N W 67 30 E by N 78 45 W by N 78 45 East 90 00 West 90 00 By which it appeareth that every point of the Compasse is distant from the Meridian 11 degrees 15 minutes The third sort of planes are inclining or rather reclining whose upper face beholds the Zenith and in that respect is called Reclining but if a Diall be made on the nether side and thereby respect the Horizon it is then called an incliner so that the one is the opposite to the other These planes are likewise accidentally divided for they are either direct recliners reclining from the direct points of East West North and South and in this sort happens the direct Polar and Aequinoctiall planes as infinite more according to the inclination or reclination of the plane or they are as erect planes doe become declining recliners which looke oblique to the Cardinall parts of the World and obtusely to the parts they respect Suppose a plane to fall backward from the Zenith and by consequence it falls towards the Horizon then that represents a Reclining plane such you shall you suppose the Aequinoctiall Circle in the figure to represent reclining from the North Southwards 51 degrees from the Zenith or suppose the Axis to represent a plane lying parallel to it which falls from the Zenith Northward reclining 38 degrees one being Aequinoctiall the other a Polar plane But for the inclining decliners you shall know them thus forasmuch as the Horizon is the limiter of our sight and being cut at right angles representeth the East West North and South points it may happen so that a plane may lie between two of these quarters in an accidentall Azimuth and so not beholding one of the Cardinall Quarters is said to decline Again the said plain may happen not to stand Verticall which is either Inclining or Reclining and so are said to be Inclining Decliners First because they make no right angle with the Cardinal Quarters Secondly because they are not Verticall or upright There are other Polar planes which lie parallel to the Poles under the Meridian which may justly be called Meridian plains and these are erect direct East and West Dials where the poles of the plane remain which planes if they recline are called Position planes cutting the Horizon in the North and South points for Circles of position are nothing but Circles crossing the Horizon in those points CHAP IV. Shewing the finding out of a Meridian Line after many wayes and the Declination of a Plane A Meridian Line is nothing else but a line whose outmost ends point due North and South and consequently lying under the Meridian Circle and the Sun comming to the Meridian doth then cast the shadow of all things Northward in our Latitude so that a line drawn through the shadow of any thing perpendicularly eraised the Sun being in the Meridian that line so drawn is a Meridian line the use whereof is to place planes in a due scituation to their points respective as in the definition of this Circle I shewed there was accidentall Meridians as many as can be imagined between place and place which difference of Meridians is the Longitude or rather difference of Longitude which is the space of two Meridians which shews why noon is sooner to some then others The Meridian may be found divers wayes as most commonly by the Mariners compasse but by reason the needle hath a point attractive subject to errour and so overthroweth the labour I cease to speake any further It may be found in the night for when the starre called Aliot seems to be over the Pole-starre they are then true North the manner of finding it Mr. Foster hath plainly laid down in his book of Dyalling performed by a Quadrant which is the fourth part of a circle being parted into 90 degrees It may also be fouhd as Master Blundevile in his Booke for the Sea teacheth being indeed a thing very necessary for the Sea which way is thus Strike a Circle on a plain Superficies and raise a wire or such like in the center to cast a shadow then observe in the forenoon when the shadow is so that it just touches the circumference or edge of the Circle and there make a mark doe so again in the afternoon and at the edge where the shadow goes out make another mark between which two marks draw a line which part in halfe then from that middle point to the center draw a line which is a true Meridian Or thus Draw a great many Circles concentricall one within another then observe by the Circles about noone when the Sun casts the shortest shadow and that then shall represent a true Meridian the reason why you must observe the length of the shadow by circles not by lines is because if the Sun have not attained to the true Meridian it wil cast its shadow from a line and so my eye may deceive me when as by Circles the Sun casting shadow round about still meetes with one circumference or other and so we may observe diligently Secondly it is proved that the shadow in the Meridian is the shortest because the Sun is neerest the Verticall point Thirdly it is proved that it is a true Meridian for this cause the Sun as all other Luminous bodies casts his shadow diametrically and so being in the South part casts his shadow northward and is therefore a true Meridian But now to finde the declination of a wall if it be an erect wall draw a perpendicular line but if it be a declining reclining plane draw first an horizontall line and then draw a perpendicular to that and in the perpendicular line strike a Style or small Wyre to make right angles with the plane then note when the shadow of the Style