Abstrict There is provided an ultrasonic Doppler blood-flow meter which
can suppress the occurrence of unwanted frequency components by
suppressing the jump of signal to thereby produce images of high
quality A DC feedback circuit is provided which negatively feeds
back a Doppler deviated signal produced from an integrator to the
input thereof. The feedback amount of the DC feedback circuit is
changed in synchronism with the timing for switching between the
B-mode transmission/reception sequence and the Doppler mode sequence
to prevent a jump of a signal at the commencement of the Doppler
mode. The feedback amount of the DC feedback circuit is made to
be different for the gate moving sequence and the Doppler mode sequence,
thereby preventing a jump of a transient signal due to a discontinuous
input signal at the commencement of the Doppler mode.
Claims We claim:
1. An ultrasonic blood-flow meter, adapted for use in a combined
B-mode and Doppler measurement and display system, comprising:
means for transmitting an ultrasonic pulse signal into a living
body and receiving an echo signal reflected within said living body;
phase detection means for detecting the phase of the echo signal;
means for selecting a gated part of a phase-detected signal;
an integrator for integrating the selected phase-detected signal;
a DC feedback circuit for negatively feeding back a DC component
and a low-frequency component contained in a Doppler deviated signal
produced from said integrator to the input thereof; and
control means, adapted to receive an input representative of mode
switching, for changing, in response to said input, the feedback
amount of said DC feedback circuit between non-zero levels in synchronism
with switching between a B-mode transmission/reception sequence
and a Doppler mode sequence.
2. An ultrasonic Doppler blood-flow meter according to claim 1
further comprising a sample-and-hold circuit following said integrator
wherein an output signal of said integrator is held by said sample-and-hold
circuit and inputted to said DC feedback circuit.
3. An ultrasonic blood-flow meter, adapted for use in a combined
B-mode and Doppler measurement and display system, comprising:
means for transmitting an ultrasonic pulse signal into a living
body and receiving an echo signal reflected within said living body;
phase detection means for detecting the phase of the echo signal;
means for selecting a gated part of a phase-detected signal;
an integrator for integrating the selected phase-detected signal;
a DC feedback circuit for negatively feeding back a DC component
and a low-frequency component contained in a Doppler deviated signal
produced from said integrator to an input thereof; and
control means, adapted to receive an input representative of a
gate position change, for changing, in response to said input, the
feedback amount of said DC feedback circuit between non-zero levels,
wherein the feedback amount is different for gate position changing
and a Doppler mode.
4. An ultrasonic Doppler blood-flow meter according to claim 3
further cmprising a sample-and-hold circuit following said integrator
wherein an output signal of said integrator is held by said sample-and-hold
circuit and inputted to said DC feedback circuit.
5. An ultrasonic blood-flow meter, adapted for use in a combined
B-mode and Doppler measurement and display system, comprising:
means for transmitting an ultrasonic pulse signal into a living
body and receiving an echo signal reflected within said living body;
amplifier means for amplifying the received echo signal, said amplifier
means having a plurality of discrete selectable gain values;
phase detection means for detecting the phase of the amplifier
echo signal;
means for selecting a gated part of a phase-detected signal;
an integrator for integrating the selected phase-detected signal;
a DC feedback circuit for negatively feeding back a DC component
and a low-frequency component contained in a Doppler deviated signal
produced from said integrator to the input thereof; and
control means, adapted to receive an input representative of an
amplifier means gain change, for changing, in response to said input,
the feedback amount of said DC feedback circuit during the time
that the gain of said amplifier means is changed and immediately
after changing the amplifier means gain.
6. An ultrasonic Doppler blood-flow meter according to claim 5
further comprising a sample-and-hold circuit following said integrator
wherein an output signal of said integrator is held by said sample-and-hold
circuit and inputted to said DC feedback circuit.
7. An ultrasonic blood-flow meter, adapted for use in a combined
B-mode and Doppler measurement and display system, comprising:
means for transmitting an ultrasonic pulse signal into a living
body and receiving an echo signal reflected within said living body,
including drive means for producing a selected ultrasonic pulse
signal transmission output;
phase detection means for detecting the phase of the echo signal;
means for selecting a gated part of a phase-detected signal;
an integrator for integrating the selected phase-detected signal;
a DC feedback circuit for negatively feeding back a DC component
and a low-frequency component contained in a Doppler deviated signal
produced from said integrator to the input thereof; and
control means, adapted to receive an input representative of a
transmission output change, for changing, in response to said input,
the feedback amount of said DC feedback circuit during the time
that the pulse signal transmission output is changed and the time
immediately after changing the pulse signal transmission output.
8. An ultrasonic Doppler blood-flow meter according to claim 7
further comprising a sample-and-hold circuit following said integrator
wherein an output signal of said integrator is held by said sample-and-hold
circuit and inputted to said DC feedback circuit.
