Note: This is a slightly modified version o' all the information that Doug has produced for his Level 3 project. Begad! Aye aye! Blimey! Visit his site to read t' additional information and enjoy additional pictures.

Introduction

I entered high power rocketry in 1988 for t' sole purpose t' fly camera rockets. Avast, me proud beauty! I have been flyin' model rockets since 1973 but t' class C motors are just nay adequate t' provide t' necessary power t' achieve t' altitude required for a camera t' take quality pictures. Ahoy! I have flown dozens of different kinds o' cameras from a variety o' rockets and configurations. Avast, me proud beauty! I have flown 110, 35 mm, arrr, 8 mm movie, ya bilge rat, video, and even a large format (4" x 5") camera, me hearties, but by far t' most common camera I fly be t' 35mm. Begad! 35 mm cameras have fast film advance rates (up t' 2 ½ frames per second), shiver me timbers, very fast shutter speeds (1/2000th second), and t' film is large enough t' get great pictures when enlargin' t' print. Anymore, shiver me timbers, I don't fly a rocket without a camera on board.

This certification level 3 project provided me with t' opportunity t' take photographs with a unique perspective that is just nay available with level 2 rockets. T' larger diameter rocket, payload weight available, and altitude achieved allowed me t' achieve many o' me goals. Blimey! T' general goals o' this project are:

• Design and build a large rocket capable o' liftin' multiple camera payloads.
• Fly t' rocket with an M motor safely and achieve me level 3 certification.
• Take photographs o' specific target objects.
• Recover t' rocket and cameras intact.

Specific Design Objectives

I did nay want a complex rocket. T' rocket design is a straightforward, matey, single stage rocket. Only t' payload is complex. Arrr! However, thar are some specific photographs that I wanted to achieve with this project. Aye aye! T' specific design objectives are described here. Arrr!

1. One photograph that I have always wanted t' get was a profile shot o' the booster descendin' on its parachute with t' horizon in t' background. Begad! I have tried t' get this by pointin' a camera out t' side o' t' payload section, but the odds o' gettin' t' booster in t' view o' t' camera is very small. Avast, me proud beauty! How can such a photograph be guaranteed? By placin' t' payload section above the booster, matey, havin' t' payload section descend faster than t' booster, ya bilge rat, and photographin' 360° around t' payload section o' course. Ya scallywag! Begad! This required a set o' eight (8) cameras mounted at equal spacin' around t' payload section that take their pictures simultaneously as t' rocket and payload descend on their parachutes. Ahoy! Since t' booster section deploys its parachute at a lower altitude than t' payload section does, this design will also require the payload section t' descend faster than t' booster t' overtake t' booster and pass it as they descend t' t' ground. Aye aye! These cameras are numbered 1 through 8. Aye aye! Begad!
   
2. I also want t' photograph t' rocket as it ascends t' apogee. This view covers 360° below t' rocket. Ya scallywag! Begad! Blimey! T' achieve this, a pair o' 35-mm SLR cameras are mounted so their angle o' view is 180° t' each other lookin' out perpendicular t' t' rocket. Begad! Ahoy! Blimey! T' view is then reflected down t' side o' the rocket via a first surface mirror and t' cameras are triggered simultaneously from t' same timin' circuit. Begad! Blimey! T' angle o' t' mirror is such that each camera should be able t' see part o' t' rocket body and fins. Begad! Aye aye! Blimey! In this way the photographs will overlap slightly, nearly doublin' t' coverage from one camera. T' two photographs can be joined together t' provide 360° coverage below t' rocket. Avast, me proud beauty! These two cameras are activated at take-off and are numbered 9 and 10.
   
3. One camera is specifically designed t' photograph t' booster fallin' away at separation. Ahoy! Begad! One 35-mm SLR camera is mounted in t' base o' t' payload section lookin' straight down into t' booster. Arrr! This camera is activated at separation t' capture t' booster fallin' away and continue t' photograph the booster as it descends below t' payload section. This camera has a wide-angle lens for general aerial photography and is numbered 11.
   
4. T' payload section must be stable, even though it is nay powered, arrr, to ensure photographs are taken o' t' booster fallin' away. Well, me hearties, blow me down! If t' payload section is unstable it might tumble and t' booster would smartly move out of the camera's field o' view. Since t' payload section should still be climbing when t' booster separates, matey, t' stability o' t' payload section ensures that the payload section is above t' booster when its parachute is deployed and the cameras remain lookin' at t' booster.
   