falleth in one line with the perpendicular and at that instant take the altitude of the Sun and so get the Azimuthe reckoned from the South for that is the true declination of the wall from the South The distance of the Azimuthes from the South or other points are mentioned in degrees and minutes in the third Chapter in the definition of the severall sorts of planes or by holding the streight side of any thing against the wall as is the long Square ABCD whose edge AB suppose to be held to a wall and suppose again that you hold a thrid and plummet in your hand at E the Sun shining and it cast shadow the line EF and at the same instant take the altitude of the Sun thereby getting the Azimuthe as is taught following then from the point F as the center of the Horizon and from the line FE reckon the distance of the South which suppose I finde the Azimuthe to be 60 degrees from the East or West by the propositions that are delivered in the end of this Booke and because there is a Quadrant of a Circle between the South and the East or West points I substract the distance of the Azimuthe from 90

elevation or greater or lesser If the arke be equal to the complement of the poles elevation by it is a token the plane is oblique under the Meridian to be inclined unto the Pole in that case the meridian of the place and of the plane and also the Axis doe concur in the same line G L if the plane be supposed to fall in the same great circle KN but if the plane be not supposed but in some parallel of the same and the Axis be somwhat carryed away as necessarily it is done if the Sciotericall be absolved the Meridian of the plane and place are two lines parallel between themselves and are mutually joyned together according to the difference of longitude of the place and of the plane which difference is according to the angle HGC which is the complement of the angle BNK late found because the angle KGH is right by 57. p. 1. yea forasmuch as the meridian of the plane may goe by the poles of the plane but concurring at G or N are equall to two right by 20 p. 1. Example Let the plane meridionall declined to the right hand 29 de 59 m. inclining toward the pole artick 23 de 3 m. the elevation of the pole 49 de 35 m. and there are to be sought in the same the meridian of the place the plane and the elevation of the pole or Axis above the plane The calculation shall be thus To 67874 the tangent of the arke KN the distance of the meridian of the place from the Verticall of the plane 34 de 10 m. per ax 2 The sine of the arke NC 49de 35 m. whose complement is the arke BN 40de 25 m per axi. 4. To 60388 the sine of the angle BNK 37d 9m whose complement is the angle HNC or HGC 52 de 51. m. the difference of the longitude of the plane from the longitude of the place or the distance of the meridians of the place and plane Therefore let the horizon of the place be LC the verticall of the plane KL the circle of the plane of the horizon KNC in which there is numbred from K towards C 34 de 10m and at the terme of the numeration N draw the right line L N E which shall be the meridian of the plane and place if the center of the Sciotericie L or F is taken for the center of the World and the right line L N F for the Axis but because in the perfection of the Diall IG remaineth the Axis with E the center of the world not in the right line L N F but above the same with props at pleasure but notwithstanding it is raised equall in height with EI and OG and moreover the plane is somwhat withdrawn frō the axis of the world therefore the line L N F is now not altogether the meridian of the place but only the meridian of the plane or as vulgarly they speake the substilar But you may finde the meridian of the place thus draw IH at right angles to the meridian of the plane which they vulgarly call the Contingence to the common section of the Equator which in the plane let E the center of the world be set from the axis IG in the meridian of the plane L N F. Then to the center E consisting in the line L N E le the circle of the Equator FK be described and in the same toward the East because the horizon of the plane is more easterly then the horizon of the place and moreover the beame is cast sooner or later upon the meridian of the plane then the place let there be numbered the difference of longitude of the place and plane 52 de 51 m. and by K the end of the numeration let a right line be drawn as it were the certain beams of the Equator EKH which where it toucheth the common section of the Equator with the plane to wit the right line FH by that point let C the meridian of the place be drawn perpendicular The second case of the third Probleme of Pitiscus his Liber Gnomonicorum Sivero arcus BN repertus fuerit c. But if the arke BN shall be found lesse then the complement of the poles elevation it is a signe the plane doth consist on this side the pole artick and moreover above such a plane not the pole Artick but the pole Antartick shall be extolled to such an angle as ILM is whose measure is the arke IM to which out of the doctrine of opposites the arke GO is equall which you may certainly finde together with the arke NO thus As MOG the right angle to NG the difference between BN and BG so ONG the angle before found to OG per axi. 3. As the tangent ONG to Radius so the tangent OG to the sine O N by axi. 2. Example Let the plane be meridionall declined to the right hand 34 de 30 m. inclined toward the pole artick 16 de 10 m. and again let the elevation of the pole