The art of dialling by a new, easie, and most speedy way. Shewing, how to describe the houre-lines upon all sorts of plaines, howsoever, or in what latitude soever scituated: as also, to find the suns azimuth, whereby the sight of any plaine is examined. Performed by a quadrant, fitted with lines necessary to the purpose. Invented and published by Samuel Foster, professor of astronomie in Gresham Colledge. Foster, Samuel, d. 1652. 1638 Approx. 60 KB of XML-encoded text transcribed from 30 1-bit group-IV TIFF page images. Text Creation Partnership, Ann Arbor, MI ; Oxford (UK) : 2005-10 (EEBO-TCP Phase 1). A01089 STC 11201 ESTC S102472 99838255 99838255 2628 This keyboarded and encoded edition of the work described above is co-owned by the institutions providing financial support to the Early English Books Online Text Creation Partnership. This Phase I text is available for reuse, according to the terms of Creative Commons 0 1.0 Universal . The text can be copied, modified, distributed and performed, even for commercial purposes, all without asking permission. Early English books online. (EEBO-TCP ; phase 1, no. A01089) Transcribed from: (Early English Books Online ; image set 2628) Images scanned from microfilm: (Early English books, 1475-1640 ; 1097:07) The art of dialling by a new, easie, and most speedy way. Shewing, how to describe the houre-lines upon all sorts of plaines, howsoever, or in what latitude soever scituated: as also, to find the suns azimuth, whereby the sight of any plaine is examined. Performed by a quadrant, fitted with lines necessary to the purpose. Invented and published by Samuel Foster, professor of astronomie in Gresham Colledge. Foster, Samuel, d. 1652. [6], 39, [1] p., [2] folded plates : ill. Printed by Iohn Dawson for Francis Eglesfield, and are to be sold at the signe of the Marigold in Pauls Church-yard, London : 1638. 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Understanding these processes should make clear that, while the overall quality of TCP data is very good, some errors will remain and some readable characters will be marked as illegible. Users should bear in mind that in all likelihood such instances will never have been looked at by a TCP editor. The texts were encoded and linked to page images in accordance with level 4 of the TEI in Libraries guidelines. Copies of the texts have been issued variously as SGML (TCP schema; ASCII text with mnemonic sdata character entities); displayable XML (TCP schema; characters represented either as UTF-8 Unicode or text strings within braces); or lossless XML (TEI P5, characters represented either as UTF-8 Unicode or TEI g elements). Keying and markup guidelines are available at the Text Creation Partnership web site . eng Dialing -- Early works to 1800. Quadrant -- Early works to 1800. 2003-06 TCP Assigned for keying and markup 2003-06 Aptara Keyed and coded from ProQuest page images 2005-02 Andrew Kuster Sampled and proofread 2005-02 Andrew Kuster Text and markup reviewed and edited 2005-04 pfs Batch review (QC) and XML conversion THE ART OF DIALLING ; BY A NEW , EASIE , AND MOST SPEEDY WAY . SHEWING , HOW TO DESCRIBE THE Houre-lines upon all sorts of Plaines , Howsoever , or in what Latitude soever Scituated : As also , To find the Suns Azimuth , whereby the sight of any Plaine is examined . Performed by a Quadrant , fitted with lines necessary to the purpose . Invented and Published by SAMVEL FOSTER , Professor of Astronomie in Grosham Colledge . LONDON , Printed by Iohn Dawson for Francis Eglesfield , and are to be sold at the signe of the Marigold in Pauls Church-yard . 1638. To the Reader . READER , HEre is presented to thy view a short and plaine Treatise ; it was written for mine owne use , it may become thine if thou like it ; The subject indeed is old ; but the manner of the Worke is all new . If any be delighted with recreation of this nature , and yet have not much time to spend , they are here fitted , the instrument will dispatch presently . If they feare to lose themselves in a wildernesse of lynes , or to out-runne the limits of a Plaine , by infinite excursions ( two inconveniences unto which the common wayes are subject ) they are here acquitted of both , having nothing to draw but the Diall it selfe , contracted within a limited equicrurall triangle . If want of skill in the Mathematicks should deterre any from this subject , let them know that here is little or none at all required , but what the most ignorant may attaine . If others shall thinke the Canons more exact ; so doe I , but not so easie to bee understood , not so ready for use , not so speedy in performance , nor so well fitting all sorts of men : and withall an instrument in part must bee used , this will doe all , and is accurate enough . If it must needs be disliked , let a better be shewed and I will dislike it too ; It is new , plaine , briefe , exact , of quicke dispatch . Accept it , and use it , till I present thee with some other thing , which will bee shortly . Imprimatur . Decemb. 1. 1637. SA . BAKER . THE DESCRIPTION OF THE QVADRANT , and the manner how the lines are inscribed and divided . CHAP. I. 1. The description of the fore-side . THe limbe is divided into 90 degrees , and subdivided into as many parts as quantity will give leave . The manner of division , and distinction of the subdivided parts is such as is usuall in all other Quadrants . To describe the other Worke in the superficies ; Take from the upper edge of the limbe about 3 degrees , and set off that space from the center R to A. Then divide AE into seven parts , whereof let EB containe two . Or in greater instruments , if AE be 1000. let EB containe 285. Make SC equall to EB , and drawe the line BC. From C , draw CD parallel , and of equall length to AB . Upon AB and CD , and BE also ( as farre as it is capable ) insert the 90 sines , from B towards A and E , and from C towards D , but let them be numbred from A unto B to 90 , and so to E 113 degrees 30 minutes , from D to C unto 90 degrees . Againe : Draw ES cutting CD at F ; so shall BCFEB containe a parallelogram , whose opposite sides , being parallel , are divided alike , and in this manner . BE and CF as whole sines , doe containe the 90 sines , or as many of them as can distinctly bee put in : and from the divisions are drawne parallel lines , having every tenth , or fifth , distinguished from the rest . These serve