Built on First Principles

When we use critical questioning to challenging existing assumptions, we dig right down to the building blocks that those assumptions are based on. These building blocks are called first principles.
Aptera is taking the electric vehicle industry to task by asking basic questions to help identify the first principles that they will address:

• What are the biggest issues that are faced by electric vehicles and what challenges are there to creating a new vehicle that will address them?
  • Range - How much distance will the vehicle go before refueling (charging)
  • Charge Time - How much time must be spent in each refueling (charging)
  • Charging Locations - Are the charging locations convenient / available
  • Cost - Electric vehicles are becoming increasingly expensive
  • Difficulty in Manufacturing - There is a significant barrier to entry in bringing a new vehicle to market from scratch
• What are the most basic principles that need to be addressed?
  • Range - Options
    • Use a bigger battery and/or a make more efficient use of energy
      • A bigger battery is more costly, so more efficient use of energy would be preferred
        • Where is the most energy used?
          

          At 65mph, wind resistance uses the most energy. Aptera's unique shape reduces the amount of drag significantly.
          The weight of the vehicle also affects the energy required to keep it moving. Aptera's 3-wheel design and 50% reduction in weight further reduces the total energy usage.

          • Reduce wind resistance (Drag)
            • This accounts for 52-56% or more of total vehicle energy use at 65 mph
            • Reducing drag cuts total energy usage by 26%
          • Rolling resistance
            • This accounts for 43-47% of vehicle energy use at 65 mph
            • Weight reduction
            

            Even with Aptera's tremendously reduced drag and weight reduction, the total vehicle weight has a significant effect on energy usage.

            • Energy usage is reduced by 17% just by reducing the weight by over 50%
            • Every 83 pounds of additional weight in the Aptera reduces overall range by around 1%
          • Heating / Cooling
            • Temperature insulation
              • Since Aptera is effectively a rolling Thermos, it takes less energy to heat and cool
                Note: With other energy drains reduced, heating and cooling the passenger compartment may draw a greater relative percentage of battery life, so range may be significantly reduced in hotter or colder temperatures. Real-world testing results have not yet been provided.
          • Accessories
            • Lights
            • Front Panel Displays
            • Rear-view mirror display
            • Side mirror displays
            • Infotainment screen
            • Data sources
              • Navigation information
              • Entertainment feeds
              • Over-The-Air (OTA) software updates

              Details are still pending as to available services and energy needs

        • Reducing weight and using a more efficient design results in only 42% of the total energy required compared to a Tesla Model S to go the same distance.
  • Charge Time - Options
    • Use a smaller battery
    • Use a faster rate of charging
  • Charging Locations - Options
    • Provide more locations
      Aptera will utilize the Tesla charging network
    • Practical charging at home
      Aptera will be able to be charged using a standard 110v 20A outlet to charge over 100 miles of range overnight.
      A 220v 30A (standard dryer) outlet will give you a full charge (over 400 miles) overnight.
    • Add the ability to charge without a charging station
      • Practical solar charging on the vehicle
        With 700W of onboard solar panels, Apter may capture up to 40 miles of range parked or driving in the sun.
  • Cost - Options
    • Reduce the cost of materials
      • Cheaper battery
        • Use lower cost battery materials
        • Use a smaller battery
          Due to Aptera's thrifty use of power, a much smaller battery can be used for the same or greater range.
      • Use cheaper structural materials
      • Reduce the amount of material needed
      • Create / Use fewer parts Aptera's body is comprised on only six pre-formed parts rather than the 400 or so parts that might otherwise be needed.
    • Reduce the cost of labor
      • Find cheaper labor
      • Require less labor to assemble the vehicle Aptera has many sub-assemblies delivered to the factory. That, in combination with a significant reduction in body parts due to large pre-formed components, allows for faster and easier assembly with a corresponding reduction in labor costs. Many of the parts are pre-formed with assembly 'keys' - much like a Lego - that allow for fast, accurate alignment by hand as opposed to robot or mechanical positioning and forcing parts into place.
  • Reduce the difficulty and expense of manufacturing - Options
    • Distributed sourcing of components
    • Smaller factories
      • Fewer part for final assembly
      • No paint station
    • Fewer / smaller assembly machines
    • Reduced labor force
    • Reduced cost to establish a factory
      • Smaller factory footprint
        • Eliminate painting
          • Up to 30% of total production cost
        • Fewer parts to assemble
      • Develop the easiest / fastest assembly process possible