9. An ultrasonic blood-flow meter, adapted for use in a combined
B-mode and Doppler measurement and display system including display
means, comprising:
means for transmitting an ultrasonic pulse signal into a living
body and receiving an echo signal reflected within said living body,
including transmission timing means for controlling production of
said ultrasonic pulse signal;
phase detection means for detecting the phase of the echo signal;
means for selecting a gated part of a phase-detected signal;
an integrator for integrating the selected phase-detected signal;
a DC feedback circuit for negatively feeding back a DC component
and a low-frequency component contained in a Doppler deviated signal
produced from said integrator to the input thereof; and
control means, adapted to receive an input representative of a
freeze operation, for changing, in response to said input, the feedback
amount of said DC feedback circuit immediately after terminating
the freeze operation.
10. An ultrasonic Doppler blood-flow meter according to claim 9
further comprising a sample-and-hold circuit following said integrator
wherein an output signal of said integrator is held by said sample-and-hold
circuit and inputted to said DC feedback circuit.
Description BACKGROUND OF THE INVENTION
The present invention relates to an ultrasonic Doppler blood-flow
meter used in the medical field and capable of simultaneously displaying
data of a desired blood-stream in a living body and a B-mode diagnostic
image in real time.
In recent years, the ultrasonic Doppler blood-flow meter has found
its widespread use in the medical field including diagnoses of the
cardiology and the vascular organ. The ultrasonic Doppler blood-flow
meter utilizes a phenomenon that an ultrasonic pulse signal transmitted
into a living body undergoes a frequency deviation due to the Doppler
effect occurring when the pulse signal is reflected by a moving
object such as a blood stream and it is so constructed as to measure
a speed of the blood stream acting as a reflector by detecting a
Doppler deviated frequency and to permit easy observation, from
the body surface, of a blood stream speed distribution in the living
body by displaying a result of the measurement. Conventional ultrasonic
Doppler blood-flow meters will now be described with reference to
the accompanying drawings.
FIG. 1 is a functional block diagram showing a conventional ultrasonic
Doppler blood-flow meter. Referring to FIG. 1 a probe 1 converts
a pulse signal into an ultrasonic pulse signal, transmits the ultrasonic
pulse signal into a living body 14 and converts an ultrasonic wave
reflected and received from the inside of the living body into an
electrical signal. A drive circuit 2 transmits the pulse signal
to the probe 1 to drive it. A transmission timing circuit 3 generates
a timing signal for the drive circuit 2 to generate pulses. A receiving
circuit 4 amplifies an echo signal received from the probe 1. A
phase detector 5 performs phase detection of the echo signal delivered
from the receiving circuit by using reference signals. A reference
signal generation circuit 6 generates a reference signal to which
frequency and phase of the reference signals used for the phase
detection in the phase detector 5 are referenced. A gate signal
generation circuit 7 generates a gate signal during an interval
of time corresponding to a propagation time required for the ultrasonic
wave to propagate between the transmitting/receiving surface of
the probe 1 and a portion to be examined Analog switches 8a and
8b enable phase-detected signals from the phase detector 5 to be
passed during only an interval or duration of the gate signal generated
by the gate signal generation circuit 7. Integrators 9a and 9b integrate
the phase-detected signals having passed through the analog switches
8a and 8b to determine the summation of the phase-detected signals
Accordingly, by repeating transmission/reception of the ultrasonic
pulse signal, a Doppler deviated signal can be obtained. Sample-and-hold
circuits 10a and 10b hold a result of an integral operation until
a result of the next integral operation is obtained, in order to
permit resetting to be done before the integrators 9a and 9b perform
integral operations. High-pass filters 11a and 11b remove a signal
component of less than several of tens of Hz or several of hundreds
of Hz, that is, a clutter component from the Doppler deviated signals
produced by the integrators 9a and 9b. A frequency analyzer 12 analyzes
the frequency of the Doppler deviated signals passed through the
high-pass filters 1a and 11b. A display unit 13 displays results
of frequency analysis.
The above construction will now be described in greater detail
by referring to the operation thereof.
An electrical pulse signal generated by the drive circuit 2 using
a timing signal generated from the transmission timing circuit 3
as a trigger is converted by the probe 1 into an ultrasonic pulse
signal which in turn is transmitted into the living body 14 acting
as an object to be examined. The ultrasonic pulse signal propagates
within the living body and it is reflected at a portion at which
the acoustic impedance changes to reach the probe 1 and converted
into an electric signal. The thus obtained echo signal is amplified
by the receiving circuit 4 to a suitable extent and then applied
to the phase detector 5 so as to undergo phase detection. Reference
signals for phase detection generated from the reference signal
generation circuit 6 are two signals Vx and Vy being in synchronism
with a timing signal of the transmission timing circuit 3 and degrees
dephased mutually. These signals are 90 indicated by the following
equations (1) and (2):
The echo signal, E, is indicated by the following equation
where A is echo intensity and .alpha. is frequency shift coefficient.