for the 12 Signes and their degrees , and therefore you see upon every 30th degree , the characters of the 12 Signes inserted , in such manner as the figure sheweth . And these lines may bee called , The Parallels of the Suns place . In like manner , The lines BC , EF , being first bisected at X and Z , shall make 4 lines of equall length . These 4 lines XB , XC , ZE , and ZF , are each of them divided as a scale of Sines , beginning at X and Z , and from each others like parts are parallel lines protracted , having every tenth and fifth distinguished from the rest . They are numbred ; upon BC , from B to X 90 , to C 180 ; upon FE , from F to Z 90 , to E 180. These lines are called , The lines of the Sunnes Azimuth . This done ; Upon the center R describe the two quadrants VT , and BC , let their distance VC bee one sixth part of Rc , or more if you will. Divide them each into 6 equall parts , at e , o , y , n , s ; and a , i , u , m , r , drawing slope-lines from each others parts , as Va , ei , on , ym , nr , sb : and these lines so drawne are to bee accounted as Houres . Then dividing each space into two equall parts , draw other slope-lines standing for halfe houres , which may be distinguished from the other , as they are in the figure . Then from the points V and T draw the right line VT . Lastly , Having a decimall scale equall to TR , you must divide the same TR into such parts as this Table here following alloweth , the numbers beginning at T , and rising upto 90 at R. Vpon your instrument ( for memory and directions sake ) neere to the line AB , write , The summe of the latitude and Sunnes altitude in Summer ; The difference in Winter . Over VT , write , The line of Houres . Neere to CD write , The summe of the latitude and Sunnes altitude in Winter ; The difference in Summer . By TR , write , The line of latitudes for the delineation of Dialls . A Table to divide the line of Latitudes . 90 10000 62 9360 46 8259 30 6325 14 3325 85 9982 61 9311 45 8165 29 6169 13 3104 80 9924 60 9258 44 8068 28 6010 12 2879 78 9888 59 9203 43 7968 27 5846 11 2650 76 9849 58 9147 42 7865 26 5678 10 2419 75 9825 57 9088 41 7738 25 5505 9 2186 74 9801 56 9026 40 7647 24 5328 8 1949 72 9745 55 8962 39 7532 23 5146 7 1711 70 9685 54 8895 38 7414 22 4961 6 1470 69 9651 53 8825 37 7292 21 4772 5 1228 68 9615 52 8753 36 7166 20 4577 4 984 67 9378 51 8678 35 7036 19 4378 3 739 66 9519 50 86●● 34 6902 18 4176 2 493 65 9496 49 8519 33 6764 17 3969 1 247 64 9454 48 8436 32 6622 16 3758 0 ● 63 9408 47 8348 31 6475 15 3543   S●… 2. The description of the backe-side . Upon the backe-side is a circle only described , of as large extent as the Quadrant will give leave , noted with ABCD , divided into two equall parts by the Diameter AC . The semicircle ABC is divided into 90 equall parts or degrees , every fifth and tenth being distinguished from the rest by the longer line ; They are numbred by 10 , 20 , 30 , &c. unto 90. The same parts are also projected upon the diameter AC , by a ruler applyed to them from the point D. These are numbred also from A to C by 10 , 20 , &c. unto 90. The other semicircle ADC , is first divided into two Quadrants at D. And then upon these two quadrants are inscribed 90 such parts as this Table insuing doth allow . The inscription is made by helpe of a Quadrant of a circle equall to AD or CD , being divided into 45 equall degrees , out of which you may take such parts as the Table giveth , and so pricke them downe , as the figure sheweth . Every fifth and tenth of these parts is distinguished from the rest by a longer line ; they are numbred from A and C , by 10 , 20 , &c. unto 90 ending in D. A Table to divide the upper and nether Quadrants of the Circle . 1 1.00 14 13.36 27 24.25 40 32.44 53 38.37 66 42.25 2 2.00 15 14.31 28 25.09 41 33.16 54 38.59 67 42.38 3 3.00 16 15.25 29 25.52 42 33.47 55 39.19 68 42.50 4 3.59 17 16 18 30 26.34 43 34.18 56 39.40 69 43.02 5 4.59 18 17.10 31 27.15 44 34.47 57 39.59 70 43.13 6 5.58 19 18.02 32 27.55 45 35.16 58 40.18 72 43.34 7 6.57 20 18.53 33 28.35 46 35.44 59 40.36 74 43.52 8 7.55 21 19.43 34 29.13 47 36.11 60 4054 75 44.00 9 8.53 22 20.32 35 29.50 48 36.37 61 41.10 76 44.08 10 9.51 23 21.21 36 30.27 49 37.03 62 41.27 78 44.22 11 10.48 24 22.08 37 31.02 50 37.27 63 41.43 80 44.34 12 11.45 25 22.55 38 31.37 51 37.51 64 41.57 85 44.53 13 12.41 26 22 40 39 32 . 1● 52 38.15 65 42.11 90 45.00 Thus have you both sides decribed . Besides all this , there are two sights added , with a threed and plummet like as in other instruments . The threed hath a moovable bead upon it for speciall use . The same threed passeth through the center R. quite behind the Quadrant , and is hung upon a pinne at the bottome of the Quadrant , noted with W. The reason of the threeds length will be seene when wee come to the uses of the instrument . CHAP. II. The use of the Quadrant in generall . FIrst upon the fore-side . The limbe serveth especially for observation of all necessary angles . The lines AE , CD , with the Parallelogram BCEF , are to find out the Suns Azimuth in any latitude whatsoever . The slope-lines within the arkes VT , cb , by helpe of the threed and bead , doe serve artificially to divide the line of Houres TV , into its requisite parts ; which together with TR the line of latitudes , doe serve to protract all plaine Dialls howsoever scituated . Secondly upon the back-side . Note that ABC is called the Semicircle : AC is called the Diameter : AD the Vpper quadrant : CD the Nether quadrant . The uses of these are to find out the necessary arkes and angles , either for preparation to the Dialls description , or serving after for the Dialls scituation upon the Plaine . In all these uses the threed bearing part , and therefore having asufficient extent of length , that being loosed it may with facility reach over either side of the Quadrant . CHAP. III. To find the Azimuth of the Sunne in any Latitude whatsoever . BEfore you can make any draught of your Diall , you must know the scituation of your plaine , both for declination and inclination . The best way to come to the plaines declination is by helpe of the Sunnes Azimuth . By having the Latitude of the place ; The place of the Sunne in the Eclipticke , and the altitude of the Sunne above the Horizon , you may find out the Azimuth thereof in this manner . Adde the Sunnes altitude , and your latitude together , and substract the lesser of them from the greater ; So shall you have the summe of them , and the Difference of them . With this summe and difference , come to your Quadrant , and according to the time of the yeare ( as the lines will direct you ) Count the said Summe and Difference respectively , and applying the threed unto them , find out the Sunnes place in the Parallels serving thereto , and where the threed cuts this Parallel , observe the Azimuth there intersecting , for that is the Azimuth from the South , if you number it from the line whereon the summe was numbred . Example 1. In the North latitude of 52 gr . 