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Module: Goblin [](@description Goblin description)

Name

MDL-goblin_tgcenvadc

Title

Goblin: a TGC-Envelop-ADC module

Description

  • The analog signal-processing heart of the echOmods
  • Setup? Have a look at the quick start guide
  • version: V0.2
  • date: 25/12/2016
  • cost:149$
  • sourcing:Custom made, get the Gerbers, or buy it preassembled on Tindie, or contact @kelu124
  • technology: Module-compatible, Homemade PCB, ICs based on AD8331 and ADL5511
  • language: Altium, Kicad
  • author: Kelu124

IOs

Inputs

  • ITF-1_GND
  • ITF-2_VDD_5V
  • ITF-7_GAIN
  • ITF-4_RawSig : because it's used internally
  • ITF-3_ENV : because it's used internally
  • ITF-18_Raw : for the signal coming from the pulser (if through track 18)
  • ITF-mET_SMA : for the signal coming from the pulser (if through SMA)

Outputs

  • ITF-4_RawSig: Amplified Raw Signal, post TGC, before the enveloppe detection
  • ITF-3_ENV_signal_envelope: enveloppe of the signal, post TGC
  • ITF-mEG_SPI : signal from the ADC

Key Components

  • ADL5511: Enveloppe detection
  • AD8331: TGC
  • AD7274: 2Msps SPI ADC
  • AD8691: OA

Information

What is it supposed to do?

The aim of this echOmod is to get the signal coming back from a transducer, and to deliver the signal, analogically processed, with all steps accessible to hackers.

With more details, this Goblin board aims at getting a signal, and giving access to key points within the signal processing chain for ultrasound imaging, namely:

  • Getting access to a TGC
  • Getting the enveloppe of the signal
  • Cleaning the signal before feeding in the on-board SPI ADC

All key signals are accessible, and jumpers, as well as pots, enable on-board fine-tuning of the signals. See more details on the testing session, to see the behavior of the board on a oscillo.

It's also a first try at a SPI ADC. Using a up to 3 Msps one in order to catch only the enveloppe, to be tested with other uC, RPi or BBB. Test have been also done with 6MSps, arduino IDE-compatible, STM32.

How does it work: block diagram

Block schema

  • ITF-7_GAIN->Goblin_Jumper2->AD8331->ITF-C_amplified_raw_signal->ADL5511->ITF-3_ENV->AD8691->ITF-Ext_Amplified->AD7274->ITF-mEG_SPI
  • ITF-18_Raw->Goblin_Jumper1->AD8331
  • ITF-mET_SMA->Goblin_Jumper1
  • ITF-InternalPot1_gain_control->Goblin_Jumper2
  • ITF-InternalPot2_ADC_Vref->AD7274
  • ADL5511->Int-Offset->AD8691

This can be summarized below - all the signals represented are accessible via separate on-board pins:

Input/Output:

About the module

Pros

Cons: what to to make better

  • Takes a lot of space because of the modularity. Jumpers and pots could be removed, not to mention SMA.
  • The amplifier removing E_REF brings in some noise: a filter could be used there to remove to high frequencies.
  • The SMA brings little, but still a noise analysis could be done to assess the difference between routing the signal through a SMA cable or through the pins.
  • There are only two layers. A fourth one to connect each pin to the other pin on the same row, as well as a ground plane, could help with the noise.
  • Little flexibility from the use of ICs - but sufficient of sorts for our use.
  • The [ADC](/goblin/datasheets/AD7274 - 7273 7276.pdf) is borderline in terms of speed of use. A higher sampling rate could be useful.
  • There was a bug with the ADL5511: need to know how it shuts down.

Detailed view

BEWARE

The transfo has been updated (see this folder for a version with an easily found transfo - untested yet).

Explained

In/Out

See more details of the acquisition of in/out of the module, using the PRUDAQ Module.

Comparing the signals: amplified signal vs enveloppe detected

The overall signal

Details

Details on the peaks

Schematics

Constraint and limits

Tests

Access to raw data

Data sampled at 10Msps on the PRUDAQ on both channels.

See the Jupyter notebook In-Out.ipynb

Data is saved here. It's 32Mb of sampling at 10 Msps. Full repo for the measure test. Let's check the Signal In vs Signal Out:

with details:

Trying with different frequencies

At 3 MHz

At 5MHz

At 7.5MHz

At 10MHz

Difference between enveloppe and ADC input?

-> the offset is removed, there's also a small gain (x2).

See below: there's an offset at the enveloppe detection (~RMS), which is removed. Enveloppe is 500mV before, comes at 1V+ afterwards.

Before the AOP

After the AOP

Idea for onboard ADC

The AD7273/AD7274 are high speed, low power, 10-/12-bit, single supply ADCs, respectively. The parts can be operated from a 2.35 V to 3.6 V supply. When operated from any supply voltage within this range, the AD7273/AD7274 are capable of throughput rates of 3 MSPS when provided with a 48 MHz clock.

Discussions

TODO

  • Test Goblin v2

DONE

  • Check the power consumption
  • Testing the in and out signals of the board with the prudaq.
  • Specs to write
  • Agreeing on the strips
  • Check if 5V and 3.3V are stable
  • Defining the ICs to use
  • Getting schematics
  • Send microcircuits to Edgeflex
  • Receive the module
  • Publish the sources in KiCAD (@Sofian maybe?)
  • CANCELLED - Test it with the EMW3165
  • Plug it to a RPi0 or BBB or STM32
  • Connect the ADC to a RPi0

People

  • Sofian (for preparing the field with Murgen)
  • Vlad for his expertise with Altium

License

Goblin

The echOmods project and its prototypes (so Goblin) are open hardware, and working with open-hardware components.

Licensed under TAPR Open Hardware License (www.tapr.org/OHL)

Copyright Kelu124 ([email protected]) 2015-2018

Based on

The following work is base on a previous TAPR project, Murgen - and respects its TAPR license.

Copyright Kelu124 ([email protected]) 2015-2018