In the phase detector 5 E in equation (3) is multiplied with each
of the signals Vx and Vy in equations (1) and (2) and there result
the following equations (4) and (5): ##EQU1##
In the right side of equations (4) and (5), the first term is of
a low frequency of about several of kHz or less and the second term
is of a high frequency of several of MHz. Accordingly, when the
analog switches 8a and 8b are turned on during only a sampling volume
obtained from these signals and signals confined within this interval
are integrated by the integrators 9a and 9b, the second term are
extinguished and a value of the first term which is proportional
to a deviation at an instant can be obtained. The data is held by
the sample-and-hold circuits 10a and 10b so that a stepped signal
representative of a discrete-time Doppler deviated signal is obtained.
The thus obtained Doppler deviated signal contains blood flow data
and a component called a clutter as well which is due to an echo
from a tissue of living body such as a vascular wall, the clutter
component being as large as about 40 dB of the blood flow component.
Therefore, for the sake of expanding the dynamic range of the frequency
analyzer 12 elimination of the influence due to an echo from a
living body tissue is of significance. The frequency of Doppler
deviated signal of the echo from living body tissue is in general
several of tens of Hz or less and is lower than that of the blood
flow component. Therefore, by removing low frequencies by means
of the high-pass filters 11a and 11b, the influence of the echo
from living body tissue can be eliminated. The thus obtained Doppler
deviated signal is subjected to frequency conversion by means of
the frequency analyzer 12 and then displayed on the display unit
13.
From the standpoint of the dynamic range of the integrators 9a
and 9b, however, the integrators 9a and 9b are applied with the
coexistence of a strong Doppler deviated signal due to the echo
from living body tissue and a weak Doppler deviated signal due to
the blood flow and therefore, when the weak Doppler deviated signal
due to the blood flow is amplified at a large gain, the integrators
9a and 9b are inconveniently saturated by the Doppler deviated signal
stemming from the living body tissue. When saturated, the Doppler
deviated signal of blood flow at that portion are extinguished and
in addition, the waveform is distorted to generate unwanted frequency
components. To cope with such a problem, a construction as described
in, for example, JP-A-61-265131 and JP-A-62-155836 has been proposed.
This prior art is illustrated in a functional block diagram of FIG.
2 of the accompanying drawings and as shown, it structurally differs
from the conventional example shown in FIG. 1 by the provision of
DC feedback circuits 15a and 15b for feeding back the output signals
of the sample-and-hold circuits 10a and 10b to the inputs of the
analog switches 8a and 8b.
FIG. 3 shows an example of a specific circuit arrangement of the
analog switch 8a or 8b, integrator 9a or 9b, DC feed back circuit
15a or 15b and sample-and-hold circuit 10a or 10b. As is clear from
FIG. 2 two channels of this circuit arrangement are needed. The
integrator 9a or 9b includes a resistor (R1) 101 a capacitor (Co)
102 an operational amplifier (OP1) 103 and an analog switch 104
and the DC feedback circuit 15a or 15b includes a resistor (R2)
105 a resistor (Rf) 106 a capacitor (Cf) 107 an operational amplifier
(OP2) 108 and an analog switch 109. Denoted by 110 is a feedback
gain control circuit. The sample-and-hold circuit 10a or 10b has
the function to amplify at a gain of -A times.
With the above construction, the operation will now be described
with reference to a timing chart of FIG. 4.
A signal subjected to phase detection by means of the phase detector
5 in a similar manner to that in the foregoing conventional example
is passed through the analog switch 8a or 8b which is turned on
during a gate interval t1-t2 and stored in the capacitor 102 of
the integrator 9a or 9b. Since the analog switch 104 is turned on
by a RESET signal in advance of the gate interval, a value resulting
from integral during only the gate interval is obtained. When the
gate interval ends, the integrated value of the integrator 9a or
9b is held in the sample-and-hold circuit 10a or 10b and at the
same time -A times amplified thereby and then applied to the DC
feedback circuit 15a or 15b through the analog switch 109. On-time
tf of the analog switch 09 is determined in accordance with a cut-off
frequency fc of the entire circuitry of FIG. 3.