30 min. in the Summer-time the Sunne entring into 8 , and the altitude being observed 30 gr : 45 min. I adde the latitude 52 gr . 30 min. and the Sunnes altitude 30 gr . 45 min So I find the summe of them 83 gr . 15 min. and substracting the lesser of them from the greater , I find the difference of them 21 gr . 45 min. The summe I number in the line AE , and the difference in DC ( because it is in Summer ) and to the termes I apply the threed , and where it crosseth the parallel of the beginning of 8 , there I meet with 66 gr . 43 min. which is the Azimuth from the South , being reckoned from the line AE whereon the Summe was counted . Example 2. The latitude and Sunnes place being the same if the altitude had beene 9 gr . 15 min. The summe of the latitude and altitude would bee 61 gr . 45 min. The difference 43 gr . 15 min. and so the threed applyed to these termes would have shewed 96 gr . 52 min. for the Azimuth from the South . A third Example . In the same Latitude of 52 gr . 30 min. in the Winter-time , the Sunne entring the tenth degree of ♏ , and the altitude being 9 gr . 30 min. I would know the Azimuth of the Sun from the South . I adde the Altitude 9 gr . 30 min. to the Latitude 52 gr . 30 min. and so find the summe of them 62 gr . 0 min. And substracting the Altitude out of the Latitude , I find the Difference of them 43 gr . 0 min. The summe ( because it is in Winter ) I count upon the line DC in the Quadrant , and the Difference upon AE . So the threed applyed to these tearmes cutteth the tenth of ♏ , at 49 gr . 50 min. which is the Azimuth numbred from DC the South . The Amplitude . Note here by the way , That the threed applyed to the Latitude of your place numbred upon both lines AE , DC , will shew you , for any place of the Sunne , the due Amplitude of his Rising or Setting , or the Azimuth whereon hee riseth or setteth , if you number the same from the middle line noted with XZ which here representeth the East and West Azimuths . CHAP. IIII. To find out the Declination of a Plaine . THe declination of a Plaine is numbred from the South or North points towards either East or West . And it is the arke of the Horizon comprehended betweene the South-North , and a line infinitely extended upon the Horizon perpendicular to the horizontall line of the Plaine ; which line may be called the Axis , and the extremity of it , the Pole of the Plaines horizontall line . To find out this declination you must make two observations by the Sunne : The first is of the Distance or angle made betweene the Axis of the horizontall line of the Plaine , and the Azimuth wherein the Sunne is at the time of observation . The second is of the Suns Altitude . Both these observations should bee made at one instant , which may bee done by two observers , but if they bee made by one , the lesse distance of time betweene them , will make the worke to agree together the better . 1. For the Distance . Upon your Plaine draw a line parallel to the horizon , to this line apply the side of your Quadrant , holding it parallel to the horizon . Then holding up a threed and plummer , which must hang at full liberty , so as the shadow of the threed may passe through the center of the Quadrant , observe the Angle made upon the Quadrant by the shadow of the threed , and that side that lyeth perpendicular to the horizontall line , for that angle is the Distance required . 2. At the same instant as neere as may be , take the Sunnes Altitude ; These two being heedfully done , will helpe you to the plaines Declination by these rules following . When you have taken the Altitude , you may find the Sunnes Azimuth by the former Chapter . Then observe , whether the Sunne bee betweene the Pole of the horizontall line and the South North point or not . If the Sunne be betweene them , adde the Azimuth and Distance together , and the summe of them is the Declination of the plaine . If the Sunne be not betweene them , subduct the lesser of them from the greater , and the difference shall be the Declination of the plaine . ¶ By your observation you may know to what coast a Plaine declineth . For if the South North point bee in the midst betweene the Sunnes Azimuth and the pole of the Plaines horizontall line , then doth the Plaine decline to the coast contrary to that wherein the ☉ is : If otherwise , the declination is upon the same coast with the Sunne . CHAP. V. To find the Inclination of a Plaine . THe Inclination of a Plaine is the angle that it maketh with the Horizon . When you have described your horizontall line upon a Plaine , as in this figure EF , crosse it with a perpendicular GH , for the Verticall line . And because the inclinations of the Upper and Under faces of the Plaine , are both of one quantitie in themselves , if therefore you apply the side of the Quadrant noted with AB unto the verticall line of the under face , or to the under side of a Ruler applyed to the verticall line of the upper face , as is here shewed in this figure ; Then shall the degrees of the Quadrant give you CAD the angle of inclination required . CHAP. VI. Of upright declining Plaines . THose Plaines are upright , which point up directly into the Zenith or verticall point of the Horizon , and may be tryed by a perpendicular or plumb-line . In these , as in the rest that follow , before the Houres can be drawne , two things must bee found ; 1. The Rectifying arke ; 2. The Elevation of the Pole above the Plaine . 1. To find the Rectifying arke . Extend the threed from your Latitude counted in the upper Quadrant of the circle on the backeside , to the complement of the Plaines declination numbred in the Semi-circle ; so shall the threed shew you on the Diameter the Arke required . 