Guilherme "Bill" Cardoso

Last updated
Bill Cardoso
Bill Cardoso at SEMA 2023.png
Dr. Cardoso at SEMA 2023
Born (1976-04-27) April 27, 1976 (age 48)
Porto Alegre, Rio Grande do Sul, Brazil
NationalityBrazilian-American
Alma mater The University of Chicago, Illinois Institute of Technology, Federal University of Rio Grande do Sul
Known forBest Engineered Vehicle of the Year SEMA '23
AwardsInnovator of the Year Award - San Diego Business Journal (2015)

Top 50 CEOs in Electronics - Industry Week (2019)

Excellence in Engineering Award - Institute of Electrical and Electronics Engineers (IEEE) (2020)

Contents

Entrepreneur of the Year - Carlsbad Chamber of Commerce (2021)

Best Engineered Vehicle of the Year - SEMA (2023)
Scientific career
FieldsX-ray Inspection, Radiation Detection, Electric Vehicles, Entrepreneurship, Economics
InstitutionsCreative Electron Inc., Scorpion-EV Inc.
Thesis Compression, Estimation, and Analysis of Ultrasonic Signals  (2005)
Doctoral advisor Dr. Jafar Saniie

Guilherme "Bill" Cardoso (born April 27, 1976) is a Brazilian-American entrepreneur, engineer, and scientist. Cardoso is the founder of Creative Electron, Inc., an X-ray inspection systems manufacturer, and Scorpion-EV Inc., an electric vehicle manufacturer. He has over 25 years of experience driving technological breakthroughs in radiation detection, electronics, and high-performance electric vehicles]. Cardoso is most notably known for winning the Best Engineered Vehicle of the Year at the 2023 SEMA show for his '23 Cobra Venom conversion kit build. [1]

Early life and education

Cardoso was born in Porto Alegre, Rio Grande do Sul, Brazil, where he developed an early interest in engineering and technology. He earned his associate's degree from the Occidental School in Porto Alegre. He pursued a bachelor’s degree in Electrical and Computer Engineering from the Federal University of Rio Grande do Sul (UFRGS), Brazil, before moving to the United States for further education. He completed his master’s and Ph.D. in electrical and Computer Engineering at the Illinois Institute of Technology (IIT) in Chicago, Illinois.

Cardoso also holds an MBA from the University of Chicago, with a focus on strategic management, economy, and entrepreneurship. His multidisciplinary education laid the foundation for his career in developing high-tech solutions for industries ranging from nuclear physics to automotive engineering.

Career

GCC

Cardoso started his first company, GCC (Guilherme Cardoso Corp), at the age of 13 after having graduated from the Occidental School of Porto Alegre with an associate's degree in electronics. GCC manufactured and sold light switch dimmers in Porto Alegre.

Robotec Automation Systems

In the early 1990s, under the government of President Fernando Collor, Brazil began reducing import taxes on foreign-made electronics. [2] After decades of protectionist policies implemented during the military dictatorship, the sudden influx of lower-cost imports disrupted Brazil’s industrial sector. In response to this economic shift, Cardoso founded Robotec in 1993. The company aimed to assist Brazilian firms in redeveloping products to remain competitive in the evolving market. Robotec specialized in providing electronic design solutions for industries ranging from automotive to medical and industrial sectors.

Fermilab

After completing his education, Cardoso worked for over a decade at the Fermi National Accelerator Laboratory (Fermilab), where he led the Electronics Systems Engineering Department. At Fermilab, he was responsible for designing and developing radiation detector systems used in nuclear particle physics experiments. [3] His work contributed to several high-profile projects, including developing a pixel radiation detector used in experiments to explore the structure of matter and the origins of the universe. [4] Cardoso also contributed to the development of onboard electronics for NASA satellites and authored numerous technical papers on advanced semiconductor solutions and pixel detectors. [5]

Aquila Technologies

Cardoso joined Aquila Technologies in 2007 and led it until his departure in 2008. Aguila focused on defense, medical imaging and radiation detection technologies. One of the company’s key innovations was the creation of the first handheld Radiation Threat Detector (RTD), capable of detecting, localizing, and identifying radiation sources within a wide energy range. His work at Aquila Technologies included securing over $1.5 million in research funding from various organizations, including the Department of Defense, Department of Homeland Security (DHS), Department of Energy (DOE), and the National Institutes of Health (NIH).

An X-ray of the iPhone 14 Pro IPhone 14 Pro X-ray.jpg
An X-ray of the iPhone 14 Pro

Creative Electron Inc.