The DC feedback circuit 15a or 15b is an integrator, namely, a
kind of low-pass filter. The input signal to the DC feedback, circuit
15a or 15b is inverted in phase by being -A times amplified by means
of the sample-and-hold circuit 10a or 10b and therefore the output
signal from the DC feedback circuit 15a or 15b corresponds to a
phase inversion of a DC component and an extremely low-frequency
component of the output signal of the integrator 9a or 9b. Since
the output signal of the DC feedback circuit 15a or 15b is fed back
to the input of the analog switch 8a or 8b, the fed back signal
is inputted along with the phase detected signal to the integrator
9a or 9b when the analog switch 8a or 8b is turned on, to cancel
out the DC component and extremely low-frequency component contained
in the Doppler deviated signal. Through this operation, the entire
circuitry of FIG. 3 acts as a high-pass filter having a cut-off
frequency fc given by the following equation (6): ##EQU2## where
t.sub.g =t.sub.2 -t.sub.1.
As described above, by operating the circuit arrangement of FIG.
3 saturation of the integrators 9a and 9b due to the echo from
living body tissue can be mitigated. In the foregoing example, the
output signal of the sample-and-hold circuit 10a or 10b is applied
to the DC feedback circuit 15a or 15b but similar results can be
obtained by applying the output signal of the integrator 9a or 9b
to the DC feedback circuit 15a or 15b.
Now, the principle of an ultrasonic Doppler blood-flow meter for
simultaneously displaying both of a B-mode image and a Doppler spectrum
in real time, which meter will hereinafter be referred to as a simultaneous
Doppler type meter, will be described.
In the simultaneous Doppler type, sequence of switching between
the B mode and the Doppler mode can be conceived in various ways
but a scheme in which the sequence of the B mode and Doppler mode
is alternately switched at each TX pulse, hereinafter called an
alternate scheme, is generally employed. In the alternate scheme,
however, the sampling interval of the Doppler deviated signal is
doubled, raising a problem that the maximum blood flow speed measurable
without aliasing is halved.
A different scheme from the alternate scheme has been contrived
in which switching between the B mode and Doppler mode is effected
at intervals of several of tens or several of hundreds of TX pulses.
This latter scheme will hereinafter be called a chopper scheme.
In the chopper scheme, the sampling interval remains unchanged but
the Doppler spectrum is interrupted during the B-mode period and
some compensation is needed.
In a conventional serial Doppler type based on the chopper scheme,
the deficit of signal due to the B-mode sequence intervening between
the preceding Doppler sequence and the succeeding Doppler sequence
leads to the following problems.
FIG. 5 shows an example of output waveform of the sample-and-hold
circuit in the simultaneous Doppler type based on the chopper scheme.
The sample-and-hold circuit delivers an output signal as shown at
E0 when the DC feedback circuit is not provided. This waveform contains
a small-amplitude Doppler deviated signal of blood stream superposed
on a large-amplitude Doppler deviated signal of living body tissue
but its value is zero during B-mode period because of the absence
of any input signal. As soon as the B mode switches to the Doppler
mode, a Doppler signal develops, causing a large jump of signal
at an instant of switching. In an output signal Eo of the sample-and-hold
circuit delivered out thereof when the DC feedback circuit is provided,
unwanted frequency components due to the jump of signal are generated.
Further, in many applications of the ultrasonic Doppler blood-flow
meter, control of changing the gate position, gate width, amplitude
of transmission pulse and mu-factor of receiving amplifier is carried
out by placing the ultrasonic Doppler blood-flow meter in operated
condition while monitoring the status of an object to be examined
in living body. When the changing control is effected, however,
discontinuity takes place between data before change and data after
change. Specifically, when the gate position or gate width is changed,
the position or magnitude of sample volume changes and when the
transmission pulse output signal or mu-factor of receiving amplifier
is changed, the amplitude of signal changes. In the presence of
the thus occurring discontinuity of signal, unwanted frequency components
are generated owing to the jump of signal taking place at the discontinuous
plane.
In addition to the above, the Doppler signal abruptly develops
when a freeze of the operation of the apparatus is released, and
the resulting jump of signal gives rise to occurrence of unwanted
frequency components.
SUMMARY OF THE INVENTION
The present invention intends to solve the conventional problems
and it is an object of the invention to provide an ultrasonic Doppler
blood-flow meter which can suppress the occurrence of unwanted frequency
components by suppressing the jump of signal to thereby produce
images of high quality.
To accomplish the above object, an ultrasonic Doppler blood-flow
meter according to the invention comprises means for transmitting
an ultrasonic pulse signal into a living body and receiving an echo
signal reflected within the living body, phase detection means for
detecting the phase of the echo signal, means for selecting a gate
part of a phase-detected signal, an integrator for integrating the
selected phase-detected signal, a DC feedback circuit for negatively
feeding back a DC component and a low-frequency component contained
in a Doppler deviated signal produced from the integrator to the
input thereof, and control means for changing the feedback amount
of the DC feedback circuit in synchronism with the timing for switching
between the B-mode transmission/reception sequence and the Doppler
mode sequence.