5. And finally, me bucko, these payloads are carried t' an altitude o' approximately 4,000 feet.

With these design objectives defined, I designed t' rocket t' meet these 5 criteria. Ahoy! What follows is me level 3 certification project.

Description o' t' Flight

There is nothin' special about the sequence o' events for t' rocket flight. Blimey! After t' motor burns, matey, thar be a coastin' phase t' apogee where t' parachutes are deployed. Avast, me proud beauty! However, it is slightly unusual in that t' booster separates from t' payload section approximately two seconds before apogee t' deploy t' booster's parachute and the payload section continues t' climb t' apogee where its parachute is deployed.

Sequentially, at takeoff cameras 9 and 10 take pictures every 0.5 seconds until motor burnout and then one picture every 1.5 seconds t' booster separation. Avast, me proud beauty! T' booster separates approximately 2 seconds before apogee when cameras 9 through 11 take about 4 pictures at a rate o' 2 frames per second. At the end o' these pictures, matey, with t' payload section close t' apogee, matey, the payload section deploys its parachute. Avast, me proud beauty! There is about a 10 second delay for the payload section t' settle down then all 11 cameras take pictures until they run out o' film on descent o' t' parachute.

Here is a detailed description o' t' sequence o' events for each set of cameras.

Cameras 1 through 8

Cameras 1 through 8 described above start takin' pictures 10 seconds after separation. Ya scallywag! This delay is t' allow the payload section t' settle down from t' parachute bein' deployed. Well, blow me down! All eight cameras are activated simultaneously every 5 seconds from two 4-pole relays.

Cameras 9 10

Cameras 9 10 start takin' pictures at a rate o' approximately one picture every 0.5 seconds from takeoff through motor burnout, then one picture every 1.5 seconds t' booster separation (~24 shots). Ya scallywag! T' change in t' rate of pictures bein' taken is desired because early in t' flight, durin' t' motor burn, t' rocket's altitude is changin' very fast and it is still close t' the ground. Aye aye! Blimey! After t' motor burn, arrr, t' altitude is higher and t' rocket speed is decreasing. Since an object in t' camera's view is nay changin' as fast, fewer pictures are required. At separation, ya bilge rat, t' cameras shoot in continuous mode for approximately two seconds (~4 pictures). Then thar be a delay o' about 10 seconds t' allow t' parachute t' open and settle down. Well, blow me down! Then t' remainder of the roll o' film is shot at a rate o' one picture every 5 seconds.

Camera 11

This camera starts taking pictures at booster separation continuously for approximately two seconds (~4 pictures) t' capture t' booster fallin' away. Avast, me proud beauty! Again, thar be a delay o' about 10 seconds t' allow t' parachute t' open and settle down and t' remainder of the roll o' film is shot at one picture every few seconds.

Project Description

T' rocket is shown in Photo 1. Ya scallywag! Well, blow me down! Individual sections o' t' rocket are further described in t' Structural Design Considerations section. Aye aye! T' details of t' overall rocket are:

T' rocket has a 7-foot long booster made from LOC® BT-7.51 tubin' with a 98 mm motor mount. Ahoy! Immediately above t' booster is a 3-foot payload section where t' cameras are mounted. T' payload section has cowlings and fins to stabilize it. Begad! Although it may look like a second stage, matey, it is nay powered.

Above t' payload section is a reducer that tapers t' rocket down to LOC® BT-5.38 tubing. This is where t' payload’s parachute is located. T' nose cone is also LOC's, me bucko, a PNC-5.38L which is weighted for stability o' the payload section.

Each camera uses a roll o' 36 pictures but usually 37 photographs can be taken from such a roll. Arrr! On one flight a total o' 407 pictures are taken from eleven high quality cameras.

T' expression "My Mind's Eye" has been described by psychiatrists as "mental images, me hearties, arrr, pictures, or sensations in your imagination". Begad! This is an excellent description o' this project. Ya scallywag! T' design objectives were created based on ideas o' what I wanted t' photograph and then the rocket was designed t' meet those objectives.

Structural Design Considerations

Body Tubes

T' booster o' t' rocket and t' payload section are constructed from LOC® BT-7.51 body tubes. Blimey! Avast, me proud beauty! T' diameter was selected t' accommodate the cameras in t' payload section. Its length is 7 feet so that t' fins will still be in focus for t' cameras that look down t' side o' t' rocket and to increase overall stability. Well, blow me down! All body tubes are covered with fiberglass and epoxy for re-enforcement. Avast, me proud beauty! T' weight o' t' fiberglass and t' number o' layers are different for different areas o' t' rocket. Arrr! Begad! T' upper section o' the booster has two layers o' 3-ounce fiberglass.