Cardoso founded Creative Electron, Inc. in 2008, in San Marcos, California. The company specializes in the design and manufacturing of X-ray inspection systems used for non-destructive testing in industries such as electronics, aerospace, and medical devices. Creative Electron is one of the largest U.S. based manufacturers in the field of X-ray inspection, integrating advanced AI and machine learning technologies into its systems to automate and enhance quality control processes. Under Cardoso’s leadership, the company has secured several patents for innovations in X-ray imaging and inspection technology.

Creative Electron and iFixit x-ray case controversy

In November 2023, Creative Electron became involved in a public controversy when accusations arose against Casetify, a phone case manufacturer, for allegedly stealing X-ray images of iPhones originally created by Creative Electron. [6] These X-ray images had been previously licensed to companies like iFixit and Dbrand, who used them for promotional phone cases. [7] Dbrand and iFixit accused Casetify of using these X-ray images without permission, prompting public outcry.

According to reports, Casetify was selling phone cases featuring these X-ray images without licensing or acknowledgment of Creative Electron, the original creator. iFixit and Dbrand publicly criticized Casetify, with Dbrand mocking the incident in a social media campaign. The controversy highlighted ongoing issues of intellectual property misuse in the design and tech industries, bringing significant attention to Creative Electron's X-ray imaging technology. [8]

Scorpion EV

A production model Scorpion 600 EV Scorpion 600.jpg
A production model Scorpion 600 EV

In 2021, during the COVID-19 pandemic lockdown, Cardoso founded Scorpion-EV, a company focused on producing high-performance electric vehicles and EV conversion kits. [9]

In 2023, Cardoso received the inaugural SEMA Best Engineered Vehicle of the Year Award for the '23 Cobra Venom. [10] This electric vehicle conversion car was designed to showcase Scorpion EV's Venom conversion kit, which simplifies the process of converting internal combustion engine vehicles to electric power. [11] The award, presented at the SEMA Show, recognizes excellence in vehicle engineering and highlights the growing importance of EV technology in the automotive industry. The '23 Cobra Venom was celebrated for its innovation and ability to inspire engineers and builders to explore new possibilities in vehicle design and electrification.

Creative Farms

Founded by Cardoso in 2020, Creative Farms grows Chardonnay grapes in beautiful wine country in California. The farm also grows olives, avocados, oranges, lemons, and grapefruits. All product is grown without pesticides following organic practices to offer wineries locally grown products.

Philanthropy and mentorship

Cardoso sits on the Illinois Institute of Technology Electrical and Computer Engineering Department Board of Advisors. [12]

Cardoso is committed to promoting STEM (Science, Technology, Engineering, and Mathematics) education. He actively supports initiatives that encourage underrepresented groups to pursue careers in engineering and technology. As part of this commitment, Creative Electron Inc and Scorpion EV Inc partner with MiraCosta Community College in Oceanside, California. This collaboration provides students with access to cutting-edge X-ray inspection technology, internship opportunities, guest lectures, and hands-on training to prepare them for careers in high-tech industries. [13]

Selected publications

Related Research Articles

<span class="mw-page-title-main">Photodiode</span> Converts light into current

A photodiode is a semiconductor diode sensitive to photon radiation, such as visible light, infrared or ultraviolet radiation, X-rays and gamma rays. It produces an electrical current when it absorbs photons. This can be used for detection and measurement applications, or for the generation of electrical power in solar cells. Photodiodes are used in a wide range of applications throughout the electromagnetic spectrum from visible light photocells to gamma ray spectrometers.

A semiconductor detector in ionizing radiation detection physics is a device that uses a semiconductor to measure the effect of incident charged particles or photons.

<span class="mw-page-title-main">Photodetector</span> Sensors of light or other electromagnetic energy

Photodetectors, also called photosensors, are sensors of light or other electromagnetic radiation. There are a wide variety of photodetectors which may be classified by mechanism of detection, such as photoelectric or photochemical effects, or by various performance metrics, such as spectral response. Semiconductor-based photodetectors typically use a p–n junction that converts photons into charge. The absorbed photons make electron–hole pairs in the depletion region. Photodiodes and photo transistors are a few examples of photo detectors. Solar cells convert some of the light energy absorbed into electrical energy.

<span class="mw-page-title-main">Gaseous ionization detector</span> Radiation detector

Gaseous ionization detectors are radiation detection instruments used in particle physics to detect the presence of ionizing particles, and in radiation protection applications to measure ionizing radiation.

Cadmium zinc telluride, (CdZnTe) or CZT, is a compound of cadmium, zinc and tellurium or, more strictly speaking, an alloy of cadmium telluride and zinc telluride. A direct bandgap semiconductor, it is used in a variety of applications, including semiconductor radiation detectors, photorefractive gratings, electro-optic modulators, solar cells, and terahertz generation and detection. The band gap varies from approximately 1.4 to 2.2 eV, depending on composition.

