom of your beam will be parallel to the earth's surface at an alti-tude of 32,000 feet agi.
If you prefer to divide by three, five or eight, place the bottom of your beam on the ground at 30, 50 or 80 nm, re-spectively. TIP still works. We'll let you calculate why.
Antenna Stabilization
Before proceeding, we must clear up a prevalent misconception. Many pilots think that tilt directs the radar beam up or down relative to the pitch attitude of the aircraft. In fact, the pilot's manual for the radar that was installed in Delta 191 states that, "Selected (tilt) angle is in relation to the longitudinal axis of the aircraft."
Totally wrong. Selected tilt angles are relative to old Mother Earth. In air-craft that do not have ~ antenna stabiliza-tion, or when stab is turned off, tilt an-gles are relative to the longitudinal axis of the aircraft. However, all airliners, and virtually all corporate turbine air-craft, have stabilized antennas.
With stabilization, a reference from the aircraft vertical gyro is biased into the tilt knob logic. Therefore, tilt set-tings command the angle at which the center of your beam sweeps relative to the plane of the earth directly below the aircraft. Change pitch or roll atti-tude and the angle of your beam and beam sweep remain unchanged with respect to the horizon.
It's very important to understand that result. It's also very important that pilots of aircraft that do not have stabi-lized antennas-or when stab is off-always correct tilt selections for deck angle excursions from level flight. Otherwise confusion will reign.
Notice what antenna stabilization does for you. Once a TIP is conducted, or once the beam is set to any desired angle relative to the earth, you do not have to mess with the tilt control again. With stabilization, the beam inclination stays where you left it relative to Earth, as your attitude and altitude change, which means you can perform a TIP once and the bottom of your beam will remain level with the earth as you climb or descend. TIP once and what you see on your radar intrudes through your current altitude even as that alti-tude is changing in a climb or de- scent. (This discussion assumes that the aircraft is in reasonably stable flight. Maneuvers and speed changes intro-duce a number of errors into the anten-na stabilization system due to gyro ex-cursions. But those errors also affect the flight control system and other flight management procedures and so must be the subject of a broader, dedicated discussion at a later time. Suffice it to state here that when gyro errors may be a factor, TIP and other tilt-management procedures must be conducted more frequently-at no more than two-min-ute intervals- in order to zero out the system.)
The HEP
Now, with "the magic radar formula" and stabilization well under-stood, how do you conduct a height evaluation procedure?
First perform TIP, which places the bottom of the beam level at your cur-rent altitude. Next, note the distance to any echo of interest and your tilt set-ting. Finally, raise tilt until the echo be-comes so weak that you can just barely see it on the indicator. (The echo be-comes weaker because the beam begins to over-scan it.) Now, the distance to the echo multiplied by 100 multiplied by the tilt difference equals the height of the storm above your aircraft's cur-rent altitude.
Let's use Delta 191 at 1756:00 as the example. The flight was about 7,000 feet agl, 23 nm from that cell over the approach course.
At least seven degrees of up-tilt from TIP would have been required to re-duce the echo to just detectable (calcu-lating 23 times 100 times seven: 16,100 feet). Adding the current altitude, 7,000 feet, yields a radar top of about 23,000 feet. A 23,000-foot-high contouring storm located directly on the localizer is bad news to anybody.
A Shortcut HEP
But a reasonable question is, does a crew have time for that much knob tweaking and mental arithmetic during a busy approach?
Normally, yes. With practice, the en-tire TIP and HEP tilt manipulations re-quire only 15 or 20 seconds. But even 15 seconds can be too long at times.
In that event, use the tilt-up tech-nique, TUT for short. That is, adjust tilt so that the center of your beam is an-gled up 10 degrees.
To accomplish that you must know where true zero degrees tilt is-true zero degrees tilt being the setting that results in the center of your beam being parallel to the earth. It's probably not at the zero-degree mark on the tilt control because of antenna installation errors and/or stabilization gyro excursions.
To find it, execute a TIP, then lower tilt one-half your beam width (see Fig-ure 3 to find your beam width). With a 12-inch antenna (assuming X-band ra-dar) true zero degrees tilt is at TIP -4.0 degrees; with an 18-inch antenna, it's at ~P -2.5 degrees; with a 30-inch an-tenna it's at TIP -1.5 degrees.
When using the + 10-degree proce-dure, ignore the fact that your beam is a cone, that it has a width. Assume that radar tops are at the center of your beam, which will build in a safety cushion.
Now, with + 10 degrees on the tilt, echoes displayed at a distance of 30 nm or more have radar tops at least 30,000 feet above your current altitude. Those displayed at distances of 20 nm or more have radar tops of more than 20,000 above you. (Note: HEP and TUT give you an estimate of radar tops-not the top of the storm. For overflight planning, hazards may exist several thou-sand feet above the radar top of a weather system.)
Research has proven that the hazards associated with a weather system are directly proportional to its radar height. In the terminal area, any storm with a radar top in excess of 20,000 feet agl is a potential killer. In addition, any echo that contours at any distance with + 10 degrees of tilt is a no-go when operat-ing below 15,000 feet.