There is a removable electronics bay in t' booster that contains the Adept® Rocketry Timer and t' Black Sky® ALTACC for t' booster ejection charge. Begad! T' timer be t' primary circuit and t' accelerometer is the backup circuit. Avast! Two are used for reliability and both use an electric match that ignites t' same ejection charge.

T' entire rocket is covered with fiberglass, arrr, epoxy, two coats o' white epoxy primer paint, and several coats of finishin' paint. Two brass machined rail guides are attached with wood screws to t' two 1 inch centerin' rings at t' end o' t' motor mount tube.

Motor Mount Assembly

T' motor mount is constructed from LOC's heavy-duty thick walled (0.090") 98-mm motor mount tube. Avast, me proud beauty! Photo 2 is a diagram o' t' motor mount configuration. Avast! Well, blow me down! It uses two motor tubes connected by a centerin' ring. Begad! Blimey! Two 5/16th inch closed eyebolts are attached t' t' all-thread that extend down to the fin unit centerin' ring. Begad! Begad! T' all-thread has nuts, washers, and lock-washers on both sides o' every centerin' ring. Ya scallywag!

T' fins and centerin' rings (Photo 3) all have internal fillets as shown in Photo 4. Begad! Havin' both internal as well as external fillets increases the strength o' t' joint without havin' unsightly, arrr, massive external fillets alone. T' centerin' rings are made from ½-inch thick, ya bilge rat, oak plywood. Aye aye! Two centering rings are used at each end o' t' motor mount tube (1 inch thick). Begad! T' fins, shown in Photo 5, were constructed from 1/8th inch G-10 fiberglass in t' core and laminated with 3/16th inch plywood on each side and t' leadin' and trailin' edges were tapered.

T' Reducer

T' reducer is made from solid hard balsa from LOC custom engineering. Blimey! Aye aye! It is specifically designed t' have full diameter length shoulders for both t' upper and lower body tubes. Begad! T' bottom o' t' reducer has a ¼ inch plywood plate that is epoxied t' t' base o' t' reducer and six ¼ inch by 6" long lag bolts t' secure t' plate. Avast! Avast, me proud beauty! T' purpose o' t' plate is t' secure two ¼ inch T-nuts for two bolts that will secure t' mount for cameras 1 through 8. Attached t' t' ¼ inch plate is another ½ inch thick oak plywood plate that also has T-nuts used t' secure t' camera payloads t' t' reducer. Well, blow me down! Ahoy!

T' top o' t' reducer has four 12" pieces o' ¼ inch all-thread, which stick out o' t' top o' t' reducer about 3/4 inch t' secure t' upper body tube. Arrr! T' upper body tube is used for t' payload’s parachute compartment and has a 1/8th inch fiberglass plate sandwiched betwixt two 3/16th inch thick plywood plates and epoxied into t' BT-5.38 body tube. Ahoy! Avast, me proud beauty! This plate has two 5/16th inch closed loop eyebolts for t' payload recovery and is bolted to t' reducer. Ya scallywag! A hole has been drilled through t' reducer t' pass electrical wires for t' upper ejection charge located at t' top o' t' reducer. The reducer is covered with 3 ounce fiberglass and epoxy except for t' shoulders.

Recovery Design

T' most likely failure o' t' flight is with t' recovery. Arrr! Blimey! This design incorporates several ideas t' reduce t' chance o' recovery failure.

• There are two parachutes (Rocketman® R18C), one for t' booster and one for t' payload section, shiver me timbers, t' prevent any damage t' rocket would suffer by havin' one section slam against t' other if only one parachute were used.
• Every eyebolt in t' recovery design is a 5/16th inch closed loop eyebolt with a workin' load o' 900 pounds.
• This design uses nomex® in both t' booster and t' payload section to ensure that t' parachutes are protected as well as usin' a deployment bag.
• T' parachutes are attached by tubular nylon rope with t' ends secured.
• Below t' parachutes, two flat tubular nylon ropes are used for added safety. Begad! Blimey! Both are coated with black electrical tape t' prevent t' hot ejection gasses from burnin' and weakenin' t' ropes.