be 49 de 35 m. and there are sought The meridian of the place the longitude of the countrey The meridian of the plane the longitude of the plane The elevation of the pole above the plane The Calculation 1. As BF Radius 100000 to FC tangent complement of declination 55 de 30 m. 14550 so 27843 the sine of the inclination 16 de 10 m. to 40511 the tangent of K N 22 de 31 3 m. the distance of the meridian of the place from the Verticall of the plane per axi. 2. The sine of the arke N C 62 de 532 3 m. whose complement is B N 27 de 61 3 m. by which substracted from BG the complement of the poles elevation 40 de 25 m. there is remaining the arke N G 13 de 182 3 m. by axi. 4. To 61108 the sine of the angle B N K or O N G 37d 40 m. per axi. 3. comp. 1. To 14069 the sine of the arch OG the distance of the axis GL from the meridian of the plane OL 8de 51 3m by ax 3. To 18410 the sine of the arch N O the distance of the meridian of the plane OL from the meridian of the place N L 30 deg. 36½ m by axi. 2. The calculation being absolved let there be drawn the horizon of the place AC secondly the verticall of the plane BQ thirdly the horizon of the plane ABCQ in whose Quadrant AQ to wit according to the pole antartique which alone appeareth above such a plane First let be numbred the distance of the meridian of the place from the verticall of the plane 22 de 3 m. and by the ende of the numeration at P let the meridian of the plane LP be drawn then from the point P let the distance of the meridian of the plane from the meridian of the place be numbered by the terme of the numeration M let the meridian of the plane LM be drawn Finally

0 11 1 59 43 56 34 48 12 36 58 25 40 17 6 13 52 10 2 53 45 50 55 43 12 32 37 21 51 13 38 10 30 9 3 45 42 43 6 36 0 26 7 15 58 8 12 5 15 8 4 36 41 34 13 27 31 18 8 8 33 1 15     7 5 27 17 24 56 18 18 9 17 0 6         6 6 18 11 15 40 9 0                 5 7 9 32 6 50                 11 37 4 8 1 32                     21 40 This Table is in Mr. Gunters Book page 240 which if you desire to have the point of the Equinoctiall for a Horizontall plane on the houre of 12 enter the Table of shadows with 38 de 30 m. and you shall finde the length of the shadow to be 15 parts 5 m. of the length of the style divided into 12 which prick down on the line of 12 for the Equinoctiall point from the foot of the style So if I desire the points of the Tropick of Cancer I finde by this Table that at 12 of the clock the Sun is 62 de high with which I enter the Table of shadows finding the length of the shadow which I prick down on the 12 a clock line for the point of the Tropick of Cancer at the houre of 12. If for the houre of 1 I desire the point through which the parallel must pass looke for the houre of 1 and 11 in this last table under Cancer and I finde the Sun to have the height of 59 de 43 m. with which I enter the table of shadows and prick down the length thereof from the bottome of the style reaching till the other foot of the Compasses fall on the houre for which it was intended Doe so in all the other houres till you have pricked down the points of the parallels of declination through which points they must be drawn Hyperbolically Proceed thus in the making of a Horizontall Diall but if it be a direct verticall Diall you shall then take the length of the verticall shadow out of the said Table or work it as an Horizontal plane only accounting the complement of the elevation in stead of the whole elevation For a declining plane you may consider it as a verticall direct in some other place and having found out the Equator of the plane and the substyle you may proceed in the same manner from the foot of the style accounting where the style stands to be no other wayes then the meridian line or line of 12 in a Horizon whose pole is elevated according to the complement height of the style above the substyle and so prick down the length of the shadows from the foot of the style on every one of the Houre lines as if it were a horizontal or Verticall plane But in this you must be wary remembring that you have the height of the sun calculated for every houre of that Latitude in the entrance of the 12 signes in that Place where your Plane is a Horizontall plane or otherwayes by considering of it as a horizontall or Verricallplane in another latitude For the Azimuths or verticall circles shewing one what point of the compasse the sun is in every houre of the day it is performed with a great deale of facility if first when the sun is in the Equator we doe know by the last Table of the height of the sun for every houre of the day and by his meridian altitude with the help of the table of shadows find out the Equinoctiall line whether it be a Horizontall or upright direct plane for having drawn that line at right angles with the meridian and having the place of the Style and length thereof in parts and the parts of shadow to all altitudes of the sun being pricked down from the foot of the Style on the Equinoctiall line through each of those points draw parallel lines to the meridian or 12 a clock line on each side which shall be the Azimuths which you must have a care how you denominate according to the quarter of heaven in which the sun is in for if the Sun be in the easterly points the Azimuths must be on the Western side of the plane so also the morning houres must be on the opposite side There are many other Astronomical conclusions that are used to be put upon planes as the diurnall arches shewing the length of the