From that comes three absolute, life-and-death, terminal area rules.
With + 10 degrees of tilt, any echo that first appears on the display· at 20 nm or greater-whether contouring or not-must be avoided.
Any echo that contours at any dis-tance with + 10 degrees of tilt must be a·voided regardless of how tall it is.
With + 10 degrees on the tilt and after the gear is out, if a· contouring echo is detected inside the five-nauti-cal-mile arc and cannot be avoided, in-itiate a missed approach immediately. On departure, don't go.
Looking back over the string of 23 thunderstorm-related air carrier acci-dents that have occurred in the last quarter century, the TUT rules alone would have prevented 16. And the false alarm rate of the rules is very low. The best data available indicate that abiding by those rules will result in an average of only 16 delays per year per major airport-a small price to pay, when you consider the cost of one fatal accident.
Surface Analysis
As important and useful as the + 10 degrees tilt procedure is, it must be fre-quently alternated with the Surface Analysis Procedure (SAP), especially in the terminal area.
The SAP requires that the tilt be ad-justed so that the bottom of your beam slopes downward four degrees (TIP minus four degrees).
That tilt setting and the 50-nm range setting (or as close to 50 nm as possible with your particular range selector) should be considered your normal ter-minal area radar configuration. Adjust tilt to TIP and TUT for several sweeps at frequent intervals, but always return it to the SAP position. Shorter or longer range selections should be used only intermittently, the exception being when within 10 nm of the runway on approach. As the airport draws near, a 25-nm or even 10-nm range selection is appropriate, but do not fail to go back out to 50 nm on occasion with tilt set at TUT to survey your missed approach path-just in case.
Whenever the bottom of your radar beam is slanted down four degrees your radar display will provide you with three vital types of information:
(1) A terminal area radar map-With the bottom of your beam down four degrees, the radar will paint a band of ground from 25 nm outward when the aircraft is at 10,000 feet agl. On arrivals, the 25 nm works inward 2.5 nm per 1,000 feet of descent so that when crossing the marker inbound, your radar will be displaying ground from about four nautical miles outward to the edge of your indicator.
Ground painting terminal areas fre-quently on VMC days is critical. A pilot who flies into a given terminal six or more times per year should know the radar signature of the area so well that he can fly to the center of the airport with no guidance other than radar. He should be able to point out, on the indi-cator, every lake, ridge, mountain peak, shopping center, tank farm and rail-road yard in a 25-nm radius of the mid-dle marker. Such ability is called radar professionalism. It is often useful and sometimes lifesaving.
By knowing where the major radar landmarks are, a pilot can quickly iden-tify storms in the airport vicinity just by glancing at the radar indicator and without touching any radar control:.
They are the strong echoes that weren't in a particular location last trip. Moun-tain peaks, suburban developments and tank farms don't grow overnight.
After identifying a weather echo ei-ther with TIP or by ground mapping, the wise pilot watches what happens with his tilt set at the SAP position. If the echo gets stronger or larger over a period of four or five minutes, it's a rap-idly growing storm. If it gets smaller and weaker minute to minute, it's like-ly to be a dissipating storm.
Interestingly, during the eight min-utes from 1751:19 to 1759:37 that Delta 191 was vectored straight toward DFW, a cell that was six nautical miles north-east of the airport over mostly farmland dissipated from Level 3 to nothing. At the same time, a second cell at four nautical miles southwest of the first, grew from nothing to Level 3. It was the second cell that spewed out the downburst as Flight 191 flew into it.
(2) Terrain threat warning-With a four-degree down slant to the bottom of the beam, over flat terrain, ground should be painted from the 25-nm arc outward as the aircraft passes through 10,000 feet agl. At 5,000 feet it should be on the 12-nm arc. Crossing the marker it should be on about the four-nautical-mile arc.
If your radar indicator doesn't agree during a climb or descent, something is not right, including the possibility that you may not have as much terrain clearance as you think.
Over mountainous terrain, a ground echo that intrudes inside the 10-nm arc with tilt adjusted for SAP should com-mand your undivided attention. You are less than 4,000 feet above a peak. Perhaps you are below it. One that in-trudes itself inside the five-nautical-mile arc is cause for alarm, unless you have it visually, because you cannot be more than 2,000 feet above its peak. Within about two minutes you'll dis-cover if you are below the peak.
(3) Radar shadow enhancement-This skill is the most important of all. Failure to identify a radar shadow is the greatest cause of convective weather accidents.
The tragedy is that they just about jump off the scope at you when you're aloft if you would just select the 50-nm range and adjust your tilt so the bottom of your beam is angled down four degrees.
The radar shadow in the accompanying photo (Figure 4) is that black wedge trailing off into the distance at the 11 o'clock position. The black area on the right is a large lake.

