Unique

Unique (pronounced yoo-neek)

(1) Existing as the only one or as the sole example; single; solitary in type or characteristics; the embodiment of unique characteristics; the only specimen of a given kind.

(2) Having no like or equal; unparalleled; incomparable.

(3) Limited in occurrence to a given class, situation, or area.

(4) Limited to a single outcome or result; without alternative possibilities:

(5) Not typical; unusual (modern non-standard (ie incorrect) English).

1595-1605: From the sixteenth century French unique, from the Latin ūnicus (unparalleled, only, single, sole, alone of its kind), from ūnus (one), from the primitive Indo-European root oi-no- (one, unique).  The meaning "forming the only one of its kind" is attested from the 1610s; erroneous sense of "remarkable, uncommon" is attested from the mid-nineteenth and lives on in the common errors “more unique” and “very unique” although etymologists are more forgiving of “quite unique”, a favorite of the antique business where it seems to be used to emphasize the quality of exquisiteness.  Unique is a noun & adjective, uniqueness, uniquity & unicity are nouns and uniquely is an adverb; the (rare) noun plural is uniques.  The comparative uniquer and the superlative uniquest are treated usually as proscribed forms which should be used only with some sense of irony but technically, while the preferred "more unique" and "most unique" might sound better, the structural objection is the same.

The Triumph Stag and its unique, ghastly engine

There was a little girl by Henry Wadsworth Longfellow (1807–1882)

There was a little girl,
And she had a little curl
Right in the middle of her forehead.
When she was good
She was very, very good,
And when she was bad she was horrid.

The V8 engine Triumph built for the Stag between 1970-1978 was a piece of machinery not quite uniquely horrid but so bad it remained, most unusually for such an engine, unique to the Stag.  The only other post-war V8 engine to be produced in any volume which was used in a single model was the Fiat 8V (1952-1954) though with a run of 114 it was hardly mass produced.  The Ford Boss 429 (1969-1970) was only ever used in the Mustang (apart from two Mercury Cougars built for drag racing) but it was a variant of the 385 series engines (370-429-460) rather than something genuinely unique.  More common have been V8s which never actually appeared in any production car such as Ford's 427 SOHC (a variant of the FE/FT family (332-352-360-361-390-406-410-427-428; 1957-1976)) or the Martin V8, designed by Ted Martin (1922-2010) initially for racing but briefly envisaged for the French Monica luxury car project (1971-1975) until a sense of reality prevailed.  What is unique about the Triumph 3.0 V8 is that it's the one produced in the greatest volume which was used in only one model.

The Triumph 3.0 V8.

Engine schematic. 

Problem 1: Some strange decisions were taken by British Leyland and many associated with the Stag’s engine are among the dopiest.  The engineering strategy was to create a family of engines of different size around common components which would enable the development of four, six and eight cylinder units with capacities between 1.5-4 litres, (75-245 cubic inches), the part-sharing offering some compelling economies of scale.  Done properly, as many have often done, it’s sound practice to create a V8 by joining two four-cylinder units but it’s unwise to using exactly the same bottom-end components for both.  Strictly speaking, because the V8 came first, the subsequent fours were actually half a V8 rather than vice-versa but the fact remains the bottom-end construction was more suited to the smaller mill; the bearings were simply too small.

Stagnant.  Blockages and corrosion by chemical reaction.

Problem 2: A second cause of engine trouble was the choice of materials. The block was made from iron and the heads from aluminum, a common enough practice even then but a combination new to Triumph owners and one demanding the year-round use of corrosion-inhibiting antifreeze, a point not widely appreciated even by the somewhat chaotic dealer network supporting them.  Consequently, in engines where only water was used as a coolant, the thermite reaction between iron and aluminum caused corrosion where the material were joined, metallic debris coming lose which was distributed inside the engine; the holes formed in the heads causing gaskets to fail, coolant and petrol mixing with lubricating oil.

Problem 3. The engine used a long, single row, roller-link timing chain which would soon stretch, causing the timing between the pistons (made of a soft metal) and the valves (made of a hard mental) to become unsynchronized.  There are “non-interference” engines where this is a nuisance because it causes things to run badly and “interference” engines where the results can be catastrophic because, at high speed, valves crash into pistons.  The Stag used an “interference” engine.

Engine schematic.  Note the angles of the head-studs.

Problem 4: There was a bizarre arrangement of cylinder head fixing studs, half of which were vertical in an orthodox arrangement while the other half sat at an angle. The angled studs, made from a high-tensile steel, were of course subject to heating and cooling and expanded and contracted at a different rate to the aluminum cylinder heads, the differential causing premature failure of the head gaskets.  It must have seemed a good idea at the time, the rationale being it made possible the replacement of the head gaskets without the need to remove the camshafts and re-set the valves and that is a time-consuming and therefore expensive business so the intention was fine but defeated by physics which should have been anticipated.  Nor did the thermal dynamics damage only head gaskets, it also warped the aluminum heads, the straight studs heating differently than the longer splayed studs which imposed the side loads that promoted warping.  As a final adding of insult to injury, the long steel studs had a propensity solidly to fuse with the aluminum head and, because they sat at dissimilar angles, it wasn’t possible simply to saw or grind the top off the offending bolt and pull of the head.