day and night as also the Jewish or old unequal houres together with the circles of position which with the meridian and horizon distinguisheth the upper hemispheare into 6 parts commonly called the houses of Heaven which if this I have writ beget any desire of the reader I shall endeavour to inlarge my self much more in shewing a demonstrative way in these particulars I have last insisted upon I might heare also shew you the exceeding use of the table of Right and versed shadow in the taking of heights of buildings as it may very wel appear in the severall uses of the quadrant in Diggs his Pantometria in Mr. Gunters quadrant having the parts of right and versed shadow graduated on them to which Books I refer you CHAP XIV Shewing the drawing of the Seeling Diall IT is an Axiom pronounced long since by those who have writ of Opticall conceipts of Light and Shadow that Omnis reflectio Luminis est secundum lineas sensibiles latitudinem habentes And it hath with as great reason bin pronounced by Geometricians that the Angles of Incidence and Reflection is all one as appeareth to us by Euclides Catoptriques and on this foundation is this conceipt of which we are now speaking Wherefore because the direct beams cannot fall on the face of this plane we must by help of a piece of glasse apt to receive and reflect the light placed somwhere horizontally in a window proceed to the work which indeed is no other then a Horizontall Diall reversed to which required a Meridian line which you must endeavour to draw and finde according as you are before taught or by the helpe of the Meridian altitude of the Sun your glasse being fixed marke the spot that reflects upon the seeling just at 12 a clock make that one point and for the other point through which you must draw your meridian line you may finde by holding up a threed and plummet till the plummet fall perpendicular on the glasse and at the other end of the line held on the seeling make another mark through both which draw the Meridian line Now for so much as the center of the Diall is a point without and the distance between the glasse and the seeling is to be considered as the height of the style the glasse it selfe representing the center of the world or the very apex of the style wee must finde out those two Tangents at right angles with the

the morning houres and 6 7 8 the evening And because the North pole is elevated above this plane 38 deg. 30 min. the Axis must be from the center according to that elevation pointing upward as the South doth downward so as A is the Zenith of the South C must be in the North The Arithmeticall calculation is the same with the former also a North plane may shew all the houres of the South by consideration of reflection For by Opticall demonstration it is proved that the angles of incidence is all one to that of reflection if any be ignorant thereof I purposely remit to teach it to whet the ingenious Reader in labouring to finde it The Figure of a direct East and West Diall for the Latitude of London 51 deg. 30 min. East Diall West Diall CHAP IV. Shewing the making of the Prime Verticall planes that is a direct East or West Diall FOr the effecting of this Diall first draw the line AD on one end thereof draw the circle in the figure representing the Equator then draw two touch lines to the Equator parallel to the line AD these are they on which the houres are marked divide the Equator in the lower semicircle in 12 equall parts then apply a ruler to the center through each part and where it touches the lines of contingence make marks from each touch point draw lines to the opposite touch point which are the parallels of the houres and at the end of those lines mark the Easterly houres from 6 to 11 and of the West from 1 to 6. These planes as I told you want the Meridian houre because it is parallel to the Meridian Now for the placing of the East Diall number the elevation of the Axis to wit the arch DC from the line of the Equator to wit the line AD and in the West Diall number the elevation to B fasten a plummet and thrid in the center A and hold it so that the plummet may fall on the line AC for the East Diall and AB for the West Diall and then the line AD is parallel to the Equator and the Dial in its right position And thus the West as well as East for according to the saying Contrariorum eadem est doctrina contraries have one manner of doctrine Here you may perceive the use of Tangent line for it is evident that every houres distance is ●●t the Tangent of the Aequinoctiall distance The Arithmeticall Calculation 1 Having drawn a line for the houre of 6 whether East or West As the tangent of the houre distance is to the Radius so is the distance of the houre from 6 to the height of the Style 2 As the Radius is to the height of the Style so is the tangent of the houre distance from 6 to the distance of the same houre from the substyle The style must be equall in height to the semidiameter of the Equator and fixed on the line of 6. CHAP V. Shewing the making a direct parallel Polar plane or opposite Aequinoctiall I Call this a direct parallel Polar plane for this cause because all planes may be called by their scituation of their Poles and so an Aequinoctiall parallel plane may be called a Polar plane because the Poles thereof lie in the poles of the World The Gnomon must be a quadrangled Parallelogram whose height is equall to the semidiameter of the Equator as in the East and West Dials so likewise these houres are Tangents to the