2. To find the Elevation of the Pole above the Plaine . Extend the threed from the Rectifying arke numbred in he upper quadrant , to your Latitudes complement taken in the Semicircle ; so shall the threed shew upon the Diameter , the Elevation of the Pole above the Plaine . According to these rules , in the latitude of 52 gr . 30 min. supposing an upright Plaine to decline 55. gr . 30 min. I find the Rectifying arke to bee 28 gr . 36 min. And the elevation of the Pole above the Plaine to be 20 gr . 10 minutes . CHAP. VII . In East and West incliners . THose plaines are called East and West incliners , whose horizontall line lyeth full North and South , and their inclination is directly towards either East or West . 1. To find the Rectifying Arke . Extend the threed from your Latitudes complement taken in the upper quadrant of the Circle on the backside , to the complement of the Plains inclination counted in the semicircle ; so shall the threed shew upon the Diameter the Arke required . 2. To find the Elevation of the Pole above the Plaine . Extend the threed from the Rectifying-arke counted in the upper quadrant , to your latitude taken in the Semicircle ; so the threed upon the Diameter gives the elevation of the Pole above the Plaine . Thus in the latitude of 52 gr . 30 min. If a Plaine incline Eastward 40 gr . to the horizon , the Rectifying-arke will be 35 gr . 58 min. And the elevation of the Pole 37 gr . 26 min. above the plaine . CHAP. VIII . In North and South incliners . SUch Plaines are called North and South incliners , whose horizontall line lyeth full East and West , and their inclination is directly upon either North or South . 1. For the Rectifying-Arke . There is no use of it in these plaines , because they all lye directly under the Meridian of the place . 2. To find the Elevation of the Pole above the Plaine . If the inclination be toward the South , adde the inclination to your latitude ; for the summe is the Elevation of the pole above the Plaine . If the summe exceed 90 degrees , take it out of 180 , and the supplement gives you the Poles elevation . If the inclination bee Northward , compare the inclination with your latitude , and subduct the lesser out of the greater : the Difference is the elevation of the Pole above the Plaine , If there bee no difference , it is a Direct polar Plaine . CHAP. IX . In declining Incliners . THose Plaines are called Declining incliners , whose horizontall line declineth from the East or West , towards either North or South , and their inclination also deflecteth from the coasts of North and South towards either East or West . The best way to find the Rectifying-arke , and the poles elevation for these Plaines , will be First , to referre them to a New latitude , wherein they may lye as East or West incliners . For which purpose you are first to find out an Arke , which in respect of its use may fitly be called , The Prosthaphaereticall arke , it is found by this rule : ¶ Extend the threed from the complement of the Plaines declination counted in the upper quadrant , to the inclination numbred in the Semicircle ; so the threed shall give you upon the Diameter the Prosthaphaereticall-arke required . This Prosthaphaereticall-arke is to be used as the Inclination was in the precedent Chapter . For , If the Plaine doe incline towards the South , it must be added to your Latitude : and so the summe ( if lesse then 90 degrees ) gives you the New Latitude : but if the summe bee greater than 90 , then the residue , or supplement of it to 180 degrees will be the New Latitude required . If the Plaine incline toward the North , compare this Prosthaphaereticall-arke with your Latitude , and subduct the lesser of them out of the greater ; So the Difference shall give you the New Latitude . If there be no difference , it is a declining Polar plaine . Secondly , it will be required to know what Inclination these Plaines shall have in this their New latitude ; and that is done by this rule : ¶ Extend the threed from the Prosthaphaereticall-arke taken in the upper quadrant to the Plaines declination counted in the Semicircle : so the threed shewes on the Diameter , the New-inclination in their New latitude . Being thus prepared , you may now proceed as in East and West incliners you did before . 1. To find the Rectifying-Arke . Extend the threed from the New latitudes complement taken in the upper quadrant , to the New-inclinations complement numbred in the Semicircle ; so the threed upon the Diameter shewes the Arke required . 2. To find the Elevation of the Pole above the Plaine . Extend the threed from the Rectifying-arke in the Vpper-quadrant to the New latitude in the Semicircle ; so the threed upon the Diameter gives the Elevation of the pole above the plaine . According to these rules , supposing a Plaine to incline towards the North 30 degrees , and to decline from the South towards the West 60 degrees in the latitude of 52 gr . 30 min. First I find the Prosthaphi-arke 60 gr . 6 min. and because the Plaine inclineth toward the North ; I compare this arke with the Latitude of the place , and taking it out of the Latitude there remaineth 36 gr . 24 min. for the New Latitude . Then I find the New inclination to bee 25 gr . 40 min. and so the Rectifying-arke 59 gr . 8 min. and the Elevation of the Pole above the Plaine to be 32 gr . 20 minutes . CHAP. X. To draw the Houre-lines upon the Horizontall , the full North or South plaines , whether standing upright or inclining . IN the foure last Chapters we have seene the uses of the Circle on the backe-side of the Quadrant : in this and the next Chapter we shall shew the use of TR the line of latitudes , and of TV the line of Houres ; which two lines with the helpe of the limbe VCTB , and of the threed and Bead , will serve to pricke downe any Diall , by the Precepts hereafter delivered . And first we begin with those Plaines which have no declination , whose Poles lye directly under the Meridian of the place ; of which sort are the Horizontall , the Erect South and North plaines , with all Incliners looking directly North or South . Having then by the former Precepts found the Elevation of the pole above your Plaine , you may begin your draught in this manner . First , Draw the line RAT of sufficient length , and out of the line of Latitudes in your Quadrant , take off the Elevation of the pole above the plaine , and pricke it downe from the point A , unto R and T both wayes . 