Problem 5: The head failures would have been a good deal less prevalent had the company management acquiesced to the engineers’ request to use the more expensive head gaskets made of a material suited to maintaining a seal between surfaces of iron and aluminum.  For cost reasons, the request was denied.

Stag engine bay.

Problem 6: Despite the under-hood space being generous, instead following the usual practice of being mounted low and belt-driven, at the front of the engine, the water pump was located high, in the valley between the heads and was gear driven off a jackshaft.  This, combined with the location of the header tank through which coolant was added, made an engine which had suffered only a small loss of coolant susceptible to over-heating which, if undetected, could soon cause catastrophic engine failure, warped cylinder heads not uncommon.  Because, when on level ground, the water pump sat higher than the coolant filling cap, unless the car was parked at an acute angle, it wasn’t possible to fill the system with enough fluid actually to reach the water pump.    It seems a strange decision for a engineer to make and the original design blueprints show a belt-driven water pump mounted in a conventional manner at the front of the block.

It transpired that Saab, which had agreed to purchase a four cylinder derivative of the modular family, had to turn the slant four through 180^o because, in their front-wheel-drive 99, the transmission needed to sit at the front and, space in the Swedish car being tight, there would be no room between block and bulkhead for a water pump and pulley to fit.  So, dictated by necessity, the pump ended up atop the block, suiting both orientations and driven by the same shaft that drove the distributor and oil pump (and would have driven the mechanical metering unit for the abortive fuel injection).  Aside from the issues with coolant, the drive mechanism for the pump brought problems of its own, the early ones proving fragile.  As if the problems inherent weren’t enough, Triumph made their detection harder, locating the coolant temperature sender in one of the cylinder heads.  On the modular fours, with one head, that would be fine but the Stag’s two heads didn’t warp or otherwise fail in unison.  One head could be suffering potentially catastrophic overheating yet, because the sensor was in the as yet unaffected other, the temperature gauge would continue to indicate a normal operating level.  That’s the reason just about every fluid-cooled engine with multiple heads has the sender placed in the water pump.  To compound the problem, the four and eight used the same specification water pump, which, while more than adequate for the former, should have be uprated for the latter.

Problem 7: This was the eventually nationalized British Leyland of the 1970s, a case study, inter alia, in poor management and ineptitude in industrial relations.  Although the pre-production engines were cast by an outside foundry and performed close to faultlessly in durability-testing, those fitted to production cars were made in house by British Leyland in a plant troubled by industrial unrest.  Quality control was appalling bad, lax manufacturing standards left casting sands in the blocks which were sent for the internal components to be fitted and head gaskets were sometimes fitted in a way which restricted coolant flow and led to overheating.

Michelotti show car, 1966.

It was a pity because but for the engine, the Stag proved, by the standards of the time, relatively trouble-free, even the often derided Lucas electrical equipment well behaved.  The story began in 1965 when Italian designer Giovanni Michelotti (1921–1980) had requested a Triumph 2000 sedan, a model he’d styled and which had been on sale since 1963.  Michelotti intended to create a one-off convertible as a promotional vehicle to display at the 1966 Geneva Motor Show and Triumph agreed, subject to the company being granted first refusal on production rights and, if accepted, it would not appear at the show.  The donor car sent to Turin was a 1964 saloon which, prior to being used as a factory hack, had been one of the support vehicles for Triumph’s 1965 Le Mans campaign with the Spitfire.  Driven to Italy for Michelotti to cut and shape, the result so delighted Triumph they immediate purchased the production rights and the Stag was born.  Briefly called TR6, the Stag name was chosen, somewhat at random, as the original project code but was retained when it was preferred to all the suggested alternatives; unlike the engine, the name was right from day one.

Michelotti pre-production styling sketch, 1967.

The styling too turned out to be just about spot-on.  The partially concealed headlights, then a fashionable trick many US manufacturers had adopted, was thought potentially troublesome and abandoned but the lines were substantially unchanged between prototype and production.  There was one exception of course and that was the most distinctive feature, the B-pillar mounted loop which connected to the centre of windscreen frame, creating a T-section.  This wasn’t added because of fears the US Congress was going to pass legislation about roll-over protection; that would come later and see European manufacturers produce a rash of “targas”, a kind of roll-bar integrated into the styling as a semi-roof structure but Triumph’s adaptation was out of structural necessity.  Based on a sedan which had a permanent roof to guarantee structural integrity, Michelotti’s prototype had been a styling exercise and no attempt had been made to adapt the engineering to the standards required for production.  Although the platform had be shortened, a sedan with its roof cut of is going to flex and flex it did, shaking somewhat if driven even at slow speeds in a straight line on smooth surfaces; with any change to any of those conditions, vibration and twisting became much worse.  The T-top not only restored structural integrity but was so well-designed and solidly built the Stag’s torsional stiffness was actually better than the sedan.