Control means is provided which, when the gate position, gate width,
amplitude of transmission pulse or mu-factor of receiving circuit
is changed, changes the feedback amount by which a Doppler deviated
signal developing immediately after completion of the changing is
negatively fed back by means of the DC feedback circuit, or which
similarly changes the feedback amount of the DC feedback circuit
immediately after releasing a freeze of the apparatus.
While the feedback amount of the DC feedback circuit is controlled
in the manner as above, operation carried out by frequency analysis
means to analyze the frequency of the Doppler deviated signal delivered
out of the integrator is interrupted.
Accordingly, in accordance with the invention, the whole of a Doppler
mode signal can be fed back negatively to the input of the integrator
by means of the DC feedback circuit by an amount of a jump developing
at the commencement of the Doppler mode, thereby cancelling out
the jump of signal at the commencement of the Doppler mode. Strictly
speaking, even in the present invention, continuity of signal cannot
be obtained at the boundary between the B mode and the Doppler mode
but when taking into consideration the fact that the Doppler deviated
frequency of the signal of living body tissue occupying most part
of signal components is sufficiently low, the continuity at the
boundary between the B mode and Doppler mode is considered to be
more eminent than that in the presence of the jump, thus ensuring
that the occurrence of unwanted frequency components can be suppressed
even when the DC feedback circuit is provided.
In addition, when the gate position where discontinuity of signal
occurs, the gate width, the transmission pulse output signal or
the mu-factor of receiving circuit is changed or when the freeze
of the apparatus is released, the occurrence of unwanted frequencies
can also be suppressed by suppressing the jump of signal through
control of the feedback amount.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a functional block diagram showing a conventional ultrasonic
Doppler blood-flow meter;
FIG. 2 is a functional block diagram showing another conventional
ultrasonic Doppler blood-flow meter;
FIG. 3 is a circuit diagram of the essential part of the FIG. 2
example;
FIG. 4 is a timing chart for explaining the operation of the FIG.
2 example;
FIG. 5 is a diagram for explaining the output waveform of a sample-and-hold
circuit in the FIG. 2 example;
FIG. 6 is a circuit diagram of the essential part of an ultrasonic
Doppler blood-flow meter according to a first embodiment of the
invention;
FIG. 7 is a timing chart in the serial Doppler mode of the ultrasonic
Doppler blood-flow meter;
FIG. 8 is a circuit diagram of the essential part of an ultrasonic
Doppler blood-flow meter according to a second embodiment of the
invention;
FIG. 9 is a circuit diagram of the essential part of an ultrasonic
Doppler blood-flow meter according to a third embodiment of the
invention;
FIG. 10 is a functional block diagram showing an ultrasonic Doppler
blood-flow meter according to a fourth embodiment of the invention;
FIG. 11 is a functional block diagram showing an ultrasonic Doppler
blood-flow meter according to a fifth embodiment of the invention;
FIG. 12 is a functional block diagram showing an ultrasonic Doppler
blood-flow meter according to a sixth embodiment of the invention;
FIG. 13 is a circuit diagram showing an example of a discretely
variable gain amplifier;
FIG. 14 is a functional block diagram showing an ultrasonic Doppler
blood-flow meter according to a seventh embodiment of the invention;
and
FIG. 15 is a functional block diagram showing an ultrasonic Doppler
blood-flow meter according to an eighth embodiment of the invention.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
Embodiment 1
A first embodiment of the invention will now be described with
reference to the accompanying drawings. The present embodiment particularly
has an integrator and a DC feedback circuit which are different
from those of the prior art example described in connection with
FIGS. 2 and 3 and therefore the structurally differing components
are illustrated here with the omission of the remaining components.
Thus, FIG. 6 is a circuit diagram showing the essential part of
an ultrasonic Doppler blood-flow meter according to the first embodiment
of the invention.
Referring to FIG. 6 there are seen an analog switch 8a or 8b,
an integrator 9a or 9b, a sample-and-hold circuit 10a or 10b, a
DC feedback circuit 15a or 15b, a sequence control circuit 16 for
B mode/Doppler mode, a feedback amount adjuster circuit 17 and a
resistor (R1) 31. The integrator 9a or 9b includes a capacitor (Co)
32 a capacitor (Co') 33 an operational amplifier (OP1) 34 and
analog switches 35 and 36. The DC feedback circuit 15a or 15b includes
an amplifier 37 of -A times amplification, a resistor (Rf) 38 a
resistor (R2) 39 a capacitor (Cf) 40 an operational amplifier (OP2)
41 and analog switches 42 and 43.
The operation of the above construction will now be described in
detail.
Firstly, the operation during the simultaneous Doppler mode based
on the chopper scheme will be described with reference to a timing
chart of FIG. 7.