2. Take the line of Houres TV also out of the Quadrant , and with that extent of your Compasses upon R and T as upon two centers , draw the arkes BV and CV , crossing each other in V ; and draw the lines RV and TV : then comming to your Quadrant againe ; 3. Apply the threed to every houre point in the limbe VT or CB , as first to s , or r , so shall it cutte the Line of houres TV in 1 ; Then take off with your Compasses T1 , and pricke it downe here from V to 1 , and from T to 7. Again , Apply your threed to the next houre in the limbe at n or m , it will cut the Line of houres TV in 2 take off T2 , and prick it down here from V to 2 , and from T to 8. So againe , the threed applyed to the third noure at y , or u , cuts the line TV , in 3 ; take off T3 , and pricke it downe here from V to 3 , and from T to 9. In like manner , the threed applyed to the fourth houre at o , or i , will cut the line TV in 4 take off T4 , and pricke it downe here from V to 4 , and from T to 10. So also the threed laid upon the fifth houre at e , or a , cutteth TV in 5 ; take off T5 , and prick it downe here from V to 5 , and from T to 11. Thus are all the Houres pricked downe . An horizontull Diall to 52 gr : 30 m : lat : Lastly then , laying your Ruler to the center A , through each of these points , you shall draw the houre-lines A7 , A8 , A9 , A10 , A11 , AV which is 12 , A1 , A2 , A3 , A4 , A5 , RAT is the line of the two sixes . So having 12 houres , which is halfe the Diall , drawne , you may extend the necessarie lines , as many as you will , beyond this center , as 5A5 , 4A4 , 7A7 , 8A8 , &c. In the same manner may the halfe houres bee pricked downe and drawne , by applying the threed to the halfe houres in the limbe , &c. And note also that in these Plaines before mentioned ; As the extent from V to 1 , is the same with that from T to 7 , so likewise is it the same with V11 , R5 ; And as V2 is the same with T8 , so likewise is it the same with V10 , R4 : So likewise V9 and T9 are all one , and both equall to R3 and V3 . So that the three first houres taken from the Quadrant , that is to say , T1 , T2 , T3 , will give all the houres for these Dialls . T1 , gives V1 , V11 , R5 , T7 . T2 , gives V2 , V10 , R4 , T8 . T3 , gives V3 or R3 , V9 or T9 . But in other Plaines it is not so , for which cause I have rather set downe this way before at length , as a direction for what comes after , for that is generall . Here note againe , that if you desire to make your draught greater , you may in your description either double or triple every length which you take in your Compasses . And so I proceed to all declining Plaines . CHAP. XI . To draw the Houres upon all sorts of declining Plaines , whether erect or inclining . BY the former precepts you must first get the Rectifying-arke , with the Elevation of the pole above the Plaine . After they are had , you may pricke downe the Houre points in this manner following , little differing from the former . A Plaine ▪ inclininge Eastward 40 gr : The horizointall line , parallel to the line of 12. 1. Asbefore ; Upon the line RAT , set off the Elevation of the pole above the plaine , being taken out of the line of latitudes in the Quadrant , from A both wayes , to R and T. 2. Take the line of Houres TV out of the Quadrant , and with that extent upon R and T as upon two centers , describe the two arkes BV and CV crossing at V , and draw the lines RV , TV , and AV. Thus farre we goe along with the last Chapter . 3. If we take the example in the seventh chapter , that plaine is the upper face of an East incliner , whose Elevation is 37 gr . 26 min. and so much doth this line TA reach unto in the line of Latitudes : the Rectifying arke is 35 gr . 58 min. This arke I number below in the limbe of the Quadrant ES , and thereto applying the threed I observe in the upper limbe Vcb T which of the Houres and where it cutteth , I find it to cut the slope line o u in the point P ; to this point P I set the Bead , which by this meanes is rectified and fitted to the description of the Diall . Here you see the use of the Bead , and the reason why this arke counted upon the limbe is called the Rectifying arke : and here bee carefull that you stretch not the threed . 4. The threed and Bead being thus placed and rectified , you shall see the threed to cut the line TV at a upon the Quadrant ; take T a in your Compasses , and pricke it downe here from V to 12 , and from R to 6. Here by the way observe , that because this plaine is an Eeast-incliner , the face of it looketh toward the West , and then if you imagine the true scituation of this Diall upon the plaine whereon it must stand , you will easily conceive that the line of 12 is to stand on the right hand from the line AV. and so the line of 6 on the left hand , whereas if this plaine had faced toward the East , the line of 12 must have stood on the left hand , and 6 on the right hand . Your owne conceit , together with the precepts of the chapter following , must helpe in this , and in other things concerning the right scituating of the lineaments of your Diall . To proceed then , In the same manner must you apply the Bead to every houre line , as in the next place I remove it to the line y m in the Quadrant , and then I see it to cut the line TV in b ; I take 1 b in my Compasses , and with it doe pricke downe from V to 1 , and from R to 7. Againe , the Bead being applyed to the lines nr , sb , the threed will cut the line TV upon the Quadrant in c and d ; I take the points TC , Td , in my Compasses , and pricke them downe from V to 2 and 3 , and from R to 8 and 9. Then againe , the Bead applyed to the lines ei , Va , the threed will cut the line TV in the points e and o ; I take then Te and Tf , and pricke them downe from U ●o 11 and 10 , and from R to 5 and 4. 5. Lastly , lay your rule to A , and draw A10 , A11 , A12 , A1 , A2 , A3 , A4 , A5 , A6 , A7 , A8 , A9 . Thus have you twelve houres , and if you extend these beyond the Center , you shall have the whole 24 houres , of which number you may take those that shall bee fit for the Plaine in this scituation . The halfe houres may thus bee pricked on and drawne also , by applying the Bead to the halfe houres pricked downe in Vcb T the upper limbe of the Quadrant , for so the threed will give you the halfe houre points upon the line TV , which may be taken off , and set downe upon the Diall as the houres themselves were . CHAP. XII . How to place the Diall in a right Scituation upon the Plaine . AFter the houre-lines are drawne by the last Chapter , they are to be placed in a right scituation upon their Plaine . Which to doe , upon some Plaines is more difficult than the Description of the Diall it selfe . To give some directions herein , I have added this Chapter , where you have 9 ▪ Questions with their Answers , giving light sufficient to what is here intended and required : but first be admonished of three things . 