- 1 Contents of the Box
- 2 SonixDAQ I/O Connections
- 3 Connecting the SonixDAQ to the Sonix System
- 4 Connecting USB Cable
- 5 Connecting BNC Cable for Sync Signal
- 6 Connecting BNC Cable for Clock Signal (Optional)
- 7 Connecting to the Power Socket-Outlet
- 8 SonixDAQ Ratings and Environmental Conditions
- 9 Maintenance and Service
- 10 Hardware Block Diagram
Contents of the Box
The SonixDAQ box contains:
- The SonixDAQ
- One USB cable,
- Two BNC cables, and
- A power adapter.
SonixDAQ I/O Connections
The SonixDAQ has the following connections:
- Probe connector
- Power supply connector
- BNC connectors:
- External Trigger
- External Clock
- USB 2.0 connector
The labels on the device can be used to identify each of the connections. The next section contains figures and instructions for assembling the SonixDAQ.
Warning: The safety of any assembled system incorporating the SonixDAQ is the responsibility of the assembler of the system.
Connecting the SonixDAQ to the Sonix System
In order to capture the data, the SonixDAQ has to be connected to the Sonix ultrasound system. For this purpose, the SonixDAQ probe connector should be connected to the Sonix system's lowest probe slot. The other probe slot of the Sonix system is reserved for the actual probe that transmits and receives the ultrasound signal in a standard way.
Note that for SonixMDP and Sonix RP systems, the two bumpers underneath the probe connectors on the DAQ need to be removed. This is shown in the figure below:
Also on the SonixMDP system the plastic on the bottom needs to be removed. This is shown in the figure below:
Connecting USB Cable
Connecting the USB cable is straight forward. Like other USB devices just connect one side of the USB cable to the DAQ and the other side of the USB cable to on of the USB port on the Sonix system. Note that USB connector is used both for programming the DAQ and transferring the data from DAQ to PC.
Connecting BNC Cable for Sync Signal
The next step is to connect the DAQ BNC Sync cable to the correct Sonix systems's BNC for proper synchronization. In the synchronous data acquisition mode, the DAQ waits for the sync signal before starting to acquire data. Thus, care should be taken to ensure that the DAQ's correct BNC connector (input sync) is connected to the Sonix system's correct BNC connector (output sync). The following figures show the correct connectors for both the DAQ and the Sonix systems.
Connecting BNC Cable for Clock Signal (Optional)
The SonixDAQ has its own internal clock for data acquisition which is running at 40MHz. This clock may not be perfectly synchronized with the Sonix systems internal clock. This may introduce one sample shift in-between sequences of channel data. To resolve this issue, the second BNC can be used to provide external clock to the DAQ. In the external clock data acquisition mode, the DAQ will ignore its internal clock and will rely on the clock which is provided to it through the second BNC cable. For this mode to work properly, the Sonix system should be programmed to output its internal clock (@40MHz) to one of the BNC cable. This signal should then be connected to the DAQ through its second port using the other BNC cable.
Note: Regardless of the sampling frequency of the SonixDAQ, this clock always has to 40MHz. SonixDAQ generates the higher sampling frequency from this 40MHz clock.
Note: 40MHz clock on the second BNC cable is only available on the SonixTOUCH and the SonixMDP systems. SonixRP systems are not able to provide the system clock through the BNC cable.
Connecting to the Power Socket-Outlet
To connect the DAQ to the power outlet, make sure that the voltage of the outlet in your area matches the specifications of the power supply provided with the DAQ. Make sure the on-off switch of the DAQ is in the off state. Connect the power supply to the DAQ and the power outlet. After this step, the SonixDAQ is ready to be powered up by its on-off switch. Once powered up, three green LEDs beside the power button should turn on.
Note: To disconnect the device from the power socket-outlet, unplug the DAQ's power supply from the outlet.
Warning: Mains supply voltage fluctuations are not to exceed 10 percent of the nominal supply voltage.
SonixDAQ Ratings and Environmental Conditions
SonixDAQ Power Supply (PSU):
- Input : 100 - 240Vac 5.0A, 110 Vac 5.0A, 220 Vac 5.0A, 50 – 60 Hz
- Output : 12V, 21.67A, 260W max
- Input : 12Vdc 20A
- 50 to 104 degrees F (10 to 40 degrees C)
- 30 to 75% relative humidity
Operational Altitude (Max):
- 2000 m
- degree 2
- Category II (including the PSU)
- 5 to 122 degrees F (-15 to 50 degrees C)
- 10 to 90% (non-condensing)
- 50 kPa to 106 kPa (kiloPascal)
Note: This device is to be used only with the PSU and medical grade power supply cord provided by Ultrasonix.
Warning: Operate in an indoor environment only, free from moisture, flammable liquids, gases, corrosive substances, strong electrical or magnetic fields, and equipment that generate high frequency waves. Ultrasonix cannot guarantee the proper performance of the system if used in the above listed conditions.
Warning: If the equipment is used in a manner not specified by Ultrasonix, the protection provided by the equipment may be impaired.
Maintenance and Service
Do not try to service or repair the SonixDAQ or otherwise open the casing of the device by yourself. Please contact Ultrasonix in case the SonixDAQ needs maintenance or service.
Hardware Block Diagram
Inside the DAQ there are four receive board each capturing 32 channel (128 channel total). There is also one main board that control the data acquisition process. Inside the DAQ is shown in a figure below:
A high-level block diagram of the SonixDAQ is shown below. The orange circles show some of the parameters provided to the user for controlling the data acquisition. The details of these parameters are given in the SonixDAQ software.
A block diagram of the SonixDAQ hardware that provides a detailed description of the signal processing chain and imaging parameters can be found below. The document shows individual components namely transmit/receive switch, LNA, PGA, AA filter, ... and the parameters which are used to adjust their performance.