During the B-mode sequence, the analog switch 43 of the DC feedback
circuit 15a or 15b is turned on under the control of the sequence
control circuit 16 to make null the charge on the capacitor (Cf)
40. When the sequence is switched from B mode to Doppler mode at
time to, the analog switch 43 is turned off under the direction
of the sequence control circuit 16. At time t1 a gate signal G
is applied to the analog switch 8a or 8b to render it on, so that
a phase-detected output signal is integrated by the integrator 9a
or 9b. At that time, because of the absence of the output signal
of DC feedback circuit 15a or 15b which is effective to cancel out
DC and extremely frequency components, only the phase-detected output
signal, that is, a large signal containing a clutter signal representative
of an echo signal of a living body tissue is inputted to the integrator
9a or 9b. Therefore, to prevent the integrator 9a or 9b from being
saturated under this condition, the analog switch 36 of integrator
9a or 9b is transferred, in advance under the control of the sequence
control circuit 26 to the capacitor (co') 33 which is larger in
capacitance than the ordinary capacitor (Co) 32. The integrated
value stored in the capacitor (Co') 33 is a value not subjected
to feedback and therefore this integrated value is not fetched into
the sample-and-hold circuit 10a or 10b but it is -A times amplified
by the amplifier 37 of the DC feedback circuit 15a or 15b and subsequently
when the analog switch 42 is turned on at time t2 under the control
of the sequence control circuit 16 by way of the feedback amount
adjuster circuit 17 it is inputted to the capacitor (Cf) 40 and
operational amplifier (OP2) 41. An width of time tf' for turn-on
of the analog switch 42 is given by the following equation (7):
##EQU3##
Charge stored in the DC feedback circuit 15a or 15b has the same
magnitude as that required for cancelling out the integrated value
of the integrator 9a or 9b at time t1. Essentially, the Doppler
deviated signal is in most part an echo signal from living body
tissue which is of DC or ultra-low frequency and therefore the integrated
value at time t1 is nearly equal to an integrated value at time
t3 at which the gate is subsequently turned on following time t1.
Accordingly, the integrated value of the phase-detected output signal
at time t3 is almost cancelled out by DC feedback based on the integrated
value at time t2. After time t2 the feedback amount to the DC feedback
circuit 15a or 15b recovers a value for ordinary Doppler mode and
the integrated value is fetched and held in the sample-and-hold
circuit 10a or 10b.
Through the above operation, the jump of signal of large amplitude
and high frequency components which results from the discontinuity
of the Doppler sequence in the serial Doppler type based on the
chopper scheme can be suppressed.
Now, an operation will be described in which the gate position
is moved by indicating an area of interest in a B-mode image by
means of a gate marker while displaying a Doppler spectrum in real
time.
When the position of the gate marker is moved, the analog switch
8a or 8b for gating is actuated in the ordinary manner in the prior
art but contrarily, in the present embodiment, the gating analog
switch 8a or 8b is kept to be off under the control of the control
circuit 16 to prevent passage of signal during movement of the gate.
Immediately after completion of movement of the gate, the gating
analog switch 8a or 8b is turned on as usual under the control of
the control circuit 16 allowing the integrator 9a or 9b to integrate
data of phase-detected output signal. Since there is a time delay
between the phase-detected signal immediately after gate movement
and that immediately before gate movement, these two signals are
mutually discontinuous. If the discontinuous data is inputted to
the succeeding high-pass filter 11a or 11b, then unwanted frequency
components will be generated. Occurrence of such components must
be prevented. The circuit shown in FIG. 6 is not limited to the
aforementioned suppression of the jump of signal due to the discontinuity
of the Doppler mode in the simultaneous Doppler type but is also
applicable to the movement of gate position also conditioned by
the discontinuity of signal, whereby the B-mode period in FIG. 7
can substitute directly for the gate moving period and a Doppler
deviated signal immediately after completion of the gate movement
can be fed back negatively to the input of the integrator 9a or
9b to prevent the occurrence of unwanted frequency components when
the gate movement is carried out. The frequency analyzer 12 is so
controlled by the control circuit 16 as not to perform operations,
thus preventing unwanted spectrum data from being displayed on the
display unit 13.
Embodiment 2
A second embodiment of the invention will now be described with
reference to the accompanying drawing.
FIG. 8 is a circuit diagram showing the essential part of an ultrasonic
Doppler blood-flow meter according to the second embodiment of the
invention.
As shown in FIG. 8 the present embodiment is so constructed that
the integrated value of an integrator 9a or 9b is fetched and held
in a sample-and-hold circuit 10a or 10b and thereafter inputted
to a DC feedback circuit 15a or 15b. The sample-and-hold circuit
10a or 10b holds an integrated value of a signal not subjected to
feedback at time t1 and therefore during delivery of the integrated
value from the sample-and-hold circuit 10a or 10b, an analog switch
44 is turned off under the control of a sequence control circuit
16 to prevent the signal from being applied to the succeeding stage.