Aptera will be addressing all of these factors through several key first principles:

• Energy Use
  • Wind resistance
    • Design a vehicle that has the least possible wind resistance
      Aptera has a drag coefficient of only 0.13 - the Lucid Air is currently the production vehicle with the lowest coefficient of drag is 50% less efficient with a drag of 0.197.
  • Light weight
    • Smallest possible battery, as it is by far the heaviest component of the vehicle
      Aptera's battery is less than 1/2 the size of cars with comparable ranges
    • Fewest reasonable number of vehicle occupants
      Takes advantage of the fact that the average number of occupants in a car is just 1.5 persons, so the initial focus is on a 2-seater model.
    • Lightest parts as practical
      • Make use of the latest materials to reduce weight without compromising strength
      • Design each structural component to require the least amount of material without compromising strength and safety
  • Incorporate solar charging to augment and replenish the battery as much as possible
    In most climates, solar charging alone can add up to 40 miles of charge.
• Cost
  • Smallest possible battery, as it is by far the most costly, expensive, and heaviest component of the vehicle
    Half the battery size means half the cost without sacrificing range.
  • Fewest and least expensive parts possible without sacrificing safety
  • Fastest and easiest final assembly possible
    • Outsource as many components as possible
      Aptera only assembles their solar panels on-site. All other components are sub-contracted out and delivered for final assembly.
    • Structural parts are designed for easy final assembly
      Apter's body is comprised of only 15 body parts, including doors and hatches.
    • Use wraps instead of paint
      • Wraps are faster and cheaper than paint
      • Wraps do not require the massive factory cost, space, ventilation, and electrical requirements that paint does
      • Wraps provide an easier way to change or customize vehicle appearance
      • Wraps are energy efficient and have a much lower environmental impact in application

Construction

Design

Aptera's design process is one of the most innovative and effective ones in the industry. Using computer simulations, the shape of the vehicle has been finely calculated to minimize drag. Compared to other vehicles, the Aptera has less than two-thirds the drag of the most efficient Tesla.
Each part has been computer modeled and analyzed for strength and excess material has been eliminated, helping to reduce the overall vehicle weight.
The entire vehicle has been put through extensive simulations to optimize and fine-tune the handling. Real-world measurements conducted on the resulting vehicles found a 95% correlation to the simulations, giving them increased confidence in their methodology.
Aptera's passenger compartment is built along the lines of a Formula-1 racecar with a protective shell that is unsurpassed in the automotive industry.
Every component of the Aptera has been simulated in a computer and designed to fit together perfectly. This will help make Aptera the easiest car to assemble ever.
When the actual parts were manufactured, there were no surprises. Every part had be thoroughly designed and refined in a computer. Every part was assembled in a 3-D simulation before the parts were molded, cast, or built, so everything fit together in real-life exactly as it did in the computer simulation. The fit and finish of the result is nearly perfect.

Minimal parts for final assembly

By utilizing fully-tested, off-the-shelf parts and custom and semi-custom sub-assemblies, the manufacturing process is widely distributed and a relatively small factory can be used to quickly and easily assemble all of these component parts into the final vehicle. In fact, Aptera estimates that a warehouse of only 100,000 sq. ft. and no special facilities can be converted into another Aptera assembly plant.
As each molded component has been designed with efficiency in mind, channels and connections for wiring and other components are already fully incorporated in each molded piece. This cuts down on the various assemblies, and myriad brackets needed to run wiring, mount components, and incorporate each part into the final assembly.
Aptera took a page from Tesla's playbook and is casting the body in just a few parts. The main body of the Aptera, rather than consisting of hundreds of parts, is comprise of just six main molded components and a total of around 15 parts makes up the entire body structure, including hatches and doors.
Each of the parts is designed with 'keys' - built-in alignment guides so that the parts go together like Lego pieces; the alignment is easy and perfect every time! The molded parts all come out perfect. There is no warpage or variation like you find in metal parts. Once molded, the parts are completely rigid and will never degrade or warp.

