Chocolate challenge! See how spectroscopy can give you answers.

Roses are red,

Violets are blue,

We used a TI DLP® NIRscan™ Nano EVM,

To pick the right chocolate for you.

Love may be fleeting, but at least we’ll always have chocolates.

While there’s nothing sweeter for your sweetheart than a box of chocolates on Valentine’s Day, choosing the option with just the right balance of cocoa and sugar content for your taste buds can be a lovelorn experience.

Photo 1: The DLP NIRscan Nano EVM in action.

At TI DLP Products, we decided to address this candy conundrum with our DLP NIRscan Nano evaluation module (EVM). We scanned unidentified samples of chocolate and compared it to a database of known milk chocolates and dark chocolates of approximately 70 percent cocoa and 85 percent cocoa.

Based on the known chocolates in the database, here’s what our testing found:

  • 70 percent dark chocolate = approximately 27.5 percent sugar
  • 85 percent dark chocolate = approximately  12.5 percent sugar
  • Milk chocolate = approximately  52.4 percent sugar

The DLP NIRscan Nano EVM is optimized for a 900 to 1,700 nanometer wavelength range and features a 6,000:1 signal-to-noise ratio. The results shown below were taken directly from the EVM’s included graphical user interface (GUI). We observed the absorbance levels of all three varieties of chocolate across this wavelength range. When compared to the absorbance spectrums in the database, we could identify which chocolates were 70 percent cocoa, 85 percent cocoa, or milk chocolate. 

Photo 2: This screen shot of the GUI plots the absorbance results of the three types of chocolate we tested.

So much more than a box of chocolates

Of course, the NIRscan Nano EVM can help determine more than just sugar content.

The EVM is an evaluation tool to help developers quickly design spectrometers and chemical analyzers using DLP chips. It uses our DLP technology in conjunction with a single element InGaAs detector to deliver high performance measurements in a portable form factor that is more affordable than expensive InGaAs array detectors or fragile rotating grating architectures. The wide NIR-window transmittance also makes it useful in a variety of industries such as agriculture, petrochemicals, and health care.