Equator Arithmeticall calculation Draw first a line representing the Meridian or 12 a clock line and another parallel to the said line for some houre which may have place on the line say As the tangent of that houre is to the Radius so is the distance of that houre from the Meridian to the height of the Style 2 As the Radius is to the height of the style so the tangent of any houre to the distance of that houre from the Meridian CHAP VI Shewing the making of a direct opposite polar plane or parallel Aequinoctiall Diall AN Aequinoctiall plane lyeth parallel to the Aequinoctiall Circle making an angle at the Horizon equal to the elevation of the said Circle the poles of which plane lie in the poles of the world The making of this plane requires little instruction for by drawing a Circle and divide it into 24 parts the plane is prepared all fixing a style in the center at right angles to the plane As the Radins is to the sine of declination so is the co-tangent of the Poles height to the tangent of the distance of the sub-stile from the Meridian If you draw lines from 7 to 5 on each side those lines so cut shall be the places of the houre lines of a parallel polar plane now if you draw to each opposite from the pricked lines those lines shall be the houre lines of the former plane CHAP VII Shewing the making of an erect Verticall declining Diall IF you will work by the fundamentall Diagram you shall first draw a line such is the line AB representing the Meridian then shall you take out of the fundamentall diagram the Secant of the Latitude viz. AC and prick it down from A to B and at B you shall draw a horizontall line at right angles such is the line CD then you shall continue the line AB toward i and from that line and where the line AB crosseth in CD describe an arch equall to the angle of Declination toward F if it decline Eastward and toward G if the plane decline Westward Then shall you prick down on the line BF if it bean Easterly declining plane or from B to G if contrary the Secant complement of the Latitude viz. AG in the fundamentall Diagram and the Sine of 51 degrees viz. DA which is all one with the semidiameter of the Equator and therewithall prick it down at right angles to the line of declination viz. BF from B to H and G and from F towards K and L then draw the long square KIKL and from B toward H and G prick down the severall tangents of 15 30 45 and prick the same distance from K and L towards H and G lastly draw lines through each of those points from F to the horizontall line CD and where they end on that line to each point draw the houre lines from the point A which plane in our example is a Verticall declining eastward 45 degrees and it is finished But because the contingent line will run out so far before it be intersected I shall give you one following Geometricall example to prick down a declining Diall in a right angled parallelogram Now for the Arithmeticall calculation the first operation shall be thus As the Radius to the co-tangent of the elevation so is the sine of the declination to the tangent of the substiles distance from the meridian of the place then II Operation Having the complement of the declination and elevation finde the

from the point M into whatsoever part let the proper elevation of the pole be numbered or the distance of the axis from the meridian of the plane 8 de 51 3m and by the term of the numeration I let the axis LI be drawn to be extolled or lifted up on the meridian of the plane LM to the angle MLN The third case of the third probleme of Pitiscus his liber Gnomonicorum Si denique arcus BN repertus fuerit major c. Lastly if the arke BN be found greater then the complement of the poles elevation BG it is a token the plane to be inclined beyond the pole artique and moreover the pole artique should be extolled above such a plane to so great an angle as the angle GLO which the arke GO measureth which arke together with the arke ON in the end you may find in such sort as in the precedent case Example Let there be a meridian plane declining to the right hand 35 de 54 m. inclining towards the pole artique 75 de 43 m. and let the elevation of the pole be 49 de 35½ m. but there is sought the meridian of the plane and place together with the elevation of the pole above the plane the calculation shall be thus to 133874 tangent of the arke KN the distance of the meridian of the place from the verticall of the plane 53 de 14½ m by axi. 2. The sine of the arke NC 8 de 29● m. whose complement is BN 81 de 30½ m. from whence if you substract BG 40 de 25 m. there remaineth the arke GN 41 de 5½ m. to 97982 the sine of the angle BNK or ONG by axi. 3. to 64399 the sine of the arch OG the distance of the axis from the meridian of the plane 40 de 51 3 m. by axi. 3. to 17483 the sine of the arke O N the distance of the meridian of the plane from the meridian of the place 10 de 4 m. by axi. comp. 2. The calculation being finished let the horizon of the place be AC the verticall of the plane KD the horizon of the plane AKCD in which let be numbered from the vertical point K toward C the distance of the meridian of the place from the vertical of the plane 53 de 14½ m. and by the end of the numeration let be drawn the meridian of the place LN then from the meridian of the place to wit from the point N backward let the distance of the meridian of the plane 10 de 4m be numbred and by O the end of the numeration let LO the meridian of the plane be drawn from which afterwards let the proper