Given the platform and styling was essentially finished at the beginning, the initial plan the Stag would be ready for release within two years didn’t seem unreasonable but it took twice that long.  Perhaps predictably, it was the engine which was responsible for much of the delay, combined with the turmoil and financial uncertainty of a corporate re-structure.  Triumph had since 1960 been part of the highly profitable bus and truck manufacturer, Leyland and until 1968 enjoyed much success as their car-making division.  However, in 1968, under some degree of government coercion, a large conglomerate was formed as British Leyland (BL) and Triumph was absorbed into BL's Specialist Division as a stable-mate to Rover and Jaguar-Daimler.

Daimler 2.5 V8.

What became the engine imbroglio was interlinked with the merger.  The coming together meant BL now had on the books, in development or production, one V12 engine and five V8s, an indulgence unlikely to survive any corporate review.  Jaguar-Daimler, the most substantially (semi-) independent entity within the conglomerate, were adamant about the importance of the twelve to their new model ranges and the point of differentiation it would provide in the vital US market.  They were notably less emphatic about their V8s.  Within the company, there had long been a feeling Jaguars should have either six or twelve cylinders, any V8 a lumpy compromise for which there’d never been much enthusiasm.  Additionally, the Jaguar was more of a compromise than most.  Based on the V12 it was thus in a 60^o configuration and so inherently harder to balance than a V8 using an orthodox 90^o layout.  Development had been minimal and Jaguar was happy to sacrifice the project, doubtlessly the correct decision.

1961 Jaguar Mark X.

Less inspired was to allow the anti-V8 feeling to doom the hemi-head Daimler V8s.  Built in 2½ litre (2,548 cm³ (155 cubic inch)) and 4½ litre (4,561 cm³ (278 cubic inch)) displacement, both were among the best engines of the era, light, compact and powerful, they were noted also for their splendid exhaust notes, the only aspect in which the unfortunate Stag engine would prove their match.  Jaguar acquired both after merging with (ie taking over) Daimler in 1960 and created a popular (and very profitable) niche model using the smaller version but the 4½ litre was only ever used in low volume limousines, barely two-thousand of which were built in a decade.  Both however showed their mettle, the 2.5 comfortably out-performing Jaguars 2.4 XK-six in the same car and almost matching the 3.4, all to the accompaniment of that glorious exhaust note.  The 4.6 too proved itself in testing.  When, in 1962, engineers replaced the 3.8 XK-six in Jaguar’s new Mark X with a 4.6, it was six seconds quicker to 100 mph (162 km/h) and added more than 10 mph (16 km/h) to an already impressive top speed of 120 mph (195 km/h).  The engineers could see the potential, especially in the US market where the engines in the Mark X’s competition was routinely now between six-seven litres (365-430 cubic inches) and increasingly being called upon to drive power-sapping accessories such as air-conditioning.  As Mercedes-Benz too would soon note, in the US, gusty sixes were becoming technologically bankrupt.  The engineers looked at the 4.6 and concluded improvements could be made to the cylinder heads and the design would accommodate capacity increases well beyond five litres (305 cubic inches); they were confident a bigger version would be a natural fit for the American market.

Internal discussion paper for Jaguar XK-V8 engine, Coventry, UK, 1949.

Curiously, it could have happened a decade earlier because, during development of the XK-six, a four cylinder version was developed and prototypes built, the intent being to emulate the company’s pre-war practice when (then known as SS Cars) a range of fours and sixes were offered.  This continued in the early post-war years while the XK was being prepared and the idea of modularity appealed; making fours into sixes would become a common English practice but Jaguar flirted also with an XK-eight.  While the days of straight-eights were nearly done, trends in the US market clearly suggested others might follow Ford and offer mass-market V8s so, in 1949, a document was circulated with preliminary thoughts outlining the specification of a 4½ litre 90^o V8 using many of the XK-four’s components including a pair of the heads.  There things seemed to have ended, both four and eight doomed by the success and adaptability of the XK-six and there's never been anything to suggest the XK-eight reached even the drawing-board.  Work on the prototype four did continue until the early 1950s, the intention being to offer a smaller car which would fill the huge gap in the range between the XK-120 and the big Mark VII saloon but so quickly did the XK-six come to define what a Jaguar was that it was realized a four would no longer suit the market.  Instead, for the small car, a small (short) block XK-six was developed, initially in two litre form and later enlarged for introduction as the 2.4; with this, the XK-four was officially cancelled by which time the flirtation with the eight had probably already been forgotten.  For decades thereafter, Jaguar would prefer to think in multiples of six and, having missed the chance in the 1960s to co-op the Daimler 4.6, it wouldn’t be for another thirty years that a V8 of four-odd litres would appear in one of their cars.

1954 prototype Jaguar 9 litre military V8.