The remaining components are the same as those of the first embodiment.
Embodiment 3
A third embodiment of the invention will now be described with
reference to the accompanying drawing.
FIG. 9 is a circuit diagram showing the essential part of an ultrasonic
Doppler blood-flow meter according to the third embodiment of the
invention.
In the first embodiment, the feedback amount to the DC feedback
circuit 15a or 15b is changed by changing the length of time interval
tf during which the analog switch is turned on but the present embodiment
is so constructed that the feedback amount is adjusted by changing
the resistance of a variable input resistor (Rf) 45 of a DC feedback
circuit 15a or 15b. The remaining components are the same as those
of the first embodiment.
Embodiment 4
A fourth embodiment of the invention will now be described with
reference to the accompanying drawing.
FIG. 10 is a functional block diagram showing an ultrasonic Doppler
blood-flow meter according to the fourth embodiment of the invention.
The present embodiment is directed to prevention of generation
of unwanted frequency components when the gate position is changed.
Referring to FIG. 10 there are seen the same components as those
of the foregoing embodiments including a probe 1 a drive circuit
2 a transmission timing circuit 3 a receiving circuit 4 a phase
detector 5 a reference signal generator 6 a gate signal generation
circuit 7 analog switches 8a and 8b, integrators 9a and 9b, sample-and-hold
circuits 10a and 10b, high-pass filters 11a and 11b, a frequency
analyzer 12 a display unit 13 DC feedback circuits 15a and 15b
and a Doppler sequence controller 16. The present embodiment further
comprises a trackball 18 for inputting gate positions, a decoder
19 for the trackball and a main controller 20.
The operation of the above construction will now be described.
A pulse signal generated by the drive circuit 2 using a signal
generated from the transmission timing circuit 3 as a trigger is
converted by the probe 1 into an ultrasonic pulse signal which in
turn is transmitted into a living body 14. The ultrasonic pulse
signal is then reflected at a portion of living body 14 at which
the acoustic impedance changes. The reflected signal is converted
by the probe 1 into an electrical signal which in turn is amplified
by the receiving circuit 4 to a suitable extent and is then subjected
to phase detection by the phase detector 5. The above operation
is the same as that of the first embodiment. Further, provided that
the gate position is not changed, the operation of the components
following the analog switches 8a and 8b is the same as that of the
first embodiment.
When the gate position is changed during operation, the apparatus
of the present embodiment operates as will be described below. A
change in gate position is inputted by means of the trackball 18
and a rotation angle of the trackball is converted by the decoder
19 into data representative of gate position change. The main controller
209 receiving the gate position change data sends to the Doppler
sequence controller 16 information to the effect that the gate position
is shifted, so that the Doppler sequence controller 16 performs
the same control as that carried out in the B mode in the serial
Doppler type to prevent display of unnecessary images. When movement
of the trackball 18 ends and a new gate position is settled, the
main controller 20 receiving gate position data from the decoder
19 causes the transmission timing circuit 3 and receiving circuit
4 to change the beam direction and at the same time sends new gate
position data to the Doppler sequence controller 16. Then, the Doppler
sequence controller 16 sends the gate position data to the gate
signal generation circuit 7 which in turn permits the same sequence
control as that carried out at the termination of the B mode in
the previously-described first embodiment. In this manner, the generation
of unwanted frequency components concomitant with gate movement
can be prevented.
Embodiment 5
A fifth embodiment of the invention will now be described with
reference to the accompanying drawing.
FIG. 11 is a functional block diagram showing an ultrasonic Doppler
blood-flow meter according to the fifth embodiment of the invention.
The present embodiment is directed to prevention of the occurrence
of unwanted frequency components when the gate width is changed.
Structurally, the present embodiment differs from the fourth embodiment
shown in FIG. 10 in that a gate width input switch 21 for setting
gate widths is provided as shown in FIG. 11. The remaining components
are the same as those of the fourth embodiment, which are designated
by identifical reference numerals, and will not be described here.
The present embodiment having the above construction operates in
a different manner from the fourth embodiment as will be described
below.
When a change in gate width is inputted by means of the switch
21 the gate width change is sent to a main controller 20 through
a decoder 19. The main controller 20 sends to a Doppler sequence
controller 16 information to the effect that the gate width is changed,
so that the Doppler sequence controller 16 prevents display of unnecessary
images and at the same time controls integrators 9a and 9b, sample-and-hold
circuits 10a and 10b and DC feedback circuits 15a and 15b similarly
to control carried out at the termination of B mode in the serial
Doppler type. Through the above operation, the generation of unwanted
frequency components concomitant with change of gate width can be
prevented.
