Chirp Microsystems’ Ultrasonic Time-of-Flight Sensors Advance Range-Finding, Position Tracking, Object Avoidance in Consumer Electronics, Robotics, Drones

--Tiny MEMS-based “sonar on a silicon chip” devices provide range-sensing with millimeter-precision and enable industry’s lowest power consumption


BERKELEY, Calif., Dec. 18, 2017 (GLOBE NEWSWIRE) -- Chirp Microsystems, the pioneer in low-power ultrasonic sensing, today launched the world’s smallest, lowest-power ultrasonic time-of-flight (ToF) sensors, the CH-101 and CH-201.

Commonly recognized as the best range-sensors for automotive and industrial applications — as well as for drones and robotics — ultrasonic ToF sensors offer numerous advantages. They deliver the most accurate range measurement regardless of target size or color and are immune to ambient noise. Unlike optical ToF sensors, they work in direct sunlight. Unlike earlier ultrasonic sensors, Chirp’s ultrasonic sensors are also small and low-power enough for space-constrained consumer applications such as smartphones.

“Ultrasonic sensors are widely used in industrial and automotive applications because they are robust, accurate and reliable,” said Michelle Kiang, CEO, Chirp Microsystems. “Until today, ultrasonic sensors were too big and ugly to fit into consumer electronics. At Chirp, we invented a tiny, millimeter-sized ultrasound chip that can deliver the same performance as conventional sensors that are one thousand times bigger. As we reduced the size, we were also able to dramatically reduce the power consumption – to the point where you can run the sensor at a few micro-amps of current. This combination of small size, ultra-low power and ease-of-use opens ultrasonic sensing to a wide variety of products for the first time.”

Product designers are adopting Chirp’s sensors in products such as drones and robots where other range sensors cannot produce the required performance. Chirp’s sensors are also ideal for smart home products such as smart speakers, where alternative sensing technologies, such as passive infrared (PIR) and optical proximity sensors, are not as effective. In virtual reality and augmented reality (VR/AR) systems, Chirp’s ultrasonic sensors provide accurate tracking of hand-held gaming controllers and other accessories.

Smartphones comprise another important target market. “The CH-101 allows product designers to remove the optical proximity sensor from the front of the phone to create a bezel-less display,” continued Kiang. “That’s because the CH-101’s wide field-of-view allows it to measure range even when it is mounted on the top or bottom sides of the phone. Since this is the location of the microphone and speakers, it’s easy for designers to add another acoustic sensor at these locations.”  

Designers, who have previously been forced to choose between bulk ultrasonic transducers and laser-based infrared (IR) ToF sensors for range-finding and object-detection, now can take advantage of the Chirp sensors’ ability to:

  • Provide precise, low-latency range measurements at sample rates up to 100 samples per second with position noise below 1 mm
  • Enable always-on sensing applications such as human presence, motion and activity sensing at power levels as low as 15 microwatts
  • Detect objects over a field-of-view up to 180° — enabling a single sensor to support room-scale sensing 
  • Work perfectly in all lighting conditions — unlike IR sensors, which do not work in direct sunlight
  • Detect objects of any color, including optically transparent ones — enhancing object detection
  • Ensure eye-safety — contrasting with laser-based IR sensors

About CH-101 and CH-201

As ultrasonic ToF sensors, the CH-101 and CH-201 measure range by emitting an ultrasonic “chirp” and then listening for echoes returning from targets in the sensor’s field-of-view. Each echo travels at the speed of sound, and an echo’s ToF provides a precise measure of the range to a corresponding target.

Chirp’s CH-101 and CH-201 are the first commercially available microelectromechanical systems (MEMS)-based ultrasonic ToF sensors. At 3.5 mm x 3.5 mm, these miniature devices combine a MEMS ultrasonic transducer with a custom low-power CMOS system on a chip (SoC) that handles all ultrasonic signal-processing functions. Similar to a MEMS microphone, the CH-101 and CH-201 are offered in a 3.5mm LGA package, operate on a single 1.8V supply, and have a convenient I2C interface, making them easy to integrate into consumer-electronics products. The sensor’s on-board microprocessor enables always-on operation for wake-up sensing applications; the total current consumption is just 8 µA when measuring 1 sample per second. The CH-101 has a maximum sensing range of 1 m, and the long-range CH-201 has a maximum range of 5 m. The CH-101 and CH-201 are currently sampling to qualified customers. For more information, visit: http://www.chirpmicro.com/technology.html or email: sales@chirpmicro.com

About Chirp Microsystems
Chirp Microsystems is bringing ultrasonics to everyday products. Founded in 2013 based on pioneering research performed at the University of California, Chirp’s piezoelectric MEMS ultrasonic transducers offer long range and low power in a tiny package, enabling products that accurately perceive the three-dimensional world in which we live. Combined with Chirp’s embedded software library, these sensors advance user experiences with VR/AR, wearables, robotics, drones and occupancy detection. For more information, please visit: www.chirpmicro.com

The Chirp Microsystems logo is a registered trademark of Chirp Microsystems. All other product and company names are trademarks or registered trademarks of their respective holders. 

Photos accompanying this announcement are available at

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Press Contacts:
Chirp Microsystems
Email: pr[at]chirpmicro.com

Maria Vetrano
Vetrano Communications
Email: maria[at]vetrano.com 

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