1. That the inclination mentioned Chap. 8. is the very same in Use with the Prosthaphaereticall arke mentioned Chapter 9. And therefore when I mention the Prosthaphaereticall arke , because it is of most frequent use , you must remember I meane both the Prosthaph : arke , Chap. 9 , and the Inclination , Chap. 8. 2. That these rules , though given primarily for places of North-latitude , lying within the Temperate , Torrid , and Frigid Zones , yet are also as true , and may bee applyed to all places of South-latitude , if we exchange the names of North and South , for South and North. Here by the way note , that the North part of the Torrid Zone extendeth from 0 degrees of latitude to 23 gr . 30 min. the Temperate Zone reacheth from 23 gr . 30 min. to 66 gr . 30 min. the Frigid Zone extendeth from 66 gr . 30 min. to 90 gr . of latitude . And so I come to the 9 Questions . 1. What Pole is elevated above the Plaine . Upon all Upright plaines declining from the North : Upon the upper faces of all East or West incliners : Upon the upper faces of all North-incliners , whose Prosthaph : arke is lesse than the latitude of the place : On the under faces of all North-incliners , whose Prosthaph : arke is greater then the Latitude of the place ; and on the upper faces of all South-incliners , The North pole is elevated . And therefore contrarily , Upon all upright Plaines declining from the South : On the under faces of all East and West , and South incliners : On the under faces of all North-incliners , whose Prosthaphaereticall arke is lesse than the Latitude of the place : On the upper faces of all North-incliners , whose Prosthaph : arke is greater than the Latitude of the place , The South pole is elevated . 2. What part of the Meridian ascendeth or descendeth from the Horizontall line of the Plaine ? In all Upright plaines the Meridian lyeth in the Verticall line , and if they decline from the South it descendeth , if from the North it ascendeth . Upon both faces of East and West Incliners the Meridian lyeth in the Horizontall line . In all North-incliners , the North part of the Meridian ascendeth , the South part descendeth : in all South incliners the South part of the Meridian ascendeth , the North part descendeth : upon both upper and under faces . And if these North and South incliners be direct , then the Meridian lyeth in the Verticall line , and so maketh a right angle with the Horizontall line : but if they decline , then the Meridian on the one side maketh an acute angle with the horizontall line . 3. To which part of the Meridian is the style with the substyle to be referred , as making with it an acute angle ? The style is the cocke of the Diall ; the substyle is the line whereon it standeth , signed out in the former descriptions by the letters AV. In all Plaines whereon the North pole is elevated , it is referred to the North part of the Meridian , and maketh an acute angle therewith . In all Plaines whereon the South pole is elevated , it is referred to the South part of the Meridian , and is to make an acute Angle therewith . Except here only those South-incliners , whose Prosthaph : arke is more than the complement of your Latitude : for on these plaines the substyle standeth on that part of the Meridian , whose denomination is contrary to the Pole elevated above the Plaine . For on the upper faces the North pole is elevated , but the substyle standeth toward the South end of the Meridian : and on the under 〈◊〉 the South pole is elevated , but the substyle lyeth toward the North end of the Meridian . Note here , that in South-incliners whose Prosthaphaereticall arke is equall to the complement of your Latitude , the substyle lyeth square to the Meridian upon the line of 6 a clocke ; which line in such plaines alwayes lyeth perpendicular to the Meridian line . Amongst these falleth the Equinoctiall plaine . 4. On which side of the Meridian lyeth the substyle ? In all direct plaines it lyeth in the Meridian . In all Decliners it goeth from the Meridian toward that coast which is contrary to the coast of the plaines declination . And so doe all houres also goe upon the Plaine to that coast which is contrary to the coast whereon they are ; As all the morning or Easterne houres goe to the Westerne coast of the Plaine , and all the Evening or Westerne houres goe to the Easterne coast of the Plaine . Which being observed will bee a great helpe to place them aright . 5. What plaines have the line of 12 upon them , and which not ? All upright Plaines , in all latitudes whatsoever , declining from the South have the line of 12 ; and decliners from the North in the temperate Zone have it not , but in the other Zones they also have it . The upper faces of East and West incliners in all Latitudes have it , the underfaces have it not . The upper faces of all North incliners whatsoever have it ; their under faces in the Temperate Zone want it , in the Frigid Zone have it , and in the Torrid Zone likewise if the Prosthaph : arke bee greater than the Sunnes least North Meridian altitude , but if it be lesse they want it also . For South incliners , consider the Sunnes greatest and least Meridian altitude upon the South coast . For if the Prosthaphaereticall arke bee such as falleth betweene them , that is , if it be greater than the least , or lesse than the greatest , then have bothsides the line of 12 upon them ; but if it be lesse than the least , then doth the Underface want it universally , and the upper face alone hath it ▪ if greater than the greatest , then doth the Upper face want it , and the under face alone hath it : Except in the Frigid Zone where the upper face hath it also , by reason of the Sunnes not setting there for a time . 