<span class="mw-page-title-main">Neutron detection</span>

Neutron detection is the effective detection of neutrons entering a well-positioned detector. There are two key aspects to effective neutron detection: hardware and software. Detection hardware refers to the kind of neutron detector used and to the electronics used in the detection setup. Further, the hardware setup also defines key experimental parameters, such as source-detector distance, solid angle and detector shielding. Detection software consists of analysis tools that perform tasks such as graphical analysis to measure the number and energies of neutrons striking the detector.

<span class="mw-page-title-main">Image sensor</span> Device that converts images into electronic signals

An image sensor or imager is a sensor that detects and conveys information used to form an image. It does so by converting the variable attenuation of light waves into signals, small bursts of current that convey the information. The waves can be light or other electromagnetic radiation. Image sensors are used in electronic imaging devices of both analog and digital types, which include digital cameras, camera modules, camera phones, optical mouse devices, medical imaging equipment, night vision equipment such as thermal imaging devices, radar, sonar, and others. As technology changes, electronic and digital imaging tends to replace chemical and analog imaging.

Charge sharing is an effect of signal degradation through transfer of charges from one electronic domain to another.

<span class="mw-page-title-main">Active-pixel sensor</span> Image sensor, consisting of an integrated circuit

An active-pixel sensor (APS) is an image sensor, which was invented by Peter J.W. Noble in 1968, where each pixel sensor unit cell has a photodetector and one or more active transistors. In a metal–oxide–semiconductor (MOS) active-pixel sensor, MOS field-effect transistors (MOSFETs) are used as amplifiers. There are different types of APS, including the early NMOS APS and the now much more common complementary MOS (CMOS) APS, also known as the CMOS sensor. CMOS sensors are used in digital camera technologies such as cell phone cameras, web cameras, most modern digital pocket cameras, most digital single-lens reflex cameras (DSLRs), mirrorless interchangeable-lens cameras (MILCs), and lensless imaging for cells.

<span class="mw-page-title-main">PILATUS (detector)</span> Series of x-ray detectors developed by the Paul Scherrer Institute

PILATUS is the name of a series of x-ray detectors originally developed by the Paul Scherrer Institute at the Swiss Light Source and further developed and commercialized by DECTRIS. The PILATUS detectors are based on hybrid photon counting (HPC) technology, by which X-rays are converted to electrical signals by the photoelectric effect in a semiconductor sensor layer—either silicon or cadmium telluride—which is subject to a substantial bias voltage. The electric signals are counted directly by a series of cells in an ASIC bonded to the sensor. Each cell—or pixel—is a complete detector in itself, equipped with an amplifier, discriminator and counter circuit. This is possible thanks to contemporary CMOS integrated circuit technology.

<span class="mw-page-title-main">Medipix</span> Family of pixel detectors

Medipix is a family of photon counting and particle tracking pixel detectors developed by an international collaboration, hosted by CERN.

Lanthanum(III) bromide (LaBr3) is an inorganic halide salt of lanthanum. When pure, it is a colorless white powder. The single crystals of LaBr3 are hexagonal crystals with melting point of 783 °C. It is highly hygroscopic and water-soluble. There are several hydrates, La3Br·x H2O, of the salt also known. It is often used as a source of lanthanum in chemical synthesis and as a scintillation material in certain applications.

<span class="mw-page-title-main">X-ray detector</span> Instrument that can measure properties of X-rays

X-ray detectors are devices used to measure the flux, spatial distribution, spectrum, and/or other properties of X-rays.

High energy X-ray imaging technology (HEXITEC) is a family of spectroscopic, single photon counting, pixel detectors developed for high energy X-ray and gamma ray spectroscopy applications.

Nanoprobing is method of extracting device electrical parameters through the use of nanoscale tungsten wires, used primarily in the semiconductor industry. The characterization of individual devices is instrumental to engineers and integrated circuit designers during initial product development and debug. It is commonly utilized in device failure analysis laboratories to aid with yield enhancement, quality and reliability issues and customer returns. Commercially available nanoprobing systems are integrated into either a vacuum-based scanning electron microscope (SEM) or atomic force microscope (AFM). Nanoprobing systems that are based on AFM technology are referred to as Atomic Force nanoProbers (AFP).

<span class="mw-page-title-main">Oleg Tolbanov</span> Russian physicist

Oleg Petrovich Tolbanov is a Russian physicist, specialist in solid state physics, solid-state electronics and physical materials science. He is the author of more than 160 scientific articles in the Web of Science database, including: monographs, 5 textbooks, more than 60 inventions.