That didn't mean in the intervening years Jaguar didn't build any V8s.  In the early 1950s, while fulfilling a contract with the Ministry of Supply to manufacture sets of spares for the Rolls-Royce Meteor mark IVB engines (a version of the wartime Merlin V12 made famous in Spitfires and other aircraft) used in the army's tanks, Jaguar was invited to produce for evaluation a number of V8s of "approximately 8 litres (488 cubic inches)".  Intended as a general purpose engine for military applications such as light tanks, armored cars and trucks, what Jaguar delivered was a 9 litre (549 cubic inches), 90^o V8 with double overhead camshafts (DOHC), four valves per cylinder and a sealed electrical system (distributors and ignition) to permit underwater operation, thereby making the units suitable also for marine use.  With an almost square configuration (the bore & stroke was 114.3 x 110 mm (4.5 x 4.33 inches)), the naturally aspirated engine exceeded the requested output, yielding 320 bhp (240 kw) at 3750 rpm and either five or six were delivered to the ministry for the army to test.  From that point, it's a mystery, neither the military, the government nor Jaguar having any record of the outcome of the trials which apparently didn't proceed beyond 1956 or 1957; certainly no orders were placed and the project was terminated.  At least one one of the V8s survived, purchased in an army surplus sale it was as late as the 1990s being used in the barbaric-sounding sport of "tractor-pulling".  Later, Jaguar enjoyed more success with the military, the army for some years using a version of the 4.2 litre XK-six in their tracked armored reconnaissance vehicles, the specification similar to that used when installed in the Dennis D600 fire engine.             

Jaguar V12 in 1973 XJ12.

Jaguar’s management vetoed production of the Daimler 4.6 on the grounds (1) there was not the capacity to increase production to what be required for the volume of sales Jaguar hoped the Mark X would achieve and (2) the Mark X would need significant modifications to permit installation of the V8.  Given that Daimler’s production facilities had no difficulty dramatically increasing production of the 2.5 when it was used in the smaller saloon body and a number of specialists have subsequently noted how easy it was to fit some very big units into the Mark X’s commodious engine bay, it’s little wonder there’s always been the suspicion the anti-V8 prejudice may have played a part.  Whatever the reasons, the decision was made instead to enlarge the XK-six to 4.2 litres and missed was the opportunity for Jaguar to offer a large V8-powered car at least competitive with and in some ways superior to the big Americans.  The Mark X (later re-named 420G) was not the hoped-for success, sales never more than modest even in its early days and in decline until its demise in 1970 by which time production had slowed to a trickle.  It was a shame for a design which was so advanced and had so much potential for the US market and had the V8 been used or had the V12 been available by the mid-1960s, things could have been different.  The unfortunate reputation the twelve later gained was because of lax standards in the production process, not any fragility in the design which was fundamentally sound and it would have been a natural fit in the Mark X.  So the Daimler 4.6 remained briefly in small-scale production for the limousines and the 2.5 enjoyed a successful run as an exclusive model under the hood of the smallest Jaguar, a life which would extend until 1969.  Unfortunately, the powerful, torquey, compact and robust 2.5, which could easily have been enlarged to three litres, wasn’t used in the Stag.  More helpfully, even if capacity had been limited to 2.8 litres (170 cubic inches) to take advantage of the lower taxation rates applied in Europe, the Daimler V8 would have been more than equal to the task.

Fuel-injected 2.5 litre Triumph six in 1968 Triumph TR5.

The six was essentially an enlarged version of the earlier four.   Released also in 1.6 & 2.0 capacities and used in the 2000/2500, Vitesse, GT6 & TR5/6, the fuel-injection was adopted only for the some of the non-US market sports cars and the short-lived 2.5 PI saloon.  Because of the reliance on the US market, TVR, which used the engine in the 2500M, in all markets, offered only the twin-carburetor version certified for US sale in the TR-250).

Triumph tried using the fuel-injected 2.5 litre straight-six already in development for the TR5 (TR-250 in North America) but the rorty six was a sports car engine unsuited to the grand tourer Triumph intended the Stag to be and thus was born the 2.5 litre V8, part of a modular family.  Another innovation was that the V8 would use the Lucas mechanical fuel-injection adopted for the long-stroke six and this at a time when relatively few Mercedes-Benz were so equipped.  However, while the power output met the design objectives, it lacked the torque needed in a car of this nature, and the high-revving nature wasn’t suited to a vehicle intended to appeal to the US market where it was likely often to be equipped both with air-conditioning and automatic transmission; the decision was taken to increase capacity to three litres.  Because the quest was for more torque, it might be thought it would be preferred to lengthen the stroke but, for reasons of cost related to the modularity project, it was decided instead to increase the bore to a very over-square 86.00 x 64.50 mm (3.39 x 2.52 inches).  Despite this, the additional half-litre delivered the desired torque but the coolant passages remained the same so an engine with a capacity twenty percent larger and an increased swept volume, still used the already hardly generous internal cooling capacity of the 2.5.  It was another straw on the camel’s back.

It was also another delay and, within Leyland, questions were being raised about why a long and expensive programme was continuing to develop something which, on paper, appeared essentially to duplicate what Leyland then had in production: Rover’s version of the small-block Buick V8 which they’d much improved after buying the rights and tooling from General Motors.  Already used to much acclaim in their P5B and P6 saloons, it would remain in production for decades.  The Rover V8 did seem an obvious choice and quite why it wasn’t adopted still isn’t entirely certain.  One story is that the Triumph development team told Rover’s chief engineer, by then in charge of the Stag project, that the design changes associated with their V8 were by then so advanced that the Rover V8 “wouldn’t fit”.  While it seems strange an engineer might believe one small V8 wouldn’t fit into a relatively large engine bay which already housed another small V8, he would later admit that believe them he did.