6. Whether the North or South part of the Meridian serveth for the line of 12 ? In those Plaines that have the line of 12 , where the North pole is elevated , there the North part of the Meridian serveth for 12. and where the South pole is elevated , there the South part of the Meridian serveth for the line of 12 or mid-day . Except , in all Latitudes , the under faces of those South incliners , whose Prosthaphaereticall arke falleth betweene the Sunnes greatest and least Meridian altitudes , for in them the South pole is elevated , but the North part of the Meridian serveth for the line of 12. Except in speciall those Upright Plaines in the Torrid-zone which looke toward the North , and the Under faces of North-incliners also , whose Prosthaphaereticall arke is greater than the least North-meridian-altitude ; for these have the South or lower part of the Meridian serving for 12 , though the North pole be elevated . 7. Which way the style pointeth , and how it is to bee placed ? In Plaines where the North pole is elevated , it pointeth up towards it ; and where the South pole is elevated , it pointeth downe towards it . The style lyeth perpendicularly over the substyle , noted in the former figures with AV , and is to be elevated above it to such an angle as the Elevation of the pole above the Plaine shall be found to be by the 6 , 7 , 8 , and 9 Chapters . 8. When is it that that part of the Meridian next the substyle , and the line of twelve doe goe contrary wayes ? In all Latitudes , Upon the upper faces of South-incliners , whose Prosthaphaereticall arke is greater than the complement of the Latitude , but lesse than the Sunnes greatest South Meridian altitude : And on the Under faces of those South-incliners also , whos 's Prosthaph : is lesse than the complement of the Latitude , but greater than the Sunnes least South meridian altitude : In the Torrid-Zone alone you must adde hither also , North upright Plaines , and those North-incliners on the Under-face , whose Prosthaphaereticall-arke is greater than the least North-meridian altitude of the Sun ; for these have the line of midday standing on that coast which is contrary to the coast of that part of the Meridian next the substyle , and none else . The line of 12. I call herethe line of midday because in the Frigid-zone , where the Sunne setteth not in many dayes together , there are two twelves , the one answering to our midday , and the other to our midnight : and so all Upper faces of South-incliners , whose Prosthaphaereticall arke falleth betweene the least and greatest South meridian altitudes , have there two 12 a clockelines upon them . 9. How much the Meridian line ascendeth or descendeth from the Horizontall line ? The quantity of the Angle is to be found upon the circle on the back-side of your Quadrant , in this manner ; Extend the threed from the complement of the Plaines inclination taken in the lower Quadrant , to the complement of the Plaines declination counted in the Semicircle , and the threed will shew you upon the Diameter , the degrees and minutes of the Meridians Ascension or Descension . In the example of the 9. Chapt. taking the Upper face of that Plaine , I find the Meridian to ascend above the Horizontall line 33 gr . 41 minutes . ¶ These directions are sufficient for the bestowing of every line into its proper place and coast . As may bee seene in the Example of the ninth Chapter . For , First , upon the upper face of that North incliner , because his Prosthaph : arke 16 gr . 6 min. is lesse than 52 gr . 30 min. the Latitude of the place , therefore the North pole is elevated above it : by the Answer to the first Quest. 2. Because it is a North-incliner , therefore the North part of the Meridian ascendeth above the Horizontall line , by the answer to the second Question . 3. Because the North pole is elevated , therefore the Style with the substyle maketh an acute angle with the North end of the Meridian , by the Answer to the third Question . 4. Because this Plaine declineth toward the West , therefore the substyle lyeth on the East-side of the Meridian , and so doe the houres of the afternoone : by the Answer to the fourth Question . 5. This Plaine , being the Upper face of the North-incliner , will have the line of 12 to bee drawne upon it , by the Answer to the fifth Question . 6. Because the North Pole is elevated , therefore the North part of the Meridian serveth for the line of 12 : by the Answer to the sixt Question . 7. Because the North pole is elevated , therefore the style pointeth upward toward the North pole ; by the Answer to the seventh Question . 8. That part of the Meridian next the Substyle , and the line of 12 are both one , and so therefore goe both one way : by the Answer to the eight Question . 9. By the second the Meridian line ascendeth , and the quantity of the ascent is 33 gr . 41 min. above the Horizontall line : by the Answer of the ninth Question . Thus you see every doubt cleared in this example : the like may be done in all others . CHAP. XIII . The making and placing of Polar Plaines . Place this Diagram betweene folio 32. and 33. The horizontall line of the Plaine . These Plaines may have Dialls described upon them by this Quadrant , but the better way is the common way , to protract them by an equinoctiall circle , for otherwise the style will be alway of one distance from the Plaine , be the Diall greater or lesser . The Polar plaines that decline , before they can be described , must have their New-inclination known , and then their delineation will be easie , the manner of it may be seene in this Example . Suppose the upper face of a North-inclining Plaine , lying in the Latitude of 52 gr . 30 min. to decline from the South toward the East 68 gr . and to incline towards the North 73 gr . 57 min. you shall find by the ninth Chapter , the Prosthaph : arke to be 52 gr . 30 min. the same with the Latitude of the place , and therefore you may conclude this plaine to be Polar . By the same Chapter you shall find the New inclination to be 63 degrees . When you have these you may draw your Semicircle AB4 , and divide it into 12 equall parts for the houres : so signing the new-inclination 63 degrees from A to B , draw CB : and supposing the altitude of your style to be CD , through D draw the perpendicular D 12 ; and where the lines drawne from C through the divisions of the semicircle doe cut the line D 12 , there raise perpendiculars for the houres , and so finish it up as the manner is . The style lyeth directly over and parallel to the substyle CB , & the distance of it from the plain is CD , and in this Example the substyle CB standeth from the line of 12 Westward , because the plaine declineth Eastward , according to the rules in the former Chapter , and so doe the morning houres also . For the placing of the Diall in a true site upon the Plaine , you shall find by the answer to the 9 Quest. in the former Chapter , that the Meridian ascendeth 55 gr . 