Tag Archives: GIS

Bees, GIS Planning, Silvopasture and Agroforestry

Trees for Bees 6: GIS Map and honorable mention

Other posts in this series:

Trees for Bees introduction

Trees for Bees 2: Planning

Trees for Bees 3: Sumac

Trees for Bees 4: Sourwood

Trees for Bees 5 : Basswood

 

You may notice one species mentioned in the first post is absent: Liriodendron tulipifera aka Tulip Poplar.

“Liriodendron tulipifera tulip close” by Dcrjsr – Own work. Licensed under CC BY 3.0 via Commons – https://commons.wikimedia.org/wiki/File:Liriodendron_tulipifera_tulip_close.jpg#/media/File:Liriodendron_tulipifera_tulip_close.jpg

This species is an abundant nectar producer early in the season helping colonies build up food stores and population numbers. While other bee gardeners are full encouraged to consider this tree, it will not be planted on the farm for a few reasons. Tulip poplars require loose, fertile soils as their roots systems are small, fleshy, soft and to put it succinctly: weak. It is also susceptible to numerous pests and diseases. Combining these attributes with its huge form and full sun requirements, the decision was made to plant the more valuable (regarding bees) Basswood in the vacant locations despite the beautiful blooms that resemble tulips, thus the common name.

Final Plans and Map

Putting everything together, there will be sumacs planted on the hill that raises the farm entrance from the pasture as well as below the powerlines. Sourwoods will be planted between the farm entrance track and the main road as well as along the fenceline in the pasture. Lastly, Basswoods will occupy the areas where they have room to spread.

Note: I apologize for the low res imagery. It is used for faster processing as well as the only aerial image saved offline for when I work on maps at the farm where my cellular data is the only access to internet!

That concludes this series…I hope you aren’t sick of bee talk!

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Garden, GIS Planning

Revisting Garden Planning With GIS

I’ve decided to follow many of the market gardening and urban micro farm literature in preparing my garden. Vertical space and efficient layout are key considerations in planning.

GIS Software mapped the garden beds at 4 feet wide with 2 foot aisles between beds.

bedsOutline

Using a GIS tool that someone published online the garden bed polygons provided the boundaries to create 1×1 ft. grids.  Some unpredictable results were produced from my minorly complex garden bed geometries. I removed all but the two largest polygons to re-run the tool, then copied, pasted and cut the results to replace the other beds.

BedGrids

This GIS tool applied my grid to the garden beds to cut the polygons into 1×1 ft. squares. I ran into the same issue so I deleted all by the western most beds. After running the tool again, I copied the resulting beds and pasted them with 2 foot aisle ways in between. Then I clipped all of the beds to the desired boundary of the garden while adding an additional piece along the main fence. The end result is below

BedsFinal

The point of doing this is that now I can link the individual 1×1 ft rectangles to any piece of data I want. Examples include: plant species, species variety, growth characteristics, water needs, sunlight recommendations, soil preference, composting/mulching/organic fertilizing needs, planting time in relation to frosts, harvest time and ANYTHING else that is even remotely useful. This will help in planning but also garden maintenance and in the future, logging location specific performance over time. With GIS software, I can analyze the latter against 3-D sunlight, elevation, soils, and climatic data when I get bored or want to knock the rust off of the skills of professions past.

 

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Garden

Sustainable, Efficient and Symbiotic Approach to Vegetable Selection (part 1)

My main goal beyond building soil quality is to be self-sufficient. Therefore I am going to focus on growing the staples in my diet and filling out the rest of the garden with vegetables that I enjoy. Maybe I will produce excess to sell but I am not planning on it in the first year. I would like to build an aquaponics system to further stretch waste products, have some fish protein on the menu and further promote soil fertility. Additionally, red wigler worms will be an integral part of composting and will provide winter protein for chickens as well as fish if the aquaponics plans are realized.

In terms of staples, sweet potatoes make up most of my carbohydrate intake so they will be the largest portion of my garden. According to the study “Effect of intercropping varieties of sweet potato and
okra in an ultisol of southeastern Nigeria”, Okra and sweet potato planted together potentially increases yields of both plants. I’m not much of an Okra eater, but they pickle well for preservation so I’m willing to give them a shot. I am going to space each plant out 18″ from its nearest neighbor of the same species which means each plant will alternate every 9 inches. Low vines of the sweet potatoes will act as a living mulch for the erect-growing okra.