elevation of the pole be numbred or the distance of the axis from the meridian of the plane 48d 5½m and by the term of the numeration G let the axis LG be drawn being extolled above the plane BO to the angle GLO CHAP X. In which is shewed the drawing of the houre-lines in these last planes not there mentioned being also part of Pitiscus his example in the fourth Probleme of his liber Gnom SO then saith he Si axis c. If the axis be oblique to the plane as the foregoing are as in any plane oblique to the Equator many of the houre-lines doe concur at the axis with equal angles but they are easily found thus But because Pitiscus is mute in defining which part he takes for the right hand and which the left we must search his meaning Pitiscus was a Divine is evident by his own words in his dedication Celsitudini tuae tota vita mea prolixe me excusarem quod ego homo Theologus c. If we take him as hee was a Divine we imagine his face to be towards the East then the South is his right hand and the North is his left hand That he was an Astronomer too appeareth by his Books both of proper and common motion then we must imagine his face representing the South the East on his left hand which cannot be as shall appear Neither must we take him according to the Poets whose face must be imagined toward the West In short take him according to Geographie representing the Pole and this shews the right hand was the East and left the West as is evident by the Diall before going for it is a plane declining from the South to the right hand 30 degrees that is the East because it hath the morning houres not the evening because the Sun shines but part of the afternoon on the plane Thus in briefe I have run throngh all planes and proceed to shew you farther conclusions But I desire the Reader to take notice that in these examples of Pitiscus I have followed his own steps and made use of the Naturall Sines and Tangents CHAP XI Shewing how by the helpe of a Horizontall Diall or other to make any Diall in any position how ever HAving prepared a Horizontall Diall as is taught before on the 12 houre as far distant as you please from the foot of the style draw a line perpendicular to the line of 12 on that describe a Semicircle plasing the foot of the Compasses in the crossing of the lines this Semicircle divide into 180 parts each Quadrant into 90 to number the declination thereon let the arch of the Semicircle be toward the North part of the Diall Then prepare a plane slate such as will blot out what hath been formerly made thereon and make it to move perpendicularly on the horizontal plane on the center of the semicircle which wil represent any declining plane by moving it on the semicircle Now knowing the declination of the plane turn this slate towards the easterly part if it decline towards the East if contrary to the West if toward the West and set it on the semicircle to the degree of declination then taking a candle and moving the Diall till the shadow fall on all the houres of the horizontall plane mark also where the shadow falls on the declining plane that also is the same houre on the plane so scituated drawn from the joyning of the style with the plane It is so plain it needs no figure So may you doe in all manner of declining reclining or reclining and inclining Dials by framing your instrument to represent the position of the plane Note also that the same angle the axis of the Horizontal Dial makes with the plane the same elevation must the axis of that plane have and where it shadows on the representing plane when the shadow of the horizontal axis is on 12 that is the meridian of the place By the same also may you describe all the conclusions Astronomicall the Almicanthers circles of height the parallels of the Sun shewing the declination the Azimuthes shewing the point of the Compasse the Sun is in and all the propositions of the Sphere Seeing this is so plain and evident nay a delightful conclusion I will not give

you farther directions in a matter of so great perspicuity as to lay down the severall wayes for projecting the Sphere on every severall plane but proceed to shew the making of a general Dial for the whole World which we will use as our Declinatorie to finde the scituation of any wall or plane as shall be required to make a Diall thereon as followeth in the next Chapter CHAP XII Shewing the making of a Diall on a Crosse form as also a Universall Quadrant drawn from the same projection as also to describe the Tropicks on Meridian or Polar planes THis Universall Diall is described by Clavius in his eighth Book de Gnomonicis But because the Artists of these times have found out a more commodious contrivance of it in the fabrique I shall describe it according to this Figure Now to know the houre of the day you shall turn the plane by the helpe of the needle so as the end A shall be toward the North and E toward the South and elevate the end E to the complement of the elevation then bringing the Box to stand in the Meridian the shoulder of the Crosse shall shew you the houre Upon this also is grounded the Universall Quadrant hereafter described which Instrument is made in Brasse by Mr. Walter Hayes as it is here described Prepare a Quadrant of Brasse divide it in the limbe into 90 degrees and at the end of 45 degrees from the center draw the line A B which shall represent the Equator divide the limbe into 90 degrees as other Quadrants are usually divided then number both wayes from the line AB the greatest declination