Shadows always point directly away from the antenna. They have a fea-thered edge, as in the photo, and they continue outward as far as ground re-turns can be painted. (If the sides of a shadow come together in the distance, you are above the object casting it.)
Radar shadows are caused by a weather system so dense that radar en-ergy cannot penetrate it just as a shad-ow from a flashlight is caused by an ob-ject so dense that light is not able to penetrate it).
Notice in the photo that energy is penetrating the left side of the storm; it cannot penetrate the right side.
The rule is, never, never, ever contin-ue toward a radar shadow. Failure to recognize a shadow and abide by the rule is the cause of 90 percent of con-vective weather accidents. Eastern Air-lines Flight 66 crashed in a shadow at JFK in 1975; Southern's Flight 242 crashed in a shadow at New Hope, Georgia in 1977; Air Wisconsin crashed in a shadow northeast of Omaha in 1980; Pan American crashed in a shad-ow on takeoff at New Orleans in 1982; USAir crashed in a shadow at Detroit in 1984; Delta Airlines Flight 191 crashed in a shadow at DEW in 1985; a corpo-rate Westwind crashed near several shadows in 1986.
Evidence is abundant that airplanes cannot fly through weather that casts a shadow. Rainfall rates in a shadow -producing storm frequently exceed the certification limits of the aircraft and engines. In addition, shadowing storms will contain microbursts, downbursts, large hail, extreme turbulence and very possibly, tornadoes. A storm casting a shadow can be identified with tilt up, but the clues are subtle and easily misread. With the SAP technique they can-not be missed. Those who know how to identify and read such indications are safe pilots; those who don't may as well turn off their radar. It's useless to them. (By the way, don't rely on the gimmicks of some newer radars that purport to identify shadows but often do not indicate a shadow where there is one. Put your tilt down and watch for the real shadows.)
In these few pages we have barely exposed the tip of an iceberg. We've touched on only two of hundreds of techniques, shortcuts and radar facts that can never be discovered in years of self-education. We hope that the NTSB will have second thoughts on their tadt agreement with the statement, .... .with any airborne radar device, written instructions and classroom academics are highly inadequate."
Meanwhile, don't let that attitude be the cause of your accident. Practice the TIP, REP, TUT and SAP techniques until they become second nature with you. Then steer far, far away from all radar shadows.
Those Confusing Side Lobes
The fundamental truth in under-standing tilt management is that ra-dar detects and displays only those objects that fall within the limited area of the three degree to 1 degree conical beam. Objects not "Illuminated" by the finite dimensions of the beam are not detected.
But for every rule there is an ex-ception. If the antenna installation is poorly engineered or if the ra-dome is imperfect, ghost images appear on the indicator. Several weather echoes can be seen in the accompanying photograph. The one at 12 o'clock and two nautical miles, however, is not weather. It's a false echo.
False echoes are commonly re-ferred to as "side lobe returns," or simply as side lobes, although in reality they are caused by refracted energy from the main beam. Metal objects in the radome cavity, water trapped In the honeycomb of the radome, a metallic paint strip. around the nose or one of those horrible plastic nose caps can gen-erate side lobe returns.
The cause should be corrected by taking the aircraft to a first-class radome repair shop, but almost no one bothers, so pilots must learn to live with false echoes.
In some instances a spear of refracted energy points downward, bounces off the ground and shows up as an echo at 12 o'clock. No matter where you place the tilt, there is the echo at 12 o'clock. In other instances the spear points to the side so that you see a side-lobe return, also at 12 o'clock, only when flying abeam a storm.
In still other instances, you see no side lobe return when your ra-dome is dry; you see one only when your radome is wet or has Ice on it. Whenever you're in weather, you always have a false, contouring storm at 12 o'clock, never more than five or six miles distant.
A necessary radar skill is learn-ing to recognize and ignore side lobe returns. There are several ways to identify them. First, just observe your radar on clear days. Ex-ecute TIP and if you see an echo, it's a side lobe. Mark it in your mind as something to ignore.
If you see side lobe returns only when in weather, however, identify-ing them gets a little trickier. One clue is movement. An echo that you cannot catch up to is a side lobe re-turn because storms never move as fast as an airplane flies. An ex-ception (there's that exception again) is when you descend. A side lobe caused by energy spilling off the antenna and pointed straight down will appear at a range rough-ly equal to aircraft altitude agl. Therefore, when you're descend-ing or flying toward rising terrain, it will appear that you're overtaking a side lobe-which is something else you must observe on several flights and learn to ignore.
If all else fails, select the 50-nm range (or as close to 50 nm as pos-sible), run your tilt down until you have a solid ground paint from 10 or 15 nm outward, then back way off counterclockwise on your gain control. If a shadow appears be-hind the suspect echo, it's real; if not, it's a side lobe because side lobes do not cast shadows.
Business &Commercial Aviation / June 1987
Antenna Tilt