Tight fit: Ford 289 (4.7) V8 in 1967 Sunbeam Tiger Mark II.  A small hatch was added to the firewall so one otherwise inaccessible spark plug could be changed from inside the cabin.

It actually wasn’t a wholly unreasonable proposition because to substitute one engine for another of similar size isn’t of necessity simple, things like cross-members and sump shapes sometimes rendering the task impossible, even while lots of spare space looms elsewhere and a similar thing had recently happened.  In 1967, after taking control of Sunbeam, Chrysler had intended to continue production of the Tiger, then powered by the 289 cubic inch (4.7 litre) Windsor V8 bought from Ford but with Chrysler’s 273 cubic inch (4.4 litre) LA V8 substituted.  Unfortunately, while 4.7 Ford litres filled it to the brim, 4.4 Chrysler litres overflowed.  Allowing it to remain in production until the stock of already purchased Ford engines had been exhausted, Chrysler instead changed the advertising from emphasizing the “…mighty Ford V8 power plant” to the correct but less revealing “…an American V-8 power train”.

Triumph Stag.

It may have been, in those perhaps kinder times, one engineer would believe another.  However, years later, a wrinkle was added to the story when, in an interview, one of the development team claimed what was said was that they felt the Rover V8 was “not a fit” for the Stag, not that “it wouldn’t fit”, an amusing piece of sophistry by which, it was said, they meant the characteristics of the engine weren't those required for the Stag.  That may have been being economical with the truth: any engineer looking at the specifications of the Rover unit would have understood it was highly adaptable and so for decades it proved to be, powering everything from the Land Rover to executive saloons and high-performance sports cars.

More plausible an explanation was competing economics.  Triumph was projecting a volume of between twelve and twenty-thousand a year for the Stag and, within the existing production facilities Rover could not have satisfied the demand in addition to their own expanding range, soon to include the Range Rover, added to which, an agreement had been reached to supply Morgan with engines for the +8 which would revitalize their fortunes.  The Morgan deal was for a relatively small volume but it was lucrative and the success of the +8 was already encouraging interest from other manufacturers.  So, with Triumph already in the throes of gearing up to produce their modular engines and Rover said to be unable to increase production without a large capital investment in plant and equipment, the fateful decision to use the Triumph engine was taken.

This was the critical point, yet even then it wasn’t too late.  Although Jaguar were emphatic about shutting down Daimler’s V8 lines and converting the factories to XJ6 production, it would have been possible to move the tooling and resume building a 2.5, 2.8 or 3.0 Daimler V8 for the Stag.  Rover had found managing a shift of some tooling across the Atlantic not too onerous a task so trucking stuff a few miles down the road should have been possible.  Ironically, Triumph argued their OHC V8 was a more modern thing than the then decade-old pushrod Daimler which, they suggested, wouldn’t be able to be adapted to upcoming US emission regulations and thus would have a short life.  Given the success of many in coaxing pushrod V8s through decades of US regulations, that probably wasn’t true but it had all become irrelevant; the decision had been taken to pursue Triumph’s modular option.  At least a decision had been taken that was final, unlike some British Leyland decisions of the era but it did mean the Stag’s introduction was further delayed.

1973 Stag.

Eventually, the Stag was launched in the summer of 1970 to a positive if not rapturous reception.  There was criticism of weight of the hardtop and the fabric roof not being as easy to us as the brochure suggested but most contemporary journalists seemed to enjoy the drive although some were disappointed with the lack of power; the wonderful exhaust note and rakish lines perhaps promising more but this was a relatively heavy four-seat grand tourer, not a sports-car.  Still, it would touch 120 mph (190 km/h) and its acceleration, brakes and handling were all at least comparable to the competition and, among that completion, it was close to unique.  A small-capacity V8, four-seat convertible with a choice of manual or automatic transmissions and all-independent suspension was a tempting specification in 1970; to get the same thing from Mercedes-Benz would cost more than three times as much.  Of course Stuttgart would probably have suggested their buyers got something more than three times as good, a not unreasonable point at the time and, given the prices at which 280SE 3.5 cabriolets now trade, the Germans appear to have been conservative in their three-fold estimate.  But it was value for money and had some nice touches, a heated rear window when that was a novelty in removable hard tops, a clever (and influential) multi-function display of warning lights and even, though curiously discordant, the option of wire wheels.

1974 Stag interior (manual o/d).

All concluded that driving one was a pleasant, if not especially rapid, experience but owning a Stag proved frequently nightmarish, all because of that unique engine.  Before many months had elapsed it was clear there were problems and, despite years of fixes and adjustments, the inherent design faults proved just too embedded in the mechanical DNA.  A change to the Rover V8 might, even then been the answer for the Stag otherwise suffered from little but by the early 1970s, Leyland was in dire financial straits, chronically under-capitalized and without any appetite to invest in a small volume product with an uncertain future.  Perhaps the earlier failure by Facel Vega to rescue the doomed Facellia by replacing the interesting but fragile French engine with a dreary but reliable Volvo unit played on their minds.  An upgraded automatic transmission, improvements to the cooling system and other detail changes to the engine were pursued and even an inconspicuous re-style was thought to warrant a “Mark 2” tag but the reputation never recovered.

