Impedance analyzer

An impedance analyzer includes: a control voltage generating unit for generating a control voltage that has a predetermined amplitude value; a measuring unit operable to provide an output current, which has an amplitude value corresponding to that of the control voltage, for flowing through first and second body portions of a biological target, and to generate a measurement voltage that has an amplitude value corresponding to a difference between voltages at the first and second body portions attributed to flow of the output current therethrough; and a calculating module operable to determine an electrical impedance between the first and second body portions according to a predetermined adjustment value and the amplitude value of the measurement voltage.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims priority of Taiwanese Application No. 101100312, filed on Jan. 4, 2012.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to an impedance analyzer, more particularly to an impedance analyzer suitable for analyzing impedance of a biological target.

2. Description of the Related Art

A conventional impedance analyzer, such as model WK6420C available from Dongguan YuanYi Electronics Co., lacks a protection mechanism for limiting constant current. During use, when a current generated by the impedance analyzer is provided through a human body, injury may occur if the current is too large.

SUMMARY OF THE INVENTION

Therefore, an object of the present invention is to provide an impedance analyzer capable of alleviating the aforesaid drawback of the prior art.

Accordingly, an impedance analyzer of the present invention is suitable to be coupled electrically across first and second body portions of a biological target for determining electrical impedance therebetween.

The impedance analyzer includes a readout module and a calculating module.

The readout module includes a control voltage generating unit and a measuring unit. The control voltage is operable to generate a control voltage that has a predetermined amplitude value. The measuring unit is adapted to be coupled electrically across the first and second body portions, is connected electrically to said control voltage generating unit for receiving the control voltage from the control voltage generating unit, and is operable to provide an output current according to the control voltage received by the measuring unit for flowing through the first and second body portions. The output current has an amplitude value that corresponds to the amplitude value of the control voltage received by the measuring unit. The measuring unit is further operable to generate a measurement voltage that has an amplitude value corresponding to a difference between voltages at the first and second body portions attributed to flow of the output current through the first and second body portions.

The calculating module has stored therein a predetermined adjustment value, is connected electrically to the measuring unit for receiving the measurement voltage from the measuring unit, and is operable to determine the electrical impedance between the first and second body portions according to the predetermined adjustment value and the amplitude value of the measurement voltage received by the calculating module.

Another object of the present invention is to provide a readout module suitable to be coupled electrically across first and second body portions of a biological target so as to generate a measurement voltage according to a difference between voltages at the first and second body portions attributed to flow of an output current through the first and second body portions.

Accordingly, a readout module of the present invention includes a control voltage generating unit and a measuring unit.

The control voltage generating unit is operable to generate a control voltage that has a predetermined amplitude value.

The measuring unit is adapted to be coupled electrically across the first and second body portions, is connected electrically to the control voltage generating unit for receiving the control voltage from the control voltage generating unit, and is operable to provide the output current according to the control voltage received by the measuring unit for flowing through the first and second body portions. The output current has an amplitude value that corresponds to the amplitude value of the control voltage received by the measuring unit. The measuring unit is further operable to generate the measurement voltage that has an amplitude value corresponding to the difference between the voltages at the first and second body portions.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

Referring toFIG. 1, the preferred embodiment of an impedance analyzer according to the present invention is suitable to be coupled electrically across first and second body portions (B1, B2) of a biological target (B) for determining electrical impedance therebetween, and includes a readout module (RM) and an calculating module (CM) operatively associated with the readout module (RM).

The readout module (RM) includes a control voltage generating unit (VGU) operable to generate an alternating-current (AC) control voltage that has a predetermined amplitude value. In this embodiment, the control voltage generating unit (VGU) includes an oscillator circuit1operable for generating an oscillation signal, and an amplifying circuit2connected electrically to the oscillator circuit1for receiving the oscillation signal from the oscillator circuit1and for amplifying the oscillation signal so as to generate the control voltage.

In this embodiment, the oscillation signal thus generated has an amplitude value of 2V, ranging from −1V to 1V, and has a frequency adjustable between the range of 0.1 MHz to 20 MHz via a variable resistor RV (seeFIG. 2).

Referring toFIG. 2, the amplifying circuit2includes a first operational amplifier (OP1), a first resistor (R1), and a second resistor (R2). The first operational amplifier (OP1) has an inverting input terminal connected electrically to the oscillator circuit1via the first resistor (R1) for receiving the oscillation signal therefrom, a grounded non-inverting input terminal, and an output terminal connected electrically to the inverting input terminal via the second resistor (R2). The first operational amplifier (OP1) is operable to generate the control voltage for output via the output terminal thereof. The control voltage thus generated has an amplitude value corresponding to an absolute value of a result of product of the amplitude value of the oscillation signal and a resistance of the second resistor (R2) divided by a resistance of the first resistor (R1).