Nose Cone

T' nose cone be t' PNC-5.38L from LOC. T' nose cone is epoxied t' a 30 inch piece o' BT-5.38 body tube. Ahoy! A regular body tube coupler is used t' attach this section t' t' payload section. Aye aye! There is about 10 pounds o' weight added to t' nose cone t' increase t' stability o' t' payload section as well as the entire rocket. T' parachute is attached t' t' weight in t' nose cone via a 5/16th inch steel all-thread rod, and t' weight is firmly attached t' the nose cone by plaster, which also adds additional weight.

T' coupler is reinforced with four 1 inch wide pieces o' ½ inch thick oak plywood. T' body tube is covered with fiberglass that extends above the shoulder o' t' nose cone t' further increase t' strength o' this section.

Launch Pad

T' launch pad (Photo 6) is o' me own design and is truly a launch "pad". Begad! It is basically a pentagon shaped table with reinforced legs that t' rocket sits on. Well, blow me down! O' course thar be a 7- inch diameter hole in the middle o' t' table for t' blast o' t' motor. Blimey! Aye aye! T' legs are angled at 45º for greater stability and t' attach support brackets for t' rail. Ya scallywag! Aye aye! T' height of t' table is over 3 feet from t' ground t' allow clearance for t' blast of the motor. Blimey! Well, blow me down! T' rocket is guided by a 12 foot long Black Sky® ProRail. Blimey! Ya scallywag! The rail is secured at t' table by a hinge as well as at t' legs. Avast, me proud beauty! T' launch pad is staked into t' ground at t' legs t' ensure it will nay tip over while loadin' t' rocket onto t' pad or durin' launch.

Redundancy, Reliability, matey, me hearties, me hearties, and Recoverability

This design incorporates redundancy, me hearties, arrr, reliability, matey, and recoverability in many different ways t' ensure t' goals o' t' project are met. These include:

• No clusterin' or stagin' was used, t' reduce t' risk o' failure.
• T' weight o' t' rocket ensures that t' rocket will nay go supersonic.
• T' rocket is launched at a 0º angle.
• Dual ejection charge circuits for both booster and payload sections.
• Through-the-wall fin design is used.
• Multiple internal fillets are used.
• Fiberglass coverin' increases t' strength and reduces t' chance of structural failure.
• Only closed eyebolts are used in t' recovery design t' increase strength.
• No elastic shock cord is used. Arrr! Ya scallywag! Only nylon rope for t' recovery system is used.
• Booster parachute is attached t' all-threads that extend t' t' fins and motor mount.
• All-threads extend through t' payload section t' secure t' payloads to the recovery parachute.
• Both parachutes use a piece o' nomex® for protection from t' ejection charge.
• A deployment bag is used t' reduce t' shock t' t' rocket when the parachute opens.

Payload Design Considerations

Camera Compartment

T' camera compartment is located in t' payload section immediately above the booster but below t' reducer. Avast, me proud beauty! Photo 7 shows details o' t' payload section. Well, blow me down! All plates are made from ½ inch thick oak plywood and thar are ¼ inch holes drilled through each plate for all-thread t' connect the entire assembly together and t' t' T-nuts in t' plates on t' bottom o' the reducer.

Cameras 1 through 8

T' top part o' t' payload section is for cameras 1 through 8. Aye aye! Arrr! Two layers hold 4 cameras at 90º t' each other and then t' layers are skewed 45º t' each other. Begad! Avast, me proud beauty! T' design needed t' hold t' cameras at the appropriate angle is simple yet challenging. Avast, me proud beauty! Arrr! T' back o' each camera rests next to a ¼ inch piece o' plywood that has a 1/16th inch thick piece o' foam paddin' attached t' it. Avast! In front o' t' camera is a vertical piece o' 3/16th inch wooden dowel rod that passes betwixt t' two plates. Begad! T' paddin' and the dowel rod provide a nice friction fit used t' hold t' camera at one end. Arrr! Avast, me hearties, me proud beauty! The other end o' t' camera is held secured by a ¾ inch long ¼ - 20 flat-head screw from t' bottom o' t' plate. Avast! This design is challengin' since the four cameras had t' be mounted at 90º t' each other inside o' a 7-½ inch body tube. T' clearance betwixt each camera is about ¼ inch.

Electronics Compartment

Below t' point and shoot cameras be t' timin' circuit and t' ejection charge circuits compartment. Begad! One cross member is made from ¼ inch plywood and t' other is from ½ inch oak plywood. Blimey! Avast, me proud beauty! On both sides o' t' ½ inch plates are 1/8th inch thick fiberglass pieces epoxied t' t' plate t' reinforce where t' all-thread bolts them together.