Environmental Impact

Aptera is designed with cradle-to-grave planning. Many components are derived from recycled or renewable materials, and are designed to themselves be recycled at the end of their lifespan.
The molded parts use dies that are computer designed to have minimal waste, and the waste material that they do have can immediately be recycled into the next piece.
Rather than painting their vehicle, Aptera has chosen to use vinyl wraps. This not only eliminates one of the costliest, most massive production stations, but it also greatly reduces the energy requirements and environmental impact of painting. The wrap is free of volatile organic compounds (VOCs) which are released into the air by paint and cause health issues and contribute to ozone depletion.

Space age materials

CPC Group produces the BinC (Body in Carbon) - the six main pieces that go into the full body of the Aptera. They use Carbon Fiber Sheet Molding Composite (CFSMC) to mold each part. They use large steel blocks that are computer carved to create molds for each piece. The CFSMC material is put into this mold after being roughly laid out in the shape of each piece. These steel molds are heated to about 150 degrees C and pushed together with thousands of tons of pressure. The molds have been built so that the exact volume needed for each piece has been exactly calculated so that there is very little excess. Once the molds are heated initially, they can be used to stamp out parts at the rate of one part every 6-12 minutes, with minimal heat needing to be added for each piece to keep the molds at the necessary temperature. This results in a very energy efficient production process for each piece. By using carbon fiber body parts, the entire body weighs less than 200 pounds. It also allows assembly by hand. Robotics or lifting machinery is not required as the parts can be lifted and positioned by one or two people. Instead of welding, the parts are chemically bonded to each other, resulting in a join that is as strong or stronger than the parts themselves.

• Strength

Carbon Fiber Sheet Molding Composites (CFSMC) are up to 10 times stronger than steel by weight.

• Cost

Although CFSMC is more expensive and complex to manufacture than steel, it returns significant savings in the ability to construct large components that would normally require many parts to assemble using metal. It is not subject to corrosion or fatigue and so has a longer lifespan.

• Life Cycle Recycling
  • Raw Materials

  Most of the Aptera is constructed of either CFSMC or aluminum, with some steel. Other areas are bamboo-based or other sustainably produced materials.

  • Processing
  • Manufacturing

  The waste from CFSMC molding is very small. The trimmings can immediately be ground up and recycled in the next batch.

  • Distributing

  Transporting products usually involves burning fossil fuels. The lighter the item, the less it pollutes in reaching its destination.

  • Product Use

  Due to its high strength-to-weight ratio, CFSMC may reduce weight by up to 70% over other materials.

  • Disposal

  CFSMC is easily recycled. Old material is simply ground up and used again.
  Aluminium is also easily melted down for recycling.

Aptera - The Company

Mission Statement

Working to make every journey powered by the sun!

Stock Symbol: SUNA (NASDAQ - Pre-IPO)

History

In 2006, Accelerated Composites was founded by Steve Fambro. Soon after, Chris Anthony joined and they changed the name to Aptera announcing a three-wheeled motorcycle design that would get 330 mpg using a combination of 12 HP diesel engine and 24HP motor with a selling price under $20,000.

In 2008, after raising $24M, Aptera ousted Steve and Chris, and accepted 4,000 $500 deposits for the vehicle, which was supposed to be delivered that year.

In March, 2009, the U.S. government denied loans under the Advanced Technology Vehicles Manufacturing Loan Program, due to the loans being limited to 4-wheel vehicles. That same year, Aptera's prototype had a cameo appearance in Star Trek: The Motion Picture.

In 2011, Aptera started returning deposits to its customers and the company liquidated, selling off its assets and IP to Chinese automakers, who failed to successfully develop the idea.

In 2019, Steve and Chris resurrected Aptera. Electric vehicles were no longer just concept cars; Tesla was having a record year and the battery, motor, solar panel technologies as well as charging networks had significantly advanced to the point that Aptera believed they could practically create a vehicle that derived significant power from incorporated solar panels.

Aptera raised $200k in 2019 in a WeFunder campaign, and double that in 2020.