Quixotic derivations were built but never pursued.  There were a couple of clumsy-looking prototype GT6-esque hatchbacks which excited little interest and in 1972 Ferguson Research adapted two using their all-wheel-drive and anti-lock brake systems made famous on the Jensen FF; said to work most effectively, both still exist in private hands but there's nothing to suggest even limited production was ever contemplated.  In seven years, 25,877 Stags were built, 6,780 of which were exported but only 2,871 Americans were persuaded, a disappointment in a market of which much had been hoped.

End of the line: 1978 Triumph Stag.

The Stag however has enjoyed an extraordinary afterlife for something once thought a fragile failure.  Seduced by the style, the surprising practicality and the intoxicating burble of the exhaust, the survival rate has been high and most still run the Triumph V8 rather than the Rover V8, Ford V6 or any of the small-block Detroit V8s to which not a few owners once resorted.  Modern additions improve the experience too, five speed manual transmissions have been fitted, mostly to cars not equipped with the desirable overdrive and there's a popular and well-executed conversion to a four-speed ZF automatic which many describe as transformative.  There can be few engines which have for so long inspired owners to devote so much energy to rectifying the defects the factory never fixed.  High strength timing chains, external water pumps, improved radiators, better bearings and (the once rejected) correct head gaskets are now available, the consensus being that properly sorted and maintained by the book, it’s a solid, reliable engine, just not one which can be tolerate the sort of neglect Detroit's V8s of the time famously would endure with little complaint.

Very

Very (pronounced ver-ee)

(1) In a high degree; extremely; exceedingly (used as an intensive emphasizing superlatives or stressing identity or oppositeness).

(2) Actual, precise; particular.

(3) Mere (in certain contexts) or sheer; utter (depending on context).

(4) Being such in the true or fullest sense of the term; extreme.

(5) True; genuine; worthy of being called such; rightful or legitimate.

(6) Pure, simple, plain.

1200–50: From the Middle English verray & verrai (true, real, genuine (and in the fourteenth century "actual, sheer")), from the Anglo-French verrai, from the Old French verai (true, truthful, sincere; right, just, legal) (from which French gained vrai), from the (assumed) Vulgar Latin vērācus, an alteration of the Classical Latin vērāx (genitive veracis) (truthful) from vērus (true (and source of the Italian vero)); the construct of vērāx was vēr(us) (true (and cognate with the Old English wǣr & the German wahr (true, correct)) + -āx (the adjectival suffix).  The ultimate source was the primitive Indo-European weh- (true, benevolent), source also of the Old English wǣr (true, correct), the Dutch waar (true), the German wahr (true) and the Icelandic alvöru (earnest).  It displaced the native Middle English sore & sār (very), from the Old English sār (grievous, extreme) which was related to the German sehr, the Dutch zeer, the Middle English wel (very (from the Old English wel (well, very)).  Other links include the German wohl, the Dutch wel, the Swedish väl, and the Middle English swith (quickly; very), from the Old English swīþe (very).  Very is an adverb & adjective and the adjectival forms verier & veriest are obsolete.  The adverb verily is effectively obsolete except for ecclesiastical use where if remains familiar in ritualistic phrases such as “verily I say unto you”.

Circa 1914 Webley & Scott Mark 1 British Royal Flying Corps (RFC) Very Pistol, brass frame with steel barrel, composition grips and 1½ inch (40mm) bore.  The short barrel design was unusual and permitted the pistol to be fitted to a mount on the side of the aircraft.

Very (as a proper noun) is spelt with an initial capital if referring to the most common type of flare gun, named after US Navy Lieutenant Edward W Very (1847–1910) (although the devices are sometimes spelt Verey).  Lieutenant Very’s invention was a large caliber single-shot pistol with a single action firing mechanism, designed fire into the air flares to signal position, usually to indicate distress and the need for assistance.  The older Very pistols were always metal and typically built with a one inch (50 mm) bore while more modern versions are often fabricated in plastic with a 12 gauge (¾ inch (19 mm) bore.  The plastic versions are usually brightly colored to make them easier to find in an emergency and to distinguish them from handguns.  The flares are available in red, green and "white star", use governed by rules which vary according to use (aviation, at sea, when using explosives etc).

It was the misuse of a Very pistol which provided the inspiration for Smoke on the Water, the most famous song by the band Deep Purple.  In December 1971, the band were in Montreux, Switzerland to record an album at an entertainment complex attached to the town’s casino.  The evening before recording was due to begin, as part of the Montreux jazz festival, Frank Zappa and the Mothers of Invention were playing a concert in the casino theatre, during which a member of the audience fired a flare gun, igniting the ceiling, the crowd initially thinking the pyrotechnics were part of the show.  The fire burned the casino to the ground and the members of Deep Purple, watching the blaze from across the lake were inspired to write Smoke on the Water which was released three months later on the Machine Head album.