of the Sun from the North and South at the termination whereof draw the arch CD which shall be the Tropicks then out of the Table of declination pag. 45 from B both wayes let there be numbered the declinatiō of the Signes according to this Table   G M   ♈ 00 00 ♎ ♉ ♍ 11 30 ♏ ♓ ♊ ♌ 20 30 ♐ ♒ ♋ 23 30 ♑ Now the plane it selfe is no other then an East or West Diall numbred on one side with the morning houres and on the other with the evening houres the middle line AB representing the Equator And to set it for the houre you shall project the Tropicks and other intermediate parallels of the Signes upon them as is hereafter shewed but that the plane may not run out of the Quadrant you shal work thus opening the Compasses to 15 degrees of the Quadrant prick that down both wayes at which distance draw parallels to the line AB and with the same distance as if it were the semidiameter of the Equator describe the semidiameter of the Equator on the top of the line AB which divide into 12 parts and laying a ruler through the center and each of those divisions in the semicircle to those parallel lines on each side of AB marke where they cut and from side to side draw the parallel houre lines as is taught in the making of an East and West Diall make those parallel lines also divided as a tangent line on each side AB so if this Quadrant were held on an East or West wall and a plummet let fall from the center of the Equator where the style stands which may be a pin fitted to take out and in fitted to the height of the distance between the line A B and the other parallels which is all one with the Radius of the small Circle it shall I say be in its right scituation on the East or West wall if you let the plummet and threed fall on the elevation of the Pole in that place But because we desire to make it generall we must describe the Tropicks and other parallels of declination upon it as is usuall to be done on your Polar and East and West Diall which how to doe is thus Having drawn the houre lines and Equator as is taught from E the height of the style take all the distances between it and the houre lines where they doe crosse the line AB and prick them down on the line representing the Equator in this figure from the center B. Then describe an occult arch of a Circle whereon describe a Chorde of 23 degrees 30 minutes with such other declinations as you intend on your plane Then on the line representing the Equator noted here with the figures of the houres they were taken from 6 7 8 9 10 11 at the marks formerly made that was taken from E the height of the style and every of the houres from these distances I say raise perpendiculars to cut the other lines of declination so those perpendiculars shall represent those houre lines from whence they were taken and the distances between the Equator and the severall lines of declination shall be the same distances from the Equator and the other parallels of declination upon your plane through which marks being pricked down upon the severall hourelines from the Equinoctiall If you draw those Hyperbolicall lines you shall have described the parallels of declination required But if you will performe the same work a second and easie way worke by this Table following which is universall and is composed out of the Table of Right Versed shadow Put this Table before thee for the point of each houre line whereby the severall parallels of the Signes shall pass worke thus The style being divided into known parts if into 12 take the parts of shadow out of the Table in the same known parts by which the style is divided prick them down on each houre line as you finde it marked in the Table answering the houre both before and after noon As suppose that a Polar plane I finde when the Sun is in Aries or Libra at 12 a clock the shadow hath no latitude but at 1 and 11 it hath 3 parts 13 min. of the parts of the style which I prick from the foot of the style on the houres of 1 and 11 both above and beneath the Equator and for 2 and 10 I finde 6 parts 56 min. which I prick down also from the center to the houre lines of 10 and 2 and so of the other houre lines and parallels through which if I draw those lines they shall represent the parallels of the Declination A Table of the Latitude of shadows   Cancer Gemini Leo Virgo Taurus Libra Aries   p m p m p m p m p m a m 12 5 13 4 25 2 26 0 0 12 1 6 17 5 35 4 5 3 13 11 2 8 11 8 35 7 27 6 56 10 3 14 5 13 31 12 39 12 0 9 4 23 15 22 45 21 21 20 27 8 5 49 6 47 57 45 45 44 47 7 6 Vmbra infinita 6 Having promised in the description of the use of this Instrument to shew how to finde the inclination and reclination of a plane I shal proceed to give you some cautions First then the quadrant is divided in the limbe as other

