Monday, October 18, 2021

Geometry of the Old First Church Fanlight - an Addendum


The first post about the design of the fanlight is here: https://www.jgrarchitect.com/2012/12/old-first-church-bennington-part-2.html

Considering the 'leaves' of the fanlight,  those 3 curved petals that fan out from the base of the light: how did Lavius Fillmore, the master builder, and his crew, especially Asa Hyde, the joiner, derive the pattern?

The layout that I drew of the leaves in the last post is too complex.

 

 The church is graceful and direct. 

 

The derivation in the previous post of the leaf pattern is not direct.
The geometry of the church is straight forward. The use of the circle to layout the framing, the design, would have been clear to other people in construction and to the church's congregation, as well as to anyone in that time who was educated beyond grammar school.

      

 

 

And then there's this diagram in my last post: 

I drew the way the scallops on the curve of the light can overlap simply by rotating the circles one half a petal's width around the circumference, or 15*.

It is also the pattern of the leaves, just at a scale too big for the fanlight.


 

 

 

Drawn smaller, the pattern has 3 overlapping circles at its center, across what would be the sill of the fanlight.  Here the circles come first; the leaves come from the pattern; the fanlight, its size and placement, come from the width of those combined circles.   

However, the pattern in the The Old First Church fanlight was laid out knowing the dimensions for the fanlight. The door and its surround, the placement and size of the door in the main elevation, the width and height of the fanlight were determined by the geometry of the building. They were fixed.

So: given the width and height (about 60"w x 30"h)  how were the leaves' sizes determined? 

The 3 circles across the sill were overlapped. If they were 3 in a row the proportions would be 1/1/1. Then the width could be divided into 3 equal parts. Instead the proportions of the circles are 8/6/8, or 22 equal parts.  Dividing a line into 22 segments with a compass and straight edge is complex.


 

The center lines  (faint pencil lines here) of one set of the fanlight's scallops meet at the center of the fanlight  These are the scallops that the leaves point to.



The distance between the scallops and the center of the fanlight is the diameter of the circles that will make the leaves.

The red spots are the centers of the circles.

 

  

The first 3 circles: where they cross each other and the sill they mark the centers of the next circles.

 

The 4 outer circles. The ones that continue below the sill are not completely drawn.  Note that even though the center circle begins the design it was not needed here. It was understood implicitly by the joiner laying out the pattern.

Below is the layout of the leaves with all the circles included. 


 

 

 

Sunday, October 3, 2021

Geometry of the Old First Church Fanlight

 

 

This is the fanlight over the main door to the Old First Church, built in 1803-5 in Bennington, Vermont. Lavius Fillmore was the Master Builder; Oliver Abel, his Master Carpenter, and Asa Hyde, the Joiner and carver.  

 The fanlight design consists of 2 parts: the 'scallops' around the curve and the 'leaves' coming up from the base. It is simple, graceful.

How was it laid out? In 2012 - when I first wrote about this fanlight - I knew the geometry for the scallops around the curve - expanded daisy wheels on the horizontal and the vertical axis. 

The 3 leaves below the scallops?  I was lost.

Laurie Smith - English timber framer, historian, geometer, the most knowledgeable person I know about the use of circle geometry in medieval design and construction - provided an answer.
Here was our geometry for the fan light in 2012.  Now, in 2021, I think it is probably not how Lavius Fillmore laid out the pattern. 

I post it because we are teaching ourselves. We are constantly learning more about how to use Practical Geometry (or 'Architectural Geometry'). One solution is not the only one. 

A square can be  derived from a circle in many ways - as can a 3/4/5 rectangle - both done using only a compass, straightedge and a marking tool. To see how the geometry can be followed and bring different designers seeing different paths, arriving at the same solution, is valuable.

 

 

 The  circle, its 6 points around the circumference laid out by the radius of the circle, is set on a line which defines the shape of the fan light.


 



 

The circle is surrounded by 6 circles which have their centers on the 6  points. The center pattern is a daisy wheel with 'petals'.



 The circles expanded.

 


 

This set of circles around the original circle adds petals 
to the exterior of the first circle. Add the fanlight shape and the petals  become scallops around the arc of the fanlight.

 

 


 

 

 Rotate the circles 15*  - or 1/2 a petal - and the fanlight's scallops' locations change.

