Precision Acoustics DPSU Foglio di istruzioni

PRODUCT INSTRUCTIONS

Precision Acoustics Ltd Hampton Farm Business Park, Higher Bockhampton, Dorchester, Dorset DT2 8QH, UK

t. +44 (0) 1305 264669 e. [email protected] w. acoustics.co.uk

Differential membrane hydrophone

Document version

Date of issue

2.2

17/03/2020

Precision Acoustics Ltd manufactures a wide range of hydrophones the ultrasonic

frequency range. The Differential membrane hydrophone is a gold-standard

hydrophone, ideally suited for measurements of broadband ultrasonic signals in the

500 kHz to 100 MHz range. The Differential membrane hydrophone is designed to be

used in conjunction with a dedicated power supply that powers the fully differential

internal preamplifier. The two items are supplied as a complete system by Precision

Acoustics Ltd. Wherever the properties of the hydrophone are stated, they relate to

the hydrophone/power-supply combination (a hydrophone system).

PRODUCT INSTRUCTIONS

INTRODUCTION

The Differential membrane hydrophone comprises a single layer of PVDF on which gold electrodes

have been deposited such that, after polarisation only a small central circular area is piezo-electrically

active. This gives a sensing device, which is acoustically transparent and can be used to plot the

pressure distribution of ultrasonic fields. Incorporated within the membrane ring is an

instrumentation amplifier. The power supply included with the membrane hydrophone provides

power to the amplifier and transfers the signal to an oscilloscope through the 50 Ωtermination.

PVDF hydrophones have an inherently wide bandwidth and Differential membrane hydrophones have

been calibrated by NPL, London over the frequency range 300 kHz to 60 MHz.

Further information on making acoustic measurements with hydrophones can be found on our

website (http://www.acoustics.co.uk). In addition, Precision Acoustics Ltd offers training courses

covering many aspects of acoustic measurement techniques and practices.

Unpacking the hydrophone system

Each Differential membrane hydrophone system contains several components. Carefully remove the

packaging and identify the following:

•Differential membrane hydrophone

•Membrane hydrophone PSU

•Calibration certificate (printed)

•Mains inlet cable

PRODUCT INSTRUCTIONS

PREPARING FOR MEASUREMENT

Mounting the hydrophone

Hydrophones should be secured in a fixture that

ensures the hydrophone can be moved around

in a water tank to align it with the acoustic

source. This could be a simple mount that

secures the hydrophone via the two locating

holes in the membrane ring or a more

comprehensive mount capable of providing

rotational adjustment.

An example of a Differential membrane

hydrophone within a mount offering 3

independent rotation adjustments is shown

alongside. This mount is available from Precision

Acoustics Ltd as an optional extra upon request.

It is recommended that all hydrophones receive

1h soaking before use. It is recommended that

the hydrophone is placed in the water tank at

this stage before completing the rest of the

setup process.

IMPORTANT NOTE

The membrane hydrophone PSU supplies an amplifier which is embedded in

the hydrophone ring. It is mains operated and should be positioned away

from water and connected to the mains supply via a Residual Current Device

(RCD).

WARNING: DO NOT position it on moving parts of the test tank system.

WARNING: If the membrane hydrophone PSU falls into the water tank,

disconnect from mains BEFORE removal from the water.

If the equipment is used in a manner not specified in this document, the

protection provided by the equipment may be impaired

Only replace the mains cord with one of sufficient current rating

WARNING: The membrane hydrophone must be handled with

extreme care. The membrane is very delicate and must

never be touched by hand or rubbed with any form of cloth

or tissue.

PRODUCT INSTRUCTIONS

Connecting the hydrophone system

Once the connections above are made, mains power should then be applied to the membrane

hydrophone PSU and the data acquisition device. The hydrophone system is now ready for operation.

Please see the section “After measurements are complete” for information about care of your

hydrophone system after use.