Meridian the one neere the window the other farther in through severall points whereof we must draw the houre-lines Let AB be the Meridian line found on the seeling now suppose the Sun being in the highest degree of Cancer should shine into the Glasse that is fixed in C it shall again reflect unto D where I make a mark then letting a plummet fall from the top of the seeling till it fall just on C the glasse from the point E from which draw the line A B through D and E which shall be the Meridian required if you do this just at noon Now if you would finde out the places where the hour-lines shall crosse the Meridian the Center lying without the window EC you may work thus CHAP X. Shewing the making and use of the Cylinder Dial whose hour-lines are straight as also a Diall drawn from the same form having no Style THis may be used on a Staff or other round made like a Cylinder being drawn as is here described where the right side represent the Tropicks and the left side the Equinoctial or it may be used flat as it is in the Book the Instrument as you see is divided into months and the bottom into signs and the line on the right side is a tangent to the radius of the breadth of the Parallelogram serving to take the height of the Sun the several Parallels downward running through the pricked line in the midle are the lines of Altitude and the Parallels to the Equator are the Parallels of Declination numbred on the bottom on a Sine of 23 de and a half For the Altitude of the Sun The use of it is first if it be described on the head of a staff to have a gnomon on the top equal to the radius and just over the tangent of Altitudes to turn it till you bring the shadow of it at right angles to it self which shal denote the height required For the Houre of the Day Seek the Altitude of the Sun in the midle prick't line and the Declination in the Parallels from the Equator and mark where the traverse lines crosse through the crossing of the two former lines and at the end you shal finde the figures of 2 or 10 3 or 9 c. only the summer Houres are sought in the right side where the Sun is highest and the traverse lines longest and in the winter the Hour is sought on the left side where the traverse lines are shorter For the Declination and degree of the Signe Seek the day of the moneth on the top marked with J. for January F for February c. and by the help of a horse hair or threed extended from that all along of Parallel of Declination till it cut on the bottom where the signes are numbred the down right lines that are parallel to the Equator counted toward the right hand is the degree of the Declination of that part of the Ecliptick which is in the bottom right against the day of the moneth sought on the top The pricked line passing through the 18 degree of the Parallel of Altitude is the line of Twy-light this projection I had of my very good friend John Hulet Master of Arts and Teacher of the Mathematicks You may also make a Dyal by preparing of a hollow Cylinder and if you doe number on both ends of the Circle on top and bottom 15 de from line to line or divide it into 24 parts and if from top to bottom you draw streight lines first by dividing the Cylinder through the middle and only making use of one half it shal have 12 houres upon it Lastly if you cut off a piece from the bottom at an angle according to the Elevation and turn the half Cylinder horizontal on that bottom til the shadow of one of the sides fal parallel with any one of those lines from top to bottom which numbred as they ought shal shew the hour without the use of a Style So also may you project a Dyal on a Globe having a round brim on the top whose projection will seem strange to those that look upon it who are ignorant of these Arts CHAP XVI Shewing the making of a universall Dyall on a Globe and how to cover it if it be required If you desire to cover the Globes and make other inventions thereon first learn here to cover it exactly with a pair of compasses bowed toward the points measure the Diameter of the Globe you intend to cover which had finde the Circumference thus Multiply the Diameter by 22 and divide that product by 7 and you have your desire That Circumference let be the line A B which divide into 12 equal parts and at the distance of three of those parts draw the Parallel C D and E F A Parallel is thus drawn take the distance you would have it asunder as here it is three of those 12 divisions set one foot in A and make the Arch at E another at B and make the Arch with the other foot at F the compasses at the wideness taken then by the outward bulks of those Arches draw the line E F so also draw the line C D. And to divide the Circumference into parts as our example is into 12 work thus set your compasses in A make the Ark B F the compasses so opened set again in B and make the Ark A C then draw the line from A to F then measure the distance from F to B on the Ark and place it on the other Arch from A to C thence draw the line C B then your compasses open at any distance prick down one part less on both those slanting lines then you intend to divide thereon which is here 11 because we would divide the line A B into 12 then draw lines from each division to the opposite that cuts the line A B in the parts of division But to proceed continue the Circumference at length to G and H numbring from A toward G9 of those equal parts and from B toward H as many which shal be the Centers for each Arch. So those quarters so cut out shall exactly cover the Globe whose Circumference is equal to the line A B. Thus have you a glance of the Mathematicks striking at one thing through the side of an other for I here made one figure serve for three several operations because I would not charge the Press with multiplicity of figures CHAP XVII Shewing the finding of the Elevation of the Pole and therewithall a Meridian without the Declination of Sun or Starre THis is done by erecting a gnomon horizontal and at 3 times of the day to give a mark at the end of the Shadows now it is certain that represents the Parallel of the Sunne for that day then take three thin sticks or the like and lay them from the top of the gnomon to the places where the shadows fell and on these three so standing lay a board to ly on all