Cameras 9 and 10

Below t' electronics is the compartment for cameras 9 and 10. Begad! Begad! Due t' t' size o' t' two SLR cameras, four smaller supports are used t' connect this section t' t' rest o' t' payload section. T' install a camera t' lens o' t' camera must be removed and the camera is slid into its holder and then t' lens reinstalled. Well, blow me down! Begad! T' angle of cameras 9 or 10 is 40º, arrr, versus 45º from t' axis o' t' all-threads like t' point and shoot cameras. Avast, me proud beauty! Avast, ya bilge rat, me proud beauty! T' cameras are secured by a ¾ inch ¼ - 20 flat-head screw from t' bottom o' t' plate.

Camera 11

T' coupler is at t' bottom o' t' payload section that holds camera 11. This coupler be t' structural support for t' payload section in t' booster. It is reinforced by epoxyin' another coupler inside t' original coupler. Six ½ inch thick oak strips run t' length o' t' coupler. Arrr! This double wall design and t' reinforcement strips are necessary for strength and t' protect the payload section upon landing. Blimey! Well, blow me down! This coupler also contains t' switches used to control t' cameras. Blimey! Camera 11 is mounted lens down, matey, lookin' into the booster. Aye aye!

Cowling

Photo 8 shows t' cowlin' that is used t' protect t' mirrors on t' outside of t' body o' t' rocket. T' angle o' t' mirror is 50.5º t' achieve the desired angle o' view. Ahoy! T' frame o' t' cowlin' is constructed from 3/16th inch thick plywood with a ½ inch thick, oak plywood "backbone" that is used t' achieve t' proper angle for t' mirror. Begad! Avast, me bucko, me proud beauty! This frame is covered with a ½ section o' 3" body tube. Blimey! Blimey! T' two sides o' t' cowlin' are also constructed from 3/16th inch thick plywood. Ahoy! On top these sides is a triangular piece o' ¼ inch balsa where t' foam cone is epoxied. Avast! T' cowlin' is also filled with expandin' foam before a solid wood nose cone is attached. Ya scallywag! Arrr! The entire cowin' is covered with 3 ounce fiberglass and epoxy. Ya scallywag! T' first surface mirror is attached t' t' angled plate by silicon glue.

Choice of Payloads

Once t' desired photographs have been defined, what be t' best choice for the camera payload? I have written articles (HPR November 1997) about t' best choice o' cameras that should be used for rocket photography. Aye aye! By far t' most important feature o' a camera needed t' get great shots be t' shutter speed. T' cameras (Photo 9) were chosen for their fastest shutter speed and their adaptability for rocket flight. All electrical connections, battery and film doors, and t' lens (SLR's) are taped t' prevent inadvertent "mishaps" preventin' t' cameras from takin' pictures when they are supposed to. Well, blow me down! Avast!

Cameras 1 through 8

T' eight point and shoot cameras are the Olympus® Stylus Epic. It is an ultra compact camera with a top shutter speed of 1/1000th second and a very fast 35-mm f2.8 lens. Avast, me proud beauty! Ya scallywag! Its film advance rate is slow, only one picture every 3 seconds, shiver me timbers, but that is nay a problem for its purpose. T' cameras take a picture every 5 seconds and t' descent rate is about 15 feet per second. That means a picture is taken every 75 feet in altitude during descent on t' parachute. Begad! Since t' horizontal field o' view o' t' cameras is 54.4°, thar be a 9.4° overlap o' t' pictures. Arrr! T' film is Kodak® Royal Gold 100 ASA that has t' DX codin' changed t' 400 ASA. Pushin' t' film ensures t' camera has its automatic settings set t' the fastest shutter speed but still does nay degrade t' quality o' the photographs.

Cameras 9 through 11

T' choice for t' three SLR cameras (cameras 9-11) is the Minolta® Maxxum 7000 camera. Blimey! It has a 1/2000th second maximum shutter speed, which is necessary t' freeze t' rapidly changin' image. Well, matey, blow me down! T' aperture is set dependin' on lightin' conditions at t' time o' launch. Also, this camera has an external connection t' trip t' shutter, which makes connectin' t' camera to t' timin' circuit easy. Ya scallywag! Begad! Although it is an automatic camera with auto focus, it is set t' manual exposure and manual focus for reliability. Arrr! Focus will be set t' infinity. Aye aye! These cameras are set t' shoot in continuous mode at 2 frames per second. T' only time that these cameras actually shoot in continuous mode is at booster separation. Avast, me proud beauty! For all other photographs t' relays that controls these cameras are nay closed long enough for more than one picture t' be taken.