MEMBRANE

HYDROPHONE PSU

50 INPUT DATA

ACQUISITION DEVICE

Image shown for illustrative purposes only

MEMBRANE

HYDROPHONE

Bespoke cable on

membrane hydrophone

50 BNC

cable

PRODUCT INSTRUCTIONS

ORIENTATION AND ALIGNMENT

All hydrophones exhibit a directional response and the maximum hydrophone signal will be received

when the plane of the hydrophone active element is orthogonal to the acoustic axis of the transducer

(as shown in the image below). If the membrane hydrophone is rotated about the X or Y axes, there

may be a reduction in the amplitude of received signal, even if the active element remains on the

acoustic axis of the source. This directionality effect will be more noticeable at higher frequencies

and with larger hydrophone active elements.

FINDING A HYDROPHONE SIGNAL

▪For large amplitude low frequency signals generated by single element transducers, this is not

generally a problem. However, for high frequency, narrow beam transducers this can take a

significant time, even if you do follow the steps suggested below. This can be a particular

problem with differential membrane hydrophones where the active area is not clearly visible.

▪Set DAQ for a higher sensitivity (e.g. 5-10 mV/div), which can always be changed later.

▪Visually align hydrophone and transducer. (assuming the optical axis is close to acoustic axis)

▪Triggering. Check that your DAQ system is triggering properly. Particularly if you are triggering

from the acoustic signal, check that you set the trigger level is to a low level since the acoustic

signal may be small.

▪Assess the transducer–hydrophone distance and use  to calculate approximate

propagation delay and set the timebase delay on your DAQ accordingly. Consider using a

deliberately reduced timebase delay in conjunction with a larger time per div setting to

acquire a longer time trace thereby ensuring that the required signal will be “in there,

somewhere”. Once found refine settings accordingly.

▪Although the signal in the far field of a transducer should be more smoothly varying, a highly

directional beam can be difficult to find. Instead, try moving hydrophone close to surface of

PRODUCT INSTRUCTIONS

transducer and locating signal there. Once signal is found, move gradually further away from

transducer (aligning hydrophone as necessary on the way) until desired field position is

achieved.

▪Noise. Where there is poor signal to noise ratio (SNR), it can sometimes be difficult to locate

signal.

oIf you believe hydrophone position is correct, use time domain averaging to improve

SNR. If signal is buried in noise, it should reveal itself.

oIf averaging is not available on oscilloscope, try moving hydrophone slightly backwards

and forwards along the acoustic axis of the transducer. This should cause the signal to

move on the screen of the DAQ and the human eye can sometimes recognise a moving

pattern easier than a stationary one.

CONVERTING HYDROPHONE VOLTAGE TO ULTRASONIC PRESSURE

A hydrophone produces an electrical output signal in response to the surface integral of the acoustic

pressure received over its active element. There may not be a linear relationship between the

acoustic pressure stimulus and the voltage response. In fact, the relationship is almost always

frequency dependent and a conversion process will be required to obtain the acoustic pressure

signal from the hydrophone output voltage. A detailed description of this process can be found within

references [1] [2] and [3]. When the source of ultrasound is only operating at one frequency (e.g.

continuous wave) or with very narrow bandwidth (e.g. sinusoidal tone burst) the relevant IEC standard

[4] states that the pressure signal, p(t), can be calculated from the measured hydrophone voltage,

v(t), according to the relationship

󰇛󰇜 󰇛󰇜

󰇛󰇜

where M(fawf)= sensitivity of a hydrophone at the acoustic working frequency of the source. More

generally however, and especially if the acoustic signal is broadband, the pressure signal should be

calculated according to the relationship

󰇛󰇜󰇫󰇛󰇛󰇜󰇜

󰇛󰇜 󰇬

where and are the Fourier and inverse Fourier transforms and M(f) = sensitivity of a hydrophone

FINDING THE BEAM MAXIMUM

Many acoustic measurements require the maximum value of the acoustic pressure field to be located.