Overlapped, the daisy petals create the double scallops around the Old First Church fanlight. See the photograph above.

 

 


The overlapped petals are also the pattern of the 'leaves' in the  fanlight: too big, not in the right location, but crossed as are the leaves. 


 

Here is how the leaves could have been added. These steps are our 2012 solution.

Add regulating lines from the center of the circles to the second ring of circles and center lines in the petals.






 

Connect the center points of the scallops to each other. Where they cross the petals is the center of the small circles which form the leaves. 

 

 

 

 

 

 

The radius of the circles is the distance from the center of the petal to the scallop.

 

 

 


 

 

 


 

 

I've drawn it in red to make it more visible. It is a complex layout for a seemly quiet, unassuming design.

This pattern was drawn at about 3/8" = 1'-0".  A scale of 1"=1'0" might have been easier. However it would still be tiny here on the page. For clarity I left out the overlapping scallops.




 

 

my drawing in 2012:



The real fanlight was laid out full scale - 5+ feet across -  on a framing table or floor. The proposed design sketch would have been studied, the arcs drawn with a compass using chalk or charcoal, the lines checked, redrawn, the points pinned.  Finally, when the regulating lines were erased, the simple, clean design was visible.



I would like to have been there, listening, watching. as the men drew this.  I think they were pleased as they derived the pattern and settled on a design.  It's not structural at all. It's one of the first things you see, an introduction to the church. It's also their signature.

Then -  I realized that this derivation is not simple enough. 

My Addendum is my current solution, my current understanding of how Lavius Fillmore, Oliver Abel, and Asa Hyde designed the fanlight. https://www.jgrarchitect.com/2021/10/geometry-of-old-first-church-fanlight.html

Monday, August 23, 2021

Rockingham Meeting House, Rockingham, VT


The Rockingham Meetinghouse  was begun in 1787, dedicated in 1798.

 After some preliminary analysis of the design and frame I realized in 2014 I needed to see it. I wondered if it would be as spare as the Rocky Hill and Sandown meetinghouses which preceded it.

It is.

 

 

 The site, on top of a hill with a view all around, emphasizes the simplicity of the structure. One can only come to it from below, and like many 18th c. New England buildings it sits upright and confident. It is very impressive.

I returned in 2018 and early 2020,  I updated the geometry as I learned more. I revised the drawings again when I gave a Zoom presentation in spring, 2021. What I first saw as a complicated geometry became simple and direct. 

This is not a dramatic design created by a London architect like Robert Adam to wow his rich patrons. It is a meeting house for a rural community. It is a straightforward layout planned by master builder, John Fuller, for a simple timber frame to be erected by a crew of local citizens.


The Town Fathers specified a building 44 ft. by 56 ft. The HABS drawings read 44'-4" x 56'-6". The difference could easily be the addition of the sheathing and siding to the frame. The porches (the end staircases) are square: 12'-2" x 12'-2". 
The difference could also be that the rule used then and the one we use today differ slightly. I am not sure they had a 'rule'. Poles of various lengths, 4ft., 5 ft., 10 ft., are in some illustrations.

 

'General' John Fuller, the master builder, was also the architect, engineer, framer. He knew the meeting house required an open space in the middle so everyone on the floor and in the balcony could see the preacher in the pulpit - and be seen by him. The pulpit was centered high on one wall, a window behind,the balcony on 3 sides.





 

He laid out a 3/4/5 rectangle. noted here in red. Then he laid out a square in the middle which defined the open space and divided that into thirds to set the columns for the balcony and the posts for the frame. See the black square and columns.


He extended the column spacing - the dashed black lines - to place the posts on the front and rear walls.This made the balcony the same depth all the around.
The porches are squares set in the middle of the west and east walls. The exterior posts were set at the porch corners, not at the 1/3 points of the wall. This also allowed for 2 windows on each side of the porches. 

 

 

 

Those 4 closely spaced posts in the center support the 4 attic trusses which are braced together to span the width of the church and allow the center of the meetinghouse to be an unobstructed space.

Walter Wallace, standing in the joined trusses under the ridge, gives a sense of how big the framing is.




 

 

The HABS prints of the End Elevation and the Interior Section for the Rockingham Meeting House are hard to read but their basic dimensions are clear.

The End Elevation is composed of 2 squares. The roof is framed using the 3/4/5 triangle. 