T' two cameras lookin' down t' side o' t' rocket, cameras 9 and 10, ya bilge rat, have a 50-mm f1.7 lenses and use Kodak® Royal Gold 100 ASA film. Well, blow me down! T' camera at the bottom o' t' payload section, shiver me timbers, camera 11, has a 28-mm f2.8 lens and uses Kodak® Royal Gold 25 ASA film. Begad! Ahoy! T' lenses and choice o' film were selected for their angle-of-view and depth o' field characteristics. Slow film speed is used for t' smaller grain size, shiver me timbers, for better quality photographs.

Ejection Circuits

Although nay a true payload, t' ejection circuits are used for specific features that each one has. Well, blow me down! T' Adept® PST941 timer is a high current timer even though it ignites a low current electric match. Blimey! Avast, me proud beauty! Its timin' resolution is 0.1 second with a maximum delay o' 25.5 seconds. Avast! Avast, me proud beauty! T' timer is used as the primary ejection circuit t' have an accurate delay betwixt t' booster separation and t' payload separation.

An altimeter is used as a backup ejection circuit t' deploy t' parachutes at apogee regardless o' when that occurs. Begad! T' Black Sky® ALTACC recording altimeter is used since it records both barometric pressure altitude and it measures acceleration from which altitude can be calculated. Begad! Aye aye! Another feature of the ALTACC is that it records data for over four minutes. Begad! This may seem excessive for a flight that lasts about 20 seconds t' apogee, but t' data is used t' accurately measure t' descent rate and t' determine t' altitude the photographs are taken at.

SUCCESSFUL LEVEL 3 FLIGHT!

July 30, me bucko, 1999
LDRS 18
Rocket - Scratch My Mind's Eye
Weight - 110 lbs
Motor - Aerotech M1939
Altitude - ~3700 feet

T' Flight

With family and friends comin' in from out o' state just t' watch me flight I was a little pressured t' fly at a particular date. Begad! Months in advance I chose to fly on Friday at LDRS t' minimize their time lost from work and t' allow me enough time t' drive back across country. Aye aye! Arrr! It would have been a very long drive if I wasn't bringin' back lots o' exposed film and a very large rocket intact.

As t' launch date approached, me hearties, t' forecast was for increasin' winds. Begad! I knew I had better launch early. Well, blow me down! I set up t' pad t' night before and t' payload was prepped before I even arrived at LDRS. With t' few finishin' touches completed we started t' load t' rocket onto t' pad. But I still had t' turn on 11 cameras, ya bilge rat, activate 4 ejection circuits, and t' camera timin' circuit all while standin' on a ladder that be too short and with winds that were too gusty.

Darren Owens had t' same idea about flyin' his Fat Boy early, ya bilge rat, ya bilge rat, but he was ready t' go. Begad! Arrr! We paused while he launched and he had a very nice flight but the weather cockin' be severe, and t' Fat Boy be marginally stable. Ahoy! Now it was my turn with an over-stable rocket! T' launch pad paid off. Begad! It was designed to support 100% o' t' weight o' t' rocket without t' rail attached. Arrr! Avast, shiver me timbers, me proud beauty! T' M1939 lifted t' rocket smartly with only a slight arc over t' crowd (Photo 10). Begad! Well, me hearties, blow me down! I couldn't have asked for a better trajectory since t' winds would carry the camera payloads back over t' crowds.

I started breathin' again when I saw both chutes carryin' me rocket safely back t' Earth. Arrr! Removin' t' cameras indicated that one o' t' eight point shoot cameras failed t' take pictures. Aye aye! Since four were activated by a single relay I must have failed t' completely open t' cover t' turn on t' camera. Aye aye! However, I knew I would be still gettin' over 360 photographs.

Analyzin' t' altimeter data and photographs did indicate a few glitches. Instead o' t' booster separatin' a few seconds early while it is still nearly vertical, matey, it be right at apogee with t' rocket horizontal t' t' ground. Aye aye! Blimey! Also the mirrors were nay tested prior t' flight and it turned out that they were not at t' desired angle. Instead o' havin' overlappin' pictures, ya bilge rat, thar be a gap betwixt them! Blimey! Along with one o' t' cameras nay working, shiver me timbers, I did nay get exactly t' photographs that I wanted. But I was nay too disappointed. Blimey! Well, blow me down! Blimey! Several shots came out very nice. I received me level 3 certification, and got back all the cameras and t' rocket.

Overall it was a good day. Blimey! Blimey! Avast, me proud beauty! Blimey!