In early 2021, Aptera closed a $4M Series A funding round and started taking $100 deposits for a future vehicle. They built three engineering prototypes, and raised over $39M in funding.

By the end of 2022, they reported $39.9M in total assets and over 18,000 reservations<\p>

In 2023, after missing several hopeful production targets, Aptera opened another crowdsourcing program, called the Accelerator Program. Starting the, investors who purchased (another) $10k of Aptera stock would receive one of the first 2,000 Aptera Launch Edition vehicles to be produced. The delivery slots would go according to the highest overall investors.

In 2024, after raising over $35M in the program, the Accelerator program completed and was closed.

On May 16, 2024, Aptera announced an agreement with US Capital to fund their production plan and start selling their cars to the public in early 2025.

At this time, it appears that Aptera early investments qualified for the IRS 1202 Qualified Small Business Stock Gain Exclusion

This is a federal capital gains exclusion (check your state code to see if your state conforms to the same guidelines. California does not).

To qualify, the business must meet the following criteria:

• The business must be a C corporation
• It must be engaged in a qualifying business
• It must used at least 80% of its assets to actively conduct business
• Less than 50% of its total assets may be working capital
• The company may have no more than $50M tax basis in assets prior to stock issuance

Aptera, to the best of my knowledge, easily meets all of these requirements.
Therefore, if you invest in Aptera today, and hold your investment for at least five years, your profit on Aptera stock will be excluded from federal capital gains (currently at 23.8%) for the greater amount of 5 times your initial investment, or $10M of gains.

Further Information

The cash compensation for the officers and directors of Aptera, for 2023 were:

• Chris Anthony (CEO / Director) - $262k in 2022, $212k in 2021
• Steve Fambro (CEO / Director) - $257k in 2022, $181k in 2021
• Brian Snow (Director) - $135k for 2022
• Sarah Hardwick (CMO) - $231k for 2022

More information will be made available soon

My Experience

• I first heard about Aptera sometime in the mid-2000's when they were trying to produce a diesel powered vehicle that could get 300 mpg. I was intrigued by the concept, but was never an investor, as at time I believed it to be pretty much a concept car rather than a serious contender. The company effectively folded in 2011.
• I first heard about the resurrection of Aptera in the spring of 2020. They were doing a Wefunder crowdfunder to raise at least $550k. They were offering a free reservation (worth $100) for a minimum investment of $1,000. After reading through all of their history and goals I immediately signed up, figuring if they went under, a $1,000 investment in a future I believed in was certainly worthwhile.
• I put in my (free) reservation right away for a 600k range vehicle with full solar, all-wheel drive, and more.
• In September, 2021, I increased my investment to exceed $10k, which further entitled me to a 5% discount if/when they ever produced their vehicle
• In December, 2023, they were having an Accelerator Program: For new investors of at least $10k, they offered a pre-order list to receive one of the first 2,000 Apteras to be produced, in a configuration that they called the Launch Edition. It was nearly the same as my initial configuration, except that they would be producing the 400-mile range version as their introductory vehicle. I made a further investment and garnered spot #712 to receive the Launch Edition, which will include a specially numbered vehicle and serialized limited-edition hardback book about producing the first Apterae, featuring CAD and design images from the development.
• In January, 2024, Aptera announced the completion of their Accelerator Program, and in June, 2024 they announced that they had successfully raised over $35M with 991 new investors and 2,072 slots filled.
• As of May, 2024, they have received the first of 16 progressive Production Intent builds, which will be used for final development of the manufacturing process, suspension refinement and, ultimately, virtually complete vehicles to show to the public and perform crash and safety testing on.
• They current expect to be producing vehicles for further internal assessment by the end of the year, and start production in early 2025.
• On May 16, 2024, they announced that US Capital would be providing funding for their production plan to get vehicles into production by 2025. The program is only open to accredited investors who can invest at least $50,000.
• On September, 2024, I received notice that my position on the Accelerator Board (and thus my delivery vehicle number) is 807, which they were projecting would be delivered in H1, 2025
• On December 2, 2024, Aptera re-opened its crowdfunding program with a minimum investment of $1,000 and a share price of $14.80