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Oscilloscope Watch: The Time Of Your Engineering Life

Nov. 25, 2013
Combining the functions of an oscilloscope, waveform generator, logic analyzer and frequency counter, the Oscilloscope Watch also tells time.

Described as "The nerdiest thing you can put on your wrist.”  The Oscilloscope Watch has the features of a modern watch (time, calendar, alarm, etc...) along with those of an oscilloscope, waveform generator, logic analyzer, protocol sniffer, and frequency counter. It was developed by Gabriel Anzziani, the founder and CEO of Gabotronics, a company that’s pushing the state-of-the-art for smaller and less expensive test equipment.

Fig. 1. Hand-held Xprotolab oscilloscope

One of Gabotronics first products was the hand-held Xprotolab oscilloscope (Fig. 1) that served as a “template” for the design of the Oscilloscope Watch. The Watch is now a fully funded Kickstarter project whose first prototype is shown in Fig. 2. The watch is scheduled for shipping in 2014 for $150. The Xprotolab oscilloscope now sells for $98.

Fig. 2. Prototype Oscilloscope Watch

With access to the hardware design, users can write their own applications. The brain of the device is a powerful 8-bit XMEGA microcontroller, easy to program in C or assembly.

Special attention has been given to extend the battery life of the device. When the Oscilloscope is not used, the analog section is turned off, so the estimated battery life will be over 30 days on each charge. When using the oscilloscope, the battery will last about 12 hours.These are initial estimates, and could be different if the battery capacity is changed to reduce the size of the watch. Fig. 3 shows the different operational modes.

Fig. 3 Oscilloscope Watch modes and functions

The enclosure will be made out of plastic. Although the current prototype looks kind of big, it is not much bigger than a regular sports watch, but reduction of the size will be one of the goals of the project.

Probes are one of the challenging aspects of the design. The oscilloscope can't be truly wearable/portable if not accompanied by the probes.There are a few solutions for this problem:

1) Carry small probes in a keychain. 
2) Make a wristband made out of the probe cables. 
3) Use the probes as the watch straps.

The keychain is the most feasible option, maybe a small case, or perhaps a retractable cable, similar to those used with tiny USB mouses. Options 2 and 3 could also be considered if backers are interested.

A special BNC adapter will also be designed that will plug in the 9 pin header, this will allow to use standard probes.

The original Xprotolab uses an OLED display, which has nice features like high contrast, and fast refresh rates. But if battery life is critical, then OLED is not the best choice. The Oscilloscope Watch will use a 1.28 in. e-paper display which combines fast refresh rate and great contrast, with a very low power consumption.

Features:

·     Mixed Signal Oscilloscope: Simultaneous sampling of analog and digital signals.

·     Advanced Trigger: Normal / Single / Auto, with rising or falling edge and adjustable trigger level.

·     Meter Mode: Average, Peak to peak and Frequency readout.

·     XY Mode (Plot Lissajous patterns or see the phase difference between two waveforms).

·     Spectrum Analyzer with different windowing options and selectable vertical log.

·     Horizontal and Vertical Cursors with automatic waveform measurements.

·     Arbitrary Waveform Generator with Sweep on all parameters.

·     Display options: Persistence, Different grid options, and more.

·     Curve tracer function

General Specifications

·     ATXMEGA256A3U 256KB Flash, 16KB SRAM, 4KB EEPROM

·     Sharp Memory LCD display 1.28 in., 128x128 pixels

·     Approximate watch size: 2 x 1.6 x 0.6 in.

·     Li-Ion Battery 400mAh, rechargeable via the micro USB connector

·     Internal PDI interface

·     8 tactile switches

·     USB connectivity: PC application available, Android App available.

Logic Analyzer Specifications

·     8 Digital Inputs, 3.3V / 5V tolerant

·     Maximum sampling rate: 16MSPS

·     Frequency counter: 16Mhz

·     Buffer size: 4096 bytes

Protocol Sniffer Specifications

·     UART: 5,6,7,8 data bit formats, 2560 byte buffer.

·     SPI: 439kHz max clock, All combinations of CPOL and CPHA, 2560 byte buffer.

·     I2C: 400kHz max clock, 2048 byte buffer.

Oscilloscope Specifications

·     2 Analog Inputs

·     Maximum Sampling rate: 4MSPS

·     Analog Bandwidth: 200kHz

·     Resolution: 8bits

·     Input Impedance: 1MΩ, 15pF

·     Buffer size per channel: 4096 bytes

·     Input Voltage Range: -14V to +20V

Arbitrary Waveform Generator Specifications

·     1 Analog Output

·     Maximum conversion rate: 1MSPS

·     Low pass filter: 50kHz

·     Resolution: 8bits

·     Output current > ± 7mA

·     Buffer size: 512 bytes

·     Output Voltage: ±4V

The design of the electronics is ready. The firmware will be similar to the Xprotolab's firmware, with the addition of the watch specific functions. The second revision of the PCB is ready.

Fig. 4. Oscilloscope Watch PCB Assembly

The PCB is a four layer board (Fig. 4). Most resistors and capacitors are size 0603, and some ICs are not in the tiniest package available, so there is room for improvement for the next version. The PCB assembly has been modeled in 3D in order to design the enclosure.

Want more information contact [email protected].

About the Author

Sam Davis Blog | Editor-In-Chief - Power Electronics

Sam Davis was the editor-in-chief of Power Electronics Technology magazine and website that is now part of Electronic Design. He has 18 years experience in electronic engineering design and management, six years in public relations and 25 years as a trade press editor. He holds a BSEE from Case-Western Reserve University, and did graduate work at the same school and UCLA. Sam was the editor for PCIM, the predecessor to Power Electronics Technology, from 1984 to 2004. His engineering experience includes circuit and system design for Litton Systems, Bunker-Ramo, Rocketdyne, and Clevite Corporation.. Design tasks included analog circuits, display systems, power supplies, underwater ordnance systems, and test systems. He also served as a program manager for a Litton Systems Navy program.

Sam is the author of Computer Data Displays, a book published by Prentice-Hall in the U.S. and Japan in 1969. He is also a recipient of the Jesse Neal Award for trade press editorial excellence, and has one patent for naval ship construction that simplifies electronic system integration.

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