Frank Zappa and the Mothers

Were at the best place around

But some stupid with a flare gun

Burned the place to the ground

The adverb verily (in truth) dates from the early fourteenth century, the construct being the Middle English verray (true, real), from verray (true, very) + -ly.  The –ly prefix was from the Middle English -ly, -li, -lik & -lich, from the Old English -līċ, from the Proto-West Germanic -līk, from the Proto-Germanic -līkaz (having the body or form of), from līką (body) (from whence Modern German gained lich); in form, it was probably influenced by the Old Norse -ligr (-ly) and was cognate with the Dutch -lijk, the German -lich and the Swedish -lig.  It was used (1) to form adjectives from nouns, the adjectives having the sense of "behaving like, having a likeness or having a nature typical of what is denoted by the noun" and (2) to form adjectives from nouns specifying time intervals, the adjectives having the sense of "occurring at such intervals".  The feminine proper name Vera is from the Latin (where literally it meant “true”)

Lindsay Lohan in very low-cut dress, New York Fashion Week, 2011.

The word very is common and familiar in English and in most of the ways it’s used, well understood.  Most past participles which have become established as adjectives can (like almost all adjectives in English) be modified by the adverb but this does not extend verbs although there are of course sentences where it’s not immediately clear if a certain past participle is adjectival and thus able to be modified by very without an intervening adverb.  In practice however, whatever the objection of the grammar Nazis, such sentences usually manage to convey the intended meaning although the adverb tends to be superfluous and detracts from the elegance of expression.  Technically, adverbs of degree such as very, too & quite should be used only to qualify adjectives and not to qualify past participles that follow the verb to be, since they would then they would be qualifying verbs.  With the exception of certain participles (disappointed, tired et al) that have come to be regarded as adjectives, all other past participles are qualified by adverbs such as much, greatly & seriously et al.

As an adverb synonyms (depending on context) can include extremely, exceedingly, exceptionally, especially, tremendously, immensely, vastly. hugely, extraordinarily, extra, excessively, overly, over, abundantly, inordinately, singularly, significantly, distinctly, outstandingly, uncommonly, unusually, decidedly, particularly, eminently, supremely, highly, remarkably, really, truly, mightily, thoroughly, most, très, right, terrifically, awfully, terribly, devilishly, madly, majorly, seriously, desperately, mega, ultra, stinking. damned, devilish, hellish, frightfully, well, bloody, jolly, dirty, fair, real, mighty, powerful, awful, darned, bitching & exceeding.  As an adjective synonyms (depending on context) can include actual, precise, exact, actual, particular, specific, distinct, ideal, perfect, appropriate, suitable, apt, fitting, fit & right.

As an intensifier, very is used to add emphasis to adjectives that have some quality of variation (long, big et al) and while hardly adding precision, the adverb can, if thoughtfully applied, enhance the meaning.  What the grammar Nazis don’t like is where very is used to modify words of single or absolute value and the one which most excites their interest is probably “unique”.  Unique does of course suggest a one-off and that meaning, noted since the 1610s remains current but the once erroneous sense of "remarkable, uncommon" had become common since the late nineteenth century, especially in commerce and has become so prevalent it can no longer be thought wrong except if used in a way deliberately deceptive or misleading.  In that sense using “very” to modify unique functions in a different manner than it operates upon words like “tall” or “capacity” et al; it exists as emphasis rather than intensify.  For that reason “most” or “quite” are also often used (especially in commerce) to modify unique.

Signature

Signature (pronounced sig-nuh-cher or sig-nuh-choor)

(1) A person's name, or a mark representing it, as signed personally or by deputy, as in subscribing a letter or other document.

(2) The act of signing a document.

(3) In music, a sign or set of signs at the beginning of a staff to indicate the key or the time of a piece.

(4) In broadcasting, a song, musical arrangement, sound effect, etc., used as a theme identifying a program.

(5) Any unique, distinguishing aspect, feature, or mark.

(6) In computing, as digital signature, any one of a number of attempts to create a mechanism whereby a digital object can have the same unique identifying characteristic as a physical signature in ink; in cryptography, data attached to a message certifying the message originated from its claimed source; in email and some other variations of communication, test, images or other objects collectively appended usually at the end of a message, analogous with a traditional signature on a letter.

(7) In digital forensic analysis, as digital signature, a term used to refer to any collection of characteristics which can be used as an identifier of origin, intent etc;

(8) The part of a prescription for pharmaceuticals instructing the patient the frequency and quantity in which a drug should be administered (US only).

(9) As an adjective, something intended to be emblematic of an institution or individual (signature dish signature cocktail, signature scent etc).

(10) In printing, a sheet of paper printed with several pages that upon folding will become a section or sections of a book; such a sheet so folded.

(11) In mathematics, a tuple specifying the sign of coefficients in any diagonal form of a quadratic form.

(12) In medicine, a resemblance between the external character of a disease and those of some physical agent (obsolete).