Granted, 45 specimens of each plant shown below is more that I need. I will build the garden to its full extent as composting on the farm yields new soil. The plant locations were determined by the same “Construct Points” that I used in mapping fence posts.

Sweet Potato/Okra Symbiotic Planting

Okra_SweetPot_Plants

Next on my list is to get a perennial asparagus bed started. Asparagus will get the fresh veggies going early and are freezable post-harvest. For now I am planning to plant it on the rows closest to the barn where it can be left undisturbed year after year. Basil seems to drive away common pests of asparagus and also is an all around good companion plant in the garden. If basil attracts slugs or snails, I can capture them in a beer trap to give the chickens a treat!

Asparagus/Basil Symbiotic Planting

AsparagusBasilPlants

Thats it for tonight! Any recommendations for the rest of the garden?

Note: When beginning construction of the garden beds, I switched my plan by siting the beds parallel to the west boundary of the garden rather than the east. When I was on location It was easier to determine the best way to work with the gentle hill. I will update the maps soon!

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Garden

Siting Vegtable Garden

To get the most from the relatively small farm, a greenhouse will be built for season extension and to winter the laying chickens while they fertilize the garden (more on this later!). Ideally this will be in a South or Southeast facing location in the barnyard. Unfortunately, the only south facing slop in my pasture is covered in trees. Good news for the wild deer and my goats, but bad news for veggies. So I will work with what I have!

Aspect Map of Barnyard Created from LiDAR Data

AspectGarden

The east facing exterior of the barn looks like a great location. The downward slope to the road in the pasture provides a good location to build a raised bed that will slowly accumulate soil as the farm builds it.

Garden Location:

gardenLocation

The next step is to plan the rows. Avoiding soil compaction when tending to the plants limits the row width to four feet. Incorporating the 2-foot aisles for foot traffic resulted in parallel lines spaced 6 feet apart. The result is shown below

Garden Rows Mapped

GardenRows

Now to plan the vegtables themselves!

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Bees

Siting the First Beehive

An unintended use for the LiDAR data has been made apparent. During my research for beginning beekeeping, I found the consensus among beekeepers was to locate hives where they receive morning sun and afternoon shade. I have not found a scientific source for this so I won’t go into the justifications just yet.

Using the LiDAR data in GIS software, I can create hillshades that show where sun reaches the ground at various points in the day as well as aspect maps. Aspect is the direction the land faces. Using hillshades and verifying with aspect, I found a good spot for the first hive plus solid locations for other hives!

Morning Sun:

HillShadeMorning

Afternoon Sun:

HillshadeAfternoon

Aspect Map with 3D Trees

3dTreesAndAspect

Note that the trees will cast shadows to the NorthEast in the afternoons!

For the initial hive, I chose a small, SouthEast facing clearing in the woods. The sun exposure factors are correct and they will have peace from livestock, laboring farmer and equipment back in the forest. My plan is to grow a perennial, spring food plot in the clearing to give nursing Doe nutrition for their fawns. Clover and Chicory will be the most likely seed (and the only seed I will plant outside of gardens) so hopefully the bees can find enough food year-round with the forest, pasture, vegetable gardens and food plots!

Decision is made!

BeeHiveSite

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General Pasture

Calculating Fencing Costs

Full digitization of fence lines and posts in GIS software makes the basic calculations simple. GIS provides geometry of the digital features including fence length:

Total Length of Permanent Fencing

(In “Sum” field)

FenceLength

Also determined by GIS, I have 26 wooden corner posts and 162 steel line posts in the full phase fence plans. Breaking it down to Phase 1-only shows a need of 23 wood and 119 steel posts.

Those figures alone let me derive most of the other materials needed in simple excel formulas. For example, each wood post requires insulators for both the spark and ground wires, while the leaving the steel posts uninsulated to the ground wire acts to ground it! However I am still trying to research if it is desirable to only leave the steel posts uninsulated at specific intervals. I am also debating if I need to install a gate at every paddock. For now the last question is factored in as affirmative.

For Phase 1 Fencing:

Fence Calc P1

Now with 3 wires added for phase 2 plans, the calculations are as follows:

Fence Calc P2

Other than buying the animals themselves, this should be the biggest investment I have to make!

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Side Projects

Fun With Lidar and Local Lore: Sinkholes!