Micropattern gaseous detectors (MPGDs) are a group of gaseous ionization detectors consisting of microelectronic structures with sub-millimeter distances between anode and cathode electrodes. When interacting with the gaseous medium of the detector, particles of ionizing radiation create electrons and ions that are subsequently drifted apart by means of an electric field. The accelerated electrons create further electron-ion pairs in an avalanche process in regions with a strong electrostatic field. The various types of MPGDs differ in the way this strong field region is created. Examples of MPGDs include the microstrip gas chamber, the gas electron multiplier and the Micromegas detector.

Hybrid pixel detectors are a type of ionizing radiation detector consisting of an array of diodes based on semiconductor technology and their associated electronics. The term “hybrid” stems from the fact that the two main elements from which these devices are built, the semiconductor sensor and the readout chip, are manufactured independently and later electrically coupled by means of a bump-bonding process. Ionizing particles are detected as they produce electron-hole pairs through their interaction with the sensor element, usually made of doped silicon or cadmium telluride. The readout ASIC is segmented into pixels containing the necessary electronics to amplify and measure the electrical signals induced by the incoming particles in the sensor layer.

<span class="mw-page-title-main">Aristos Christou</span> American engineer

Aristos Christou is an American engineer and scientist, academic professor and researcher. He is a Professor of Materials Science, Professor of Mechanical Engineering and Professor of Reliability Engineering at the University of Maryland.

<span class="mw-page-title-main">Edoardo Charbon</span> Swiss quantum engineer

Edoardo Charbon is a Swiss electrical engineer. He is a professor of quantum engineering at EPFL and the head of the Laboratory of Advanced Quantum Architecture (AQUA) at the School of Engineering.

References

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  2. Brooke, James (July 5, 1990). "ERA OF FREE TRADE TO BEGIN IN BRAZIL". The New York Times . p. 1. Retrieved September 13, 2023.
  3. 2008 IEEE NSS/MIC/RTSD Conference Record, October 19-25, 2008, Dresden, Germnay. Dreseden, Germany: IEEE. 2008. ISBN   978-1-4244-2715-4.
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  8. Shakir, Umar (2023-11-24). "The case of the stolen X-Ray cases is bigger and dumber than we thought". The Verge. Retrieved 2024-09-13.
  9. Ross, David (2023-04-27). "Expo points towards a carbon-less future - Escondido Times-Advocate". Escondido Times-Advocate. Retrieved 2024-09-12.
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  12. "Board of Advisors | Electrical and Computer Engineering". www.iit.edu. Retrieved 2024-09-12.
  13. "MiraCosta College - PIO - News Center". hub.miracosta.edu. Retrieved 2024-09-12.
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  16. Chen, H.; Awadalla, S. A.; Harris, F.; Lu, P. H.; Bindley, G.; Lenos, H.; Cardoso, B. (2008). Burger, Arnold; Franks, Larry A.; James, Ralph B. (eds.). "Reliability of pixellated CZT detector modules used for medical imaging and homeland security". Hard X-Ray, Gamma-Ray, and Neutron Detector Physics X. 7079. SPIE: 31–40. Bibcode:2008SPIE.7079E..05C. doi:10.1117/12.795252.
  17. Turqueti, Marcos; Kunin, Vitaliy; Cardoso, Bill; Saniie, Jafar; Oruklu, Erdal (2010). "Acoustic sensor array for sonic imaging in air". 2010 IEEE International Ultrasonics Symposium. IEEE. pp. 1833–1836. doi:10.1109/ULTSYM.2010.5935842. ISBN   978-1-4577-0382-9.
  18. Tumer, Tumay O.; Cajipe, Victoria B.; Albert Capote, M.; Cardoso, Guilherme; Clajus, Martin; Hayakawa, Satoshi; Lee, Michael; Volkovskii, Alexander (2008-10-02). "Readout ICs for high spatial resolution slot-scan imaging with CZT or CdTe pixel arrays". 2008 IEEE Nuclear Science Symposium Conference Record. IEEE. pp. 412–418. doi:10.1109/nssmic.2008.4775197. ISBN   978-1-4244-2714-7.
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  20. Turqueti, M. A.; Andresen, J.; Brooks, M. L.; Butsyk, S. A.; Cardoso, G.; Christian, D.; Kapustinsky, J.; Kunde, G. J.; Kwan, S. W.; Lee, D. M.; Rivera, R. (2006). "Pixel Multichip Module Development at Fermilab for the PHENIX Experiment". 2006 IEEE Nuclear Science Symposium Conference Record. Vol. 465. IEEE. pp. 496–499. doi:10.1109/nssmic.2006.356205. ISBN   1-4244-0560-2.
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