1525-1535: From the Old & Middle French signature, from the Medieval Latin signātura, future active periphrastic of the verb signāre (to sign), the construct being signum (sign), + -tura, feminine of -turus, the future active periphrastic suffix.  The first use with a link to English appears to have been as a kind of document defined in Scottish law.  The Medieval Latin signatura, was, in Classical Latin a rescript (the matrix of a seal).  The meaning "one's own name written in one's own hand" is from 1570s, which replaced the early-fifteenth century “sign-manual” in this sense.  The use in musical notation in which composers used "signs placed it the beginning of a staff to indicate the key and rhythm" was noted first in 1806.  Signature began to be used in the generalized sense of "a distinguishing mark of any kind" as early as the 1620s.

Non est factum

Historically, in contract law a signature was binding on the party who signed and obliged the performance of the specific terms of the contract.  Even if someone could prove they signed because of their own misunderstandings or in an act of carelessness even to the point of gross negligence, courts would still usually enforce the contract but a notable exception was the doctrine of non est factum.  Translated literally from the Latin as "it is not my deed", it’s available as a defense where a person has been induced to sign something in circumstances where the contents of what was signed differ fundamentally from what the person was led to believe.  Where a plea is upheld, the court can set aside the contract (void ab initio).  Special circumstances must exist for the defense to succeed: it does not cover a claim where someone either misunderstood or failed to read the terms and conditions.

An octuple of Lindsay Lohan signatures on Lohanic merchandise. 

It’s novel in that it differs from other aspects of contract law such as the provisions which permit judges to strike-out particular clauses or even entire contracts if their enforcement is held to be “unconscionable”.  Non est factum is available even where terms and conditions can be reasonable such as the sale of a property for fair value; it hinges instead on the state of mind of the signee and the circumstances under which a signature was induced.  Typically, courts are most sympathetic to “innocent victims”, those who through no fault of their own (those illiterate, deaf, blind or suffering some other relevant incapacity) could not understand the document they were signing and relied upon another for advice.  Such is the reverence in contract law for the sanctity of the signature, a heavy evidential onus of proof is laid upon a claimant for non est factum to succeed; it’s a rare and exceptional defense.

The signature dish

Noted chefs and great restaurants often have signature dishes, not necessarily unique to them but something with which they’re famously associated.  Countries and regions also have signature dishes, sometimes advertised and promoted and sometimes just a link which develops over time.  There can even be disputes if the origin of something is thought a source of pride; there are factions in both Australia and New Zealand which lay claim to the pavlova. 

Minnesota Hotdish.

Despite the name, the concept of the Minnesota’s signature hotdish didn’t originate there and, with variations, is popular across the Upper Midwest region of the United States.  As a dish, such is the simplicity in preparation and adaptability in content that something recognizably close has probably been a feature of human cuisine for as long as the technical means of production has been available.  Anything of the hotdish type contains usually a starch, a meat, canned or frozen vegetables with canned soup as the binding agent; cooked in the one flat dish, it’s served heated.  The distinguishing characteristic of the classic Minnesota hotdish is the use of mushroom soup but beyond that, there’s much variation, inventiveness encouraged by the many hotdish completions in the region.  As well as the traditional beef base, tuna, turkey and chicken are used, pasta is often replaced by rice or potatoes and vegetarian versions have appeared.  The critical aspect seems to be the texture, while a Minnesota hotdish won’t entirely maintain the shape when sliced, it should have sufficient integrity for the potatoes or breadcrumbs to stay atop and not sink into the mix.

Hubert Humphrey, Cardinal Francis Spellman, President Lyndon Johnson & Richard Nixon, twenty-third Alfred E Smith dinner, New York, 16 October 1968.

Hubert Horatio Humphrey (1911–1978) served as a senator for Minnesota (1949-1964 & 1971-1978) and as US vice president (1965-1969).  He was the Democratic Party’s nominee for president in 1968.  As part of the 1968 campaign, his wife’s Minnesota hotdish recipe was published, unusual today in that it didn’t include the potato gems which usually now sit atop the concoction.  Mrs Humphrey’s culinary campaign contribution wasn’t decisive, her husband, although running Republican Richard Nixon close in the popular vote (Nixon (31,783,783 votes; 43.4%), Humphrey (31,271,839; 42.7%)), lost the electoral college (Nixon, 32 states & 301 votes, Humphrey 13 states & 191 votes).

Mrs Humphrey’s Ingredients

4 tablespoons shortening

2 green bell peppers, sliced

1 medium onion, chopped

1 lb (500 g) ground beef

1½ half teaspoons salt

¼ teaspoon pepper

2 eggs

2 cups whole kernel corn

4 medium tomatoes, sliced

½ cup dry bread crumbs

Butter

Mrs Humphrey’s Instructions

(1) Put shortening in skillet; lightly fry green peppers, onion and ground beef for 3 minutes or until partially done. Salt and pepper. Remove from heat; stir in eggs and mix well.

(2) Place 1 cup corn in casserole. Top with layer of meat mixture and layer of sliced tomatoes.

(3) Repeat until corn, meat mixture and tomatoes are used.

(4) Cover casserole with crumbs. Dot with bits of butter.

(5) Bake at 375º F (190º C) for 1 hour or until heated thoroughly.

It can be finished in a grill to add something to the cheese.  Serve with a side salad and rolls.