Referring once more toFIG. 1, the readout module (RM) further includes a measuring unit (VPU) connected electrically to the control voltage generating unit (VGU) for receiving the control voltage therefrom, and operable to provide an output current according to the control voltage received by the readout module (RM) for flowing through the first and second body portions (B1, B2) of the biological target (B). The output current has an amplitude value varying in a positive relation to the predetermined amplitude value of the control voltage.

The measuring unit (VPU) includes a voltage-controlled current generator3, first and second buffers4,4′, and a differential amplifier5.

Referring toFIG. 3, the voltage-controlled current generator3includes a second operational amplifier (OP2) and a third resistor (R3). The second operational amplifier (OP2) has an inverting input terminal that is connected electrically to the amplifying circuit2via the third resistor (R3) for receiving the control voltage therefrom and that is adapted to be coupled electrically to the first body portion (B1), a grounded non-inverting input terminal, and an output terminal that is adapted to be coupled electrically to the second body portion (B2). A current flowing through the third resistor (R3) serves as the output current.

In this embodiment, the amplitude value of the output current corresponds to a result of division of the amplitude value of the control voltage by a resistance of the third resistor (R3). Since the amplitude value of the control voltage is predetermined, the amplitude value of the output current is also predetermined.

The first and second buffers4,4′ include third and fourth operational amplifiers (OP3, OP4), respectively.

The third operational amplifier (OP3) has a non-inverting input terminal connected electrically to the inverting input terminal of the second operational amplifier (OP2), an inverting input terminal, and an output terminal connected electrically to the inverting input terminal of the third operational amplifier (OP3). The third operational amplifier (OP3) is operable to generate a first voltage, according to a voltage at the inverting input terminal of the second operational amplifier (OP2), for output via the output terminal thereof. The first voltage thus generated has an amplitude value corresponding to the amplitude value of the voltage at the first body portion (B1).

The fourth operational amplifier (OP4) has a non-inverting input terminal connected electrically to the output terminal of the second operational amplifier (OP2), an inverting input terminal, and an output terminal connected electrically to the inverting input terminal of the fourth operational amplifier (OP4). The fourth operational amplifier (OP4) is operable to generate a second voltage, according to a voltage at the output terminal of the second operational amplifier (OP2), for output via the output terminal thereof. The second voltage thus generated has an amplitude value corresponding to the amplitude value of the voltage at the second body portion (B2).

The differential amplifier5is connected electrically to the output terminal of each of the third and fourth operational amplifiers (OP4, OP5) for receiving a corresponding one of the first and second voltages therefrom, and is operable to generate a measurement voltage having an amplitude value that varies in a positive relation to a difference between the first and second voltages received by the differential amplifier5.

In this embodiment, the differential amplifier5includes fourth, fifth, sixth, and seventh resistors (R4-R7), and a fifth operational amplifier (OP5) having: an inverting input terminal that is connected electrically to the output terminal of the fourth operational amplifier (OP4) via the fifth resistor (R5) for receiving the second voltage therefrom; a non-inverting input terminal that is connected electrically to the output terminal of the third operational amplifier (OP3) via the fourth resistor (R4) for receiving the first voltage therefrom, and that is connected electrically to ground via the sixth resistor (R6); and an output terminal that is connected electrically to the inverting input terminal of the fifth operational amplifier (OP5) via the seventh resistor (R7). The fifth operational amplifier (OP5) is operable to generate the measurement voltage for output via the output terminal thereof according to the first and second voltages received by the fifth operational amplifier (OP5).

The differential amplifier5has a gain corresponding to a result of division of a resistance of the seventh resistor (R7) by that of the fifth resistor (R5), which is substantially equal to a result of division of a resistance of the sixth resistor (R6) by that of the fourth resistor (R4), and which, in this embodiment, is equal to two. The amplitude value of the measurement voltage corresponds substantially to a result of division of the difference between the first and second voltages by the gain of the differential amplifier5.

Since the amplitude value of the output current is predetermined, the calculating module (CM) may be preconfigured with a predetermined adjustment value corresponding to the predetermined amplitude value of the output current for later comparison with the amplitude value of the measurement voltage outputted by the measuring unit (VPU) so as to determine the electrical impedance between the first and second body portions (B1, B2). In particular, the impedance value thus determined corresponds to a result of division of the difference between the first and second voltages by the predetermined adjustment value.

In summary, since the amplitude value of the output current varies in a positive relation with the predetermined amplitude value of the control voltage, the amplitude value of the output current does not vary according to the electrical impedance of the biological target (B), thereby reducing the risk of injury to the biological target (B).