The notation to the right of the rafters says the pitch is a 9/12, modern language for the same thing.

 

 

The porches, the name for the stair towers, are set in the center of the end walls. The diagram shows that if the overall width of the wall is 8 modules (each square divided into 4 equal parts) the porch  is 2 modules wide.  





The proportions are 3-2-3, a graceful rhythm. If instead the massing had been 3-3-3 - all the widths equal - it would have felt dull. 

John Fuller, Master Builder, understood how to create with those simple shapes.  




 

 

The Interior Section shows the roof trusses, all using the 3/4/5 geometry. I've highlighted them in black for visibility

The meeting house height is divided in half horizontally. The columns which support the balcony divide the width of the meeting house in thirds.

If those columns has been the posts in the exterior walls only 1 window would have been possible on each side of the door. As I described above, the posts in the exterior walls were set differently (the black dot/dash line). 

 

 

 

 

With his frame laid out, John Fuller now needed to place the windows. The 6 posts on the front elevation were fixed. To allow any visual space* between the 2 windows on either side of the main door had to framed against the posts.  Here you can see how they were placed; there is no room for casings. 

* 'Visual space': the windows needed to be viewed as separate shapes, not as pairs.    


 

 

 

The red lines on the front elevation show the locations of the 6 bents for the meeting house.

 

One more window was needed on either side of the main entrance.

Where would they fit so that they were part of the whole, not call attention to themselves, and enhanced the main entrance ? 

Fuller used geometry to place the outer windows in relationship with the others. 

On the right side of the entrance is the front elevation as it was built.

On the left the outer windows are shown set in relationship not to the posts, but to their next closest windows and the left side of the elevation. The entrance is flanked, but not crowded by the windows.

 

 

The 'empty' wall to the left becomes part of the geometry. It shares the  proportions, being 1/4 of the wall. It is not 'left over'.

 



You can see the design succeeded. The uneven spacing between the windows is interesting and enlivens the facade, but it does not detract from the main door with its pediment. On either end the stretches of wall without a window anchor the meeting house to its site. 

 

 





Here is the main door. Its height is the determining dimension. Half the height is the radius for a circle and its square, drawn in red. The rotated square is drawn in black. The intersections determine the width of the architrave, the columns. The location of the plinth blocks and the depth of the moldings in the architrave, over the door are governed by the sides of the smaller square to the original circle.







The pediment follows Serlio's instructions:
 half of the width dropped below the base of the pediment - black lines - becomes the point for an arc whose radius -dashed red line - is the distance to the edge of the pediment. The dropped line is extended up to the arc; that marks the height of the pediment.

 

 

 

 

 

 

This way of laying out a pediment is shown in Asher Benjamin's 1797 pattern book:


 

 

The door itself came after the frame was in place. It was built to fit the opening. 

First the door's rails and stiles were laid out. 

Then the Rule of Thirds divided the remaining space in half and sized the panels and the stiles between the panels.

 

 

 

 

Last picture: The windows on the sides of the meeting house were framed against the posts as they also were on the front and rear elevations.

Just as at the Rocky Hill Meeting House in Amesbury, MA, the eaves on the porches bump into those windows. Neither master builder had solved that problem.

 




For excellent information about trusses in meeting houses and churches see Historic American Roof Trusses, Jan Lewandoski, et al., published by the Timber Framers Guild, 2006. www.tfg.org.

The Rockingham Meeting House is not included but the theory, practice, and evolution of the trusses used for similar meeting houses is laid out with clear photographs and Jack Sobon's drawings.

If you do not know how to use of the 'Rule of Thirds' square as a design tool, see: https://www.jgrarchitect.com/2020/08/lesson-6-rule-of-thirds-part-1_21.html 







Monday, July 12, 2021

The Geometry of Gunston Hall's North Porch


This post is about exploring Practical Geometry, getting lost, and finding the simple answer. I have used my working  drawings to show the process. Faint lines show where I erased possibility that didn't work.

 

Gunston Hall was the home of George Mason, a Virginia planter, with a big family, lots of land, and many enslaved people. He was one of the delegates to the Constitutional Convention in Philadelphia is 1787.

He was also a mason: he advised George Washington about mortar mixes. 