The following two steps are required to maximise the hydrophone signal.

•Correct for directional response of hydrophone –consider the hydrophone active element as

lying in the X-Y plane (Z direction coming normally out of active element). There will be a

directivity pattern associated with both the X and the Y axes (although hopefully the patterns

are the same). First rotate about the X-axis to obtain maximum signal, and then repeat around

the Y Axis.

PRODUCT INSTRUCTIONS

•Find the pressure field maximum –centred on your current position, move the hydrophone

along a line parallel with the X-axis. Move the hydrophone to the location of the field maximum

along that line. Repeat this type of line scan alignment in the orthogonal direction of the Y-

axis. The hydrophone should now be at the position of a maximum. Ensure that your line scans

are long enough to capture the global maximum rather than a local maximum. Repeat with

finer scans if required

•If your hydrophone mount does not have truly independent degrees of freedom there may be

some translation of the hydrophone tip during rotation, so you may have to iterate through

the above two steps.

ALIGNING THE TRANSDUCER BEAM

To align the acoustic axis of the transducer with one of the axes of your hydrophone positioning

system.

•Place hydrophone close to the near field /far field separation distance 

of the transducer and

conduct a line scan in the X direction, centred on your current position. Note the position of

the maximum.

•Move the hydrophone a known distance further into the far field of the transducer and conduct

a second, centred line scan. Once again note the position of the maximum.

•Use trigonometry to ascertain the angular misalignment of the acoustic axis of the transducer,

and rotate the transducer to correct accordingly.

•Repeat this process for the Y direction.

•The transducer may not have well behaved field symmetry and the positions of the maxima

may appear to vary as a function of angle, so it is best to repeat the above process for a

second iteration, to fine tune the alignment.

AFTER MEASUREMENTS ARE COMPLETE

Once measurements are complete please observe the following steps

•Disconnect the membrane hydrophone PSU from the main supply

•Remove the Differential membrane hydrophone from the water.

oRinse the membrane with de-ionised water. Do not attempt rub the membrane with a

cloth/tissue to “clean” it.

•Leave the hydrophone to air dry in a secure location where it cannot get damaged.

PRODUCT INSTRUCTIONS

TROUBLESHOOTING AND FAQ

Troubleshooting

The Membrane hydrophone PSU has a green LED power indicator on the front panel. If this is not

illuminated then the most likely fault is a blown fuse on the membrane hydrophone PSU. If this needs

replacing then a 0.2 A, Quick blow, 20 mm fuse should be used.

Provided the membrane is not physically damaged, there are no electrical or mechanical checks

which will determine whether the differential membrane hydrophone is working correctly. It can only

be checked acoustically. Ensure that the power supply is working and connected to the membrane

cable. Then follow the instructions above for finding a signal. If no signal can be found and you are

certain that your transducer is working correctly, there may be a fault with the membrane hydrophone

system should be returned to Precision Acoustics for inspection. It is unlikely that the membrane

can be repaired but a generous discount will be offered against a new membrane.

Frequency asked questions (FAQ)

▪What liquids can I used my hydrophone in?

oThe Differential membrane hydrophone is designed for use in water with a conductivity

of < 5 μS/cm. Degassing so that dissolved gas content is < 5 ppm is also

recommended.

oFor high amplitude fields the dissolved gas limit changes from recommended to

required and the level drops to < 2.5 ppm. Failure to do so may result in cavitation

damage to the hydrophone which is NOT covered by our warranty.

oHydrophones can be used in castor oil or mineral oil. The hydrophone is constructed

from PVDF which although resilient can be damaged by some organic solvents. If any

medium other than water is used, the calibration figure will not be valid since the

medium will have changed the electrical and acoustical loading conditions on the

hydrophone

▪Do I have to soak the hydrophone?

oAll hydrophones should be soaked before use. Our recommendation is to soak for 1

hour so that the output stabilises before measurements are taken, although most

hydrophones stabilise after about 20 minutes.