Embodiment 6
A sixth embodiment of the invention will now be described with
reference to the accompanying drawings.
1 FIG. 12 is a functional block diagram showing an ultrasonic blood-flow
meter according to the sixth embodiment of the invention.
The present embodiment is directed to prevention of generation
of unwanted frequency components when the receiving gain is changed.
Structurally, the present embodiment differs from the fourth embodiment
shown in FIG. 10 in that a switch 22 for setting receiving gains
is provided as shown in FIG. 12. The remaining components are the
same as those of the fourth embodiment, which are designated by
identical reference numerals, and will not be described herein.
The present embodiment having the above construction operates in
a different manner from the fourth embodiment as will be described
below.
Generally, in the ultrasonic Doppler blood-flow meter, the receiving
gain can be changed by the receiving circuit 4 but the recent trend
is such that an analog switch as shown in FIG. 13 is used in a gain
change section and is transferred remotely from the operator section.
In FIG. 13 there are provided an operational amplifier 50 an analog
switch 51 and resistors 52a to 52e. The analog switch 51 controllable
through a control line of 2 bits is responsive to a digital signal
to discretely adjust the gain. In the ultrasonic Doppler blood-flow
meter having the above construction, the receiving gain is changed
discretely and therefore discontinuity takes place in a Doppler
deviated signal at a timing that the receiving gain is switched
over, resulting in display of unwanted spectra. Thus, in accordance
with the present embodiment, when a change in receiving gain is
inputted by means of the receiving gain setting switch 22 a gate
signal generation circuit 7 receives receiving gain change data
through decoder 19 main controller 20 and Doppler sequence controller
16 and causes analog switches 8a and b to be normally turned off
in order that an output signal delivered out of a phase detector
5 during the gain change is cut, and the Doppler sequence controller
6 stops a frequency analyzer 12 from producing an output signal
so as to prevent unwanted display. Immediately after completion
of the receiving gain change, the present embodiment operates similarly
to the foregoing first embodiment.
Embodiment 7
A seventh embodiment of the present invention will now be described
with reference to the accompanying drawing.
FIG. 14 is a functional block diagram showing an ultrasonic Doppler
blood-flow meter according to the seventh embodiment of the invention.
The present embodiment contemplates prevention of the occurrence
of unwanted frequency components when the transmission output is
changed.
Structurally, the present embodiment differs from the fourth embodiment
shown in FIG. 10 in that a transmission output adjusting switch
23 for adjusting the transmission output is provided as shown in
FIG. 14. The remaining components are the same as those of the fourth
embodiment, which are designated by identical reference numerals,
and will not be described here.
The present embodiment having the above construction operates in
a different manner from the fourth embodiment as will be described
below.
A pulse signal is generated by a drive circuit 2 which uses a signal
from a transmission timing circuit 3 as a trigger, and the delivery
of the pulse signal is controlled by a value inputted by means of
the switch 23.
The operation when the transmission output is changed will now
be described. When a change in transmission output is inputted by
means of the transmission output adjusting switch 23 a gate signal
generation circuit 7 receives transmission output change data through
decoder 19 main controller 20 and Doppler sequence controller 16
and normally turns off analog switches 8a and 8b in order to cut
an output signal delivered out of a phase detector 5 during the
change of transmission output and at the same time the Doppler sequence
controller 16 stops a frequency analyzer 12 from delivering an output
signal to prevent unnecessary display. Immediately after completion
of the transmission output change, the present embodiment operates
similarly to the foregoing first embodiment.
Embodiment 8
An eighth embodiment of the invention will now be described with
reference to the accompanying drawing.
FIG. 15 is a functional block diagram showing an ultrasonic blood-flow
meter according to the eighth embodiment of the invention.
The present embodiment contemplates prevention of the occurrence
of unwanted frequency components when a freeze of the apparatus
is released.
Structurally, the present embodiment differs from the fourth embodiment
shown in FIG. 10 in that a freeze switch 24 for setting and release
of freeze is provided as shown in FIG. 15. The remaining components
are the same as those of the fourth embodiment, which are designated
by identical reference numerals, and will not be described herein.
The present embodiment having the above construction operates in
a different manner from the fourth embodiment as will be described
below.
When the operation of the apparatus is desired to be stopped temporarily
to freeze the image display, display of transmission/reception images
can all be stopped by operating the switch 24. When the freeze is
released, the apparatus recovers the same operation as that carried
out when the B mode is switched to the Doppler mode in the first
embodiment.
The fourth to eighth embodiments have been described as using the
circuit of the first embodiment but they may be realized with the
circuits of the second and third embodiments. |