When he had his house built, in 1754, he made the formal dining room and parlor (on the right side of the house in this picture) larger than the family parlor and chamber (on the left side of the picture).  

 

That meant that the house was not symmetrical around the door.  (To see this look at the spacing between the windows on the left and right sides.) The lack of balance might have distracted those arriving to either the north or the south entrance. However the small door and windows at the entrance were probably more jarring.

William Buckland, a young architect just come from England, solved the problem. The porches he designed are so inviting they make the asymmetry is almost invisible. More importantly they enveloped the existing entries.

In  2014, I wrote about the house here: https://www.jgrarchitect.com/2014/05/gunston-hall-ason-neck-virginia.html

The geometry I suggested for the north porch never quite fit. I tried other solutions.  Nothing was much better. I could see the geometry of Buckland's design but I couldn't draw it. 


Here is the HABS drawing of the north porch.

 

 

 

 Here is my attempt to understand what geometry had guided the proportions of the design.

It's neat. It seems to work until you consider that the intersections of the lines do not tell the carpenters how to layout the porch, where the parts should go. The diagram is interesting, but gives no useful information.


Here is a later exploration when I still wanted the diagram to describe the porch design.

Perhaps my initial square was too large, not based on the right width or height?

Would a  circle within its square work?

How about a daisy wheel ?  or an octagon?

The pencil lines, the red and blue inked lines are finally just confusing.


6+ years later I changed the question. Not, "What geometry did Buckland use?" Rather, "What was he given?" 

I knew this. I'm an architect who works with existing houses. My first questions about a house are, "What's here? What are the existing conditions?" 

The HABS drawing of the Hall show the north wall, a door with a fanlight and small side windows, a baseboard, a chair rail and an expanse of upper wall with some crown molding.  This is what existed, and seen from the outside,  just too little.

I realized that the main problem was not the lack of symmetry, it was the dinky entrance. The door and lovely fanlight are dwarfed by the expanse of brick, the windows are minuscule. 

Refer to my first picture of the house (above) to see how little the windows are compared to the windows on either side.  

Buckland couldn't change this; he had to work with what was there. 


 

What were the existing dimensions?
One was the height from the sill of the door to the eaves of the roof. Buckland could add inches by adding a step down, but he couldn't easily go higher.

The second dimension was the width. His width couldn't be so large that it drew attention to the uneven spacing of the left and right windows. And: the porch needed to be centered on the door,to  enhance it and its fanlight. The side windows had to be integral to the design.

He used the given height for his width. He drew a square and added the diagonals and the mid-lines. horizontal and vertical.


He added his Lines - upper center of the square to left and right corners.

The square was divided into thirds where the Lines crossed the diagonals. Placing the columns within the 1/3 of the width gave more importance to the door while keeping the rhythm, as well as keeping the steps wide and gracious, the porch airy and open. If the columns had been set on - not beside -  the 1/3 lines the design would have been static, staid.

The points where the Lines crossed the diagonals also marked the edge of the frieze (also called the architrave).

The mid-lines divided the square into 4 smaller squares. When  diagonals were added to the upper squares, where the Lines crossed the diagonals located the height of the frieze, the beginning of the gable, the roof. In the lower squares the Line crossed the diagonals at the top of the hand rail.

I have drawn these  Lines only the right side. The layout is hard to read  when all the Lines are added. On a framing floor. all the Lines would be marked and used to layout the frame.



The arch draws our attention. The half-round shape makes the porch open and welcoming. It frames the main door and its fanlight - inviting you to the house.

Its diameter is 1/3 the width of the porch. It is part of the whole.

 I've drawn it with its cascading circles because it's fun. I also wanted to note how the circle can be a tool for laying out a plan.

Palladio used a circle as his unit of measure: he called it a 'diameter'. His diameter was usually the column in his drawing. Although it's possible that the circle here was also the unit of measure, I think it more likely that it was one element Buckland knew how to use, one that would enhance and unify the porch with the house, especially as its diameter came from the basic geometry of the porch.    


For an introduction to the Rule of Thirds see: https://www.jgrarchitect.com/2020/08/lesson-6-rule-of-thirds-part-1_21.html 


 

An after thought: George Mason used the geometry of the 3/4/5 triangle to layout Gunston Hall, including the dimensions of  his windows. If William Buckland had used the geometry of the square and its circle, its proportions would not have complimented the Hall.