▪How long can I leave the hydrophone in water?

oHydrophones should be removed from the water whenever they are not in use and we

advise that if they are left immersed longer than 24 hours they are removed as soon

as possible and dried out.

▪How do I dry the hydrophone?

oRinse the hydrophone in distilled water after use and leave to air dry or place in a warm

oven at no more than 50 °C. Do not touch the membrane surface.

PRODUCT INSTRUCTIONS

▪How do I clean the calcium carbonate deposits from the hydrophone?

oImmerse the hydrophone in lemon juice and then rinse in distilled or running water.

Never use a cloth/towel/abrasive cleaner on the membrane

▪Do I have to terminate the hydrophone output in 50 Ω?

oThe input and output from your measurement equipment should be terminated with

50 Ω. Cables connecting to/from the hydrophone system must have a characteristic

impedance of 50 Ω. If your data acquisition equipment has only a high impedance

termination then you much use an inline through 50 Ωterminator to achieve the correct

impedance

POWER SUPPLY SPECIFICATION

Model number

DPSU

AC supply voltage

Wide range input: 100/120V, 0.2A at 60Hz or

230/240V, 0.2A at 50Hz AC.

(switchable)

Input impedance

50 Ω

Output impedance

50 Ω

Power consumption

2.4 W

Operating temperature range

0 °C to 50 °C

Relative humidity (recommended)

50%

Terminations

Custom 5-way connector (input)

BNC (output)

Maximum dimensions

185 mm (length)

109 mm (width)

45 mm (height)

Weight

925 g

Note: Connection to a power supply must be made via the mains cord supplied by Precision

Acoustics Ltd. If another cord is to be used it must conform to IEC60320-1 or BS1363-1: 2016 (UK

only).

PRODUCT SUPPORT

Disclaimer

Use of either the hydrophone or its power supply in a way not in accordance with information

provided in these product instructions may be hazardous. Precision Acoustics does not accept

liability for incidents occurring as a result of improper use and recommends these instructions MUST

be followed.

All information is based on results gained from experience and tests, and is believed to be accurate

but is given without acceptance of liability for loss or damage attributable to reliance thereon as

conditions of use lie outside the control of Precision Acoustics Ltd.

PRODUCT INSTRUCTIONS

Warranty

Warranty will be for 12 months against defect of hardware component or manufacture only.

If a warranty claim is made on devices that have been calibrated at NPL London, the charge for

calibration of the replacement device is pro-rata against the used part of the original device’s 12-

month calibration.

Warranty replacement after

Calibration period remaining

Discount on recalibration charge

3 months

9 months

75%

8 months

4 months

33%

Contact

Further advice and technical assistance can be obtained from our Applications Engineers

Address: Precision Acoustics Ltd, Hampton Farm Business Park, Higher

Bockhampton, Dorchester, Dorset DT2 8QH

Email: technical@acoustics.co.uk

Tel: +44 1305 264669

Fax: +44 1305 260866

Terms and conditions

PA terms & conditions are available at https://www.acoustics.co.uk/company/terms-and-conditions/

REFERENCES

[1]

A. Hurrell, "Voltage to Pressure Conversion: Are You Getting "Phased" by the Problem?," J. Phys:

Conf. Ser., vol. 1, pp. 57-62, 2004.

[2]

V. Wilkens and C. Koch, "Improvement of hydrophone measurements on diagnostic ultrasound

machines using broadband complex-valued calibration data," J. Phys: Conf. Ser., vol. 1, 2004.

[3]

A. M. Hurrell and S. Rajagopal, "The practicalities of obtaining and using hydrophone calibration

data to derive pressure waveforms," IEEE Trans UFFC., vol. 64, pp. 126-140, 2017.

[4]

IEC, 62127 Ultrasonics - Hydrophones - Part 1: Measurement and characterisation of medical

ultrasonic fields up to 40 MHz, 2013.

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