38 min. for other necessaries , the precepts of the former Chapter will direct you . Onely observe , that in Upright East and West plaine , the line of 6 is alwayes the substyle , and it ascendeth above the North end of the Horizontall line , as much as the Latitude of the place commeth to . FINIS . AN APPENDIX Shewing a ready way to find out the Latitude of any place by the Sunne . BEcause in the third Chapter , and quite through this Treatise , the Latitude of the place is supposed to bee knowne , when as every one perhaps cannot tell which way to find it out ; I thought good therefore to adde this Appendix as a ready helpe to shew how it may bee attained sufficiently for our purpose . Know then that for the finding out of the Latitude of a place by the Sunne , these things are required . 1. To find the Meridian line . The readiest way to find the Meridian line is by the North-starre . This starre is within 2 degr . 37 min. of the North-pole . The North-pole lyes very neere betweene Allioth , or the root of the great Beares tayle , and this starre ; You may therefore imagine where the Pole is , if you conceive a right line drawne from the Pole-starre to Allioth , and by your imagination suppose ⅔ parts of the distance of the next starre of the little Beares taile from the Pole-starre towards Allioth , for there is the very Pole-point . Now then if you set up two poles aslope , and from the tops of them hang two cords with weights at the ends of them , and turne them till you standing on the South-side of them may see them both together with the Pole-point , as it were all in one line , then be sure these two cords doe hang in the Meridian line , or very neere it , yea so neere it , that though you should erre 3 degrees herein ( wherein you need not to erre one degree ) yet will not the Meridian altitude in these Climates ( especially more Northward ) faile you above 3 minutes , which is neere enough to our purpose . I have here given you the chiefe starres of the great and little Beares , that by them you may come to know the starres used in this observation , and so find the very Pole-point it selfe . 2. To find the Sunnes Meridian altitude . Observe diligently about noone when the shadow of the South cord shall fall upon the North cord , for then is the Sun in the Meridian . At that instant observe the Suns altitude stedily and carefully , for that is the Meridian and greatest altitude of the Sun for that day . 3. To find the Sunnes declination . For this purpose the limbe hath the characters of the 12 Signes fixed to each 30 degree , and a scale of declinations under the limbe noted with MN . The Scale is divided by this table ; for looke what degr . and min. of the Eclipt . doe answer to the degr . of declination in the table , the same are to be numbred in the limbe , and by a ruler applyed to them , the degrees of declination are drawne upon the Scale . A Table to make the Scale for the declination of every part of the Eclipticke . Degr. of decl . Deg. of the ecl . Degr. of decl Deg. of the ecl . Degr. declin . Degr. eclipt . Degr. declin . Degr. Eclipt Degr. declin . Degr. Eclipt . Degr. declin . Degr. Eclipt . 0.0 0.00 4.0 10.04 8.0 20.26 12.0 31.26 16.0 43.44 2.0 59.04 0.15 0.38 4.15 10.43 8.15 21.06 12.15 31.09 16.15 44.34 20.15 60.14 0.30 1.15 4.30 11.21 8.30 21.46 12.30 32.52 16.30 45.25 20.30 61.26 0.45 1.53 4.45 11.59 8.45 22.26 12.45 33.36 16.45 46.17 20.45 62.41 1.0 2.31 5.0 12.37 9.0 23.06 13.0 34.21 17.0 47.09 20.0 46.00 1.15 3.08 5.15 13.16 9.15 23.46 13.15 35.05 17.15 48.03 21.15 65.22 1.30 3.46 5.30 13.54 9.30 24.27 13.30 35.50 17.30 48.57 21.30 66.48 1.45 4.24 5.45 14.33 9.45 25.08 13.45 36.35 17.45 49.52 21.45 68. ●● 2.0 5.01 6.0 15.12 10.0 25.49 14.0 37.21 18.0 50.48 22.0 69.58 2.15 5.39 6.15 15.51 10.15 26.30 14.15 38.07 18.15 51.45 22.15 71.44 2.30 6.16 6.30 16.30 10.30 27.12 14.30 38.54 18.30 52.43 22.30 73.41 2.45 6.55 6.45 17.08 10.45 27.53 14.45 39.41 18.45 53.43 22.45 75.53 3.0 7.33 7.0 17.48 11.0 28.36 15.0 40.28 19.0 54.44 23.0 78.30 3.15 8.10 7.15 18.27 11.15 29.17 15.15 41.16 19.15 55.47 23.15 81.52 3.30 8.48 7.30 19.6 11.30 30.00 15.30 42.05 19.30 56.50 23.30 90.00 3.45 9.26 7.45 19.46 11.45 30.43 15.45 42.54 19.45 57.56 Finis . Before you can find the Declination , you must know the Sunnes place , and for such as know not the use of the Astronomicall tables , an Almanacke will serve , where for every day at noone , you shall find the Sunnes place in signes , degrees and minutes . The degr . and min. must bee numbred in their Signes upon the limbe , and the threed applyed thereto will shew the declination answerable . As for example . September 21. 1637 in the Almanack for this yeare , the Sunne is found to be in 8 gr . 23 min. of ♎ . In the Quadrants limbe I looke for the Signe ♎ and number there , 8 gr . 23 min. whereto apply the threed , I find it to cut in the scale of Declinations 3 gr . 20 min. 4. By the Meridian Altitude , and declination of the Sun had ; how to find the Latitude of the place , or the Elevation of the Pole above the Horizon . Compare the Sunnes Meridian altitude and declination together , and if the Sunne be in a North Signe as ♈ ♉ ♊ ♋ ♌ ♍ , then substract the declination out of the Meridian altitude , so shall the difference give you the height of the Equinoctiall . But if the Sun be in the South Signes , as ♎ ♏ ♐ ♑ ♒ ♓ , then adde the declination to the Meridian altitude , so shall the summe give you the height of the Equinoctiall , which being taken out of the Quadrant or 90 degrees , leaveth the Latitude of your place , or the Elevation of the Pole above your Horizen . For Example . Upon the 21 of September 1637. I observed the Sunnes altitude in the Meridian to be 34 gr . 10 min. Upon which day I find the Sunnes place to be ( as before ) 8 gr . 23 min. of ♎ , and the declination 3 gr . 20 min. And because the Sun is in a South signe , I adde this declination and Meridian altitude together ; the summe 37 gr . 30 min. is the altitude of the Aequator , and this taken out of 90 degrees leaveth 52 gr . 30 min. for the Latitude of Coventrie .