I decided to have a bit of fun to further research a bit of unsubstantiated lore regard the karst land I will be farming. The previous owner mentioned that local lore told that one of the many sinkholes on the farm opens to a 20′ x 10′ cavernous room.

Here is the raw LiDAR:

Raw Lidar

 

Not much is visible. So when I clip it down so the elevation range is smaller, feature become a bit more apparent:

Clipped LiDAR

However, creating a hillshade layer applies illuminated shadows to the hillshade relief makes the sinkholes pop!

Hillshade

I have no idea how to go about exploring the sinkholes even if I wanted to, but I had fun finding them digitally!

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General Pasture

Mapping the Fence Posts

Lucky for me, there is a built-in tool in GIS software that allows points to be added along lines. I’m going to go ahead and add the points then make modifications to the fence line and posts together.

Constructing Posts:

 ConstructingPosts

Based on recommendation from fence vendors and manufacturers, I want the distance between posts to be no greater than 45 feet. Since I have to chose units in the same coordinate system I am using (State Plane), my input is 16 meters (~40 ft). In the “Construct Point” tool, I choose to create points based on the desired interval, not a total number of posts. Clearly you need posts at the start and end of the fence so that option is selected as well:

ConstructingPosts2

The fence posts will now be outputted to the blank point shapefile in which it was directed. Keep in mind that these are only the permanent fence posts!

For electric fencing, I want well-anchored wooden post for corners and galvanized steel for the line posts. The galvanized posts have an additional benefit of acting as grounding rods for the electric fence system while the braced wooden posts keep everything secure. Symbolized wood/steel posts, cleaned up fence lines and cleaned up post points yield the next iteration of my fence map:

FencePosts

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General Pasture

Mapping the Fences

Now that the paddocks are roughly mapped out, I can start mapping the fencing. My plan is to have multiple rows of permanent fencing running north-south with an east-west gap of about 100 feet. Temporary fencing can be laid east-west and moved daily to create new paddocks. Therefore the paddock area can be adjusted if necessary by how far apart the temporary fences are spaced.

Using maps to optimize the fencing uses additional factors than just creating exact areas. Using the parcels as a basis, elevation is also factored in as the most optimal fence will follow the contours as efficiently as possible. To achieve this I downloaded LiDAR data. LiDAR is collected from an aerial source that broadcasts a laser then senses and analyzes the reflected light. It is one of the most accurate technologies to collect elevation data but it is very expensive. Luckily free LiDAR data is available for my farm, but please consider making a donation to show your appreciation if you use free LiDAR data!

Fencing can now be optimally mapped thanks to high resolution, LiDAR-based digital elevation model (DEM).

LiDAR_Pasture

Now I can do my best to plan the fences based on my paddock area needs as well as keeping the permanent segments as straight as possible and minimizing elevation change where possible.

Fences Mapped:

Fencing_Managmen2

There will still need to be some manual cleanup to close some ends, accommodate developments in planning and work with the trees in the pasture. Here is the starting point for you to follow along!

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Cattle

Determining Paddock Needs

While technology is often is a distraction and detraction to satisfaction, it provides invaluable tools. My planning will be done through Geographic Information Systems (GIS) to maximize performance and efficiency of the farm operation.

Calculated Square Footage: Top Row is with Trees Removed

Acrage2

 

Instead of basing my calculations off of stocking rates and head of cattle, I am going to use the amount of land available.

Through much trial and error, I was determined to find a paddock area that would yield 40 individual paddocks. Complicated by removing trees from my pasture data, I could not simply divide my total area by 40 (although parcel editor seems to be able to accomplish this even though I could not get it to work). So the production process consisted of cutting, merging and various other GIS processes as well as running a python command. Here it is for any other GIS users out there:

arcpy.CalculateField_management(“Pasture_Boundary”,”Acreage”,”!shape.area@squarefeet!”,”PYTHON”)

The python command re-calculates the area of the paddocks in square feet.

In the end, I found that 5,000 square foot paddocks produced 45 ugly-shaped but usable paddocks. Remember that grass growth factors rely on climatic variables. The truth is that grass may not regenerate quickly in a drought situation. So I want to give each paddock at least 30 days of rest with an option for 10-15 to accommodate potential drought situations. I designed 40 paddocks for cyclical use while leaving 5 open for the existing wildlife corridor to be used only if necessary.

Proposed Paddocks

5000sqFT_Parcels

Now it will be easy to determine fencing needs!

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