Airbus has in their series, "Getting to Grips", Flight Operations Briefing Notes entitled, "Optimum Use of the Weather RADAR."

This document, together with tons of other very interesting read can be found on http://www.smartcockpit.com/pdf/flightops/aircraft/0017/

Those who would take Archie Trammell as gospel should be made aware that while he was doing a service, he was selling his services, so was not unbiased.

Flt 191 Delta 1011 had the old Arinc 564 radar with all its sidelobes and other limitations. The Bendix and Collins Arinc 700 digital wx radars had been in operation three years already in the 767, 757 and other airplanes. Those radars were designed to overcome the limitations of the prior radars, around which Trammell's course was built. The new radars provide(d) a reliable solution to shadowing: Path Attenuation Compensation, and PAC Alert, when the radar senses it cannot see completely through the storm, or the storm behind the storm.

A Dallas tv station had its own weather radar 15 miles from DFW. It was a ground-based version of the Arinc 700 airborne Wx radar, complete with doppler turbulence detection. At about the very moment DL 191 was on approach, the tv weather man showed and commented on the turbulent cell right over DFW.

You might ask why the FAA didn't have that same radar picture? Government incompetence reigns.

Why hadn't Delta retrofitted the valuable L-1011 fleet with the latest radar? The FAA didn't require it.

GB

My response: If the pucker factor overwhelms, then AVOID.

Otherwise your colleagues will be writing about you in this forum!

A good book on this is "Airborne weather radar: A user's guide" by James C. Barr.
By the way, who plays with the radar at your airlines? PF, PNF or always the captain?

I remember the old Archie Trammell movies from many years ago which always sent me to sleep. I think Harry Hill probably based his character on archie with the ill fitting jacket, big collar and a dozen pens in the top pocket.

just thought Id share that with you as Im bored