MULTI-FUNCTIONAL PH METER AND FABRICATION THEREOF
A multi-functional PH meter and the fabrication thereof are disclosed. The multi-functional pH meter comprises a sensor unit, an analog signal processing unit, a microprocessor unit, a liquid crystal display unit, a compact flash card unit and a data transmission unit. The sensor unit includes an electrode, a substrate, an indium tin oxide film on the substrate, a sensing film on the indium tin oxide film and connecting to a conductive wire, a package material covering the sensing film, the indium tin oxide film and a portion of the substrate and exposing the sensing film via a sensing window. The analog signal processing unit processes analog signals from the sensing unit via the conductive wire. The microprocessor unit receives the signals from the analog signal processing unit and generates a pH value of a solution being detected. The liquid crystal display unit displays the pH value and the compact flash card unit saves the pH value. The data transmission unit transmits the pH value to a computer via Universal Serial Bus (USB) and Universal Asynchronous Receiver/Transmitter (UART) interfaces.
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1. Field of the Invention
The present invention is generally related to a multi-functional pH meter and fabrication thereof, and more particularly to a multi-functional pH meter and fabrication thereof by integrating semiconductor processes and embedded system technology.
2. Description of the Prior Art
Ion sensitive field effect transistors (ISFETs) are micro sensing devices appeared in 70s and quickly developed. For only 30 years till now, there are more than 600 research papers and 150 other related papers, such as enzyme field effect transistors (EnFETs) and immuno field effect transistors (IMFETs) (P. Bergveld, “Thirty years of ISFETOLOGY: What happened in the past 30 years and what may happen in the next 30 years”, Sensors and Actuators B, Vol. 88, pp. 1-20, 2003.). In addition, ion sensitive field effect transistors can be used to measure pH values and ion concentrations, such as Na+, K+, Cl−, NH4+, Ca2+, in stead of fragile glass electrodes (Miao Yuqing, Guan Jianguo, and Chen Jianrong, “Ion sensitive field effect transducer-based biosensors”, Biotechnology Advances, Vol. 21, pp. 527-534, 2003.). The idea was first introduced by P. Bergveld. By using a metal oxide semiconductor field effect transistor (MOSFET) without a gate electrode, a device with a SiO2 layer is placed in aqueous solution together with a reference electrode. The electric current passing the device changes with the hydrogen-ion concentration, whose response is similar to that of a glass electrode. Thus, it has the acid-base sensing characteristic (Chen Jian-pin, Lee Yang-li, Kao Hung, “Ion sensitive field effect transistors and applications thereof”, Analytical Chemistry, Vol. 23, No. 7, pp. 842-849, 1995; Wu Shih-hsiang, Yu Chun, Wang Kuei-hua, “Measurement by chemical sensors”, Sensor technology, No. 3, pp. 57-62, 1990).
Some ISFET sensing devices have been commercialized, such as ISFET pH meters made by Arrow Scientific, Deltatrak, and Metropolis. However, it has problems of stability and lifetime, for example drift phenomena and hysteresis effect. The present invention discloses another type of ISFETs, an extended gate field effect transistor (EGFET). The field effect transistor (FET) is isolated from the chemical measurement environment. The chemical sensing film is deposited on one end of the signal wire extended from the area of the gate electrode. The portions of the electric effect and the chemical effect are packaged separately. Therefore, compared to conventional ISFETs, EGFETs are easy in packaging and storage and have better stability (Liao Han-chou, “Novel calibration and compensation technique of circuit for biosensors”, June 2004, Department of electrical engineering, Chung Yuan Christian University, Master dissertation, pp. 11-29).
Recently, there are many researches in characteristics of the extended gate ion sensitive field effect transistors, such as device design (Li Te Yin, Jung Chuan Chou, Wen Yaw Chung, Tai Ping Sun, and Shen Kan Hsiung, “Separate structure extended gate H+-ion sensitive filed effect transistor on a glass substrate”, Sensors and Actuators B, Vol. 71, 106-111, 2000; Li Te Yin, Jung Chuan Chou, Wen Yaw Chung, Tai Ping Sun, and Shen Kan Hsiung, “Study of indium tin oxide thin film for separative extended gate ISFET”, Materials Chemistry and Physics, Vol. 70, pp. 12-16, 2001; Li Te Yin, Jung Chuan Chou, Wen Yaw Chung, Tai Ping Sun, Kuang Pin Hsiung, and Shen Kan Hsiung, “Study on glucose ENFET doped with MnO2 powder”, Sensors and Actuators B, Vol. 76, pp. 187-192, 2001; Yin Li-Te, “Study of Biosensors Based on an Ion Sensitive Field Effect Transistor”, June 2001, Department of biomedical engineering, Chung Yuan Christian University, Ph. D. dissertation, pp. 76-108.), characteristic analysis (Jia Yong-Long, “Study of the extended gate field effect transistor (EGFET) and signal processing IC using the CMOS technology”, June 2001, Department of electrical engineering, Chung Yuan Christian University, Ph. D. dissertation, pp. 36-44; Chen Jia-Chi, “Study of the disposable urea sensor and the pre-amplifier”, June 2002, Department of biomedical engineering, Chung Yuan Christian University, Master dissertation, pp. 51-80; Jia Chyi Chen, Jung Chuan Chou, Tai Ping Sun, and Shen Kan Hsiung, “Portable urea biosensor based on the extended-gate field effect transistor”, Sensors and Actuators B, Vol. 91, pp. 180-186, 2003; Chung We Pan, Jung Chuan Chou, I Kone Kao, Tai Ping Sun, and Shen Kan Hsiung, “Using polypyrrole as the contrast pH detector to fabricate a whole solid-state pH sensing device”, IEEE Sensors Journal, Vol. 3, pp. 164-170, 2003; Jui Fu Cheng, Jung Chuan Chou, Tai Ping Sun, and Shen Kan Hsiung, “Study on the chloride ion selective electrode based on the SnO2/ITO glass”, Proceedings of The 2003 Electron Devices and Materials Symposium (EDMS), National Taiwan Ocean University, Keelung, Taiwan, R.O.C., pp. 557-560, 2003; Jui Fu Cheng, Jung Chuan Chou, Tai Ping Sun, and Shen Kan Hsiung, “Study on the chloride ion selective electrode based on the SnO2/ITO glass and double-layer sensor structure”, Proceedings of The 10th International Meeting on Chemical Sensors, Tsukuba International Congress Center, Tsukuba, Japan, pp. 720-721, 2004.), characteristics of drift phenomena and hysteresis effect (Liao Han-chou, “Novel calibration and compensation technique of circuit for biosensors”, Master dissertation, Department of electrical engineering, Chung Yuan Christian University, pp. 11-29, June 2004; Chu Neng Tsai, Jung Chuan Chou, Tai Ping Sun, and Shen Kan Hsiung, “Study on the hysteresis of the metal oxide pH electrode”, Proceedings of The 10th International Meeting on Chemical Sensors, Tsukuba International Congress Center, Tsukuba, Japan, pp. 586-587, 2004; Chu Neng Tsai, Jung Chuan Chou, Tai Ping Sun, and Shen Kan Hsiung, “Study on the sensing characteristics and hysteresis effect of the tin oxide pH electrode”, Sensors and Actuators B, Vol. 108, pp. 877-882, 2005.).
SUMMARY OF THE INVENTIONCompared to the above described prior arts, the present invention provides a multi-functional pH meter by integrating semiconductor processes and embedded system technology. An acid-base sensing electrode with a tin dioxide/indium tin oxide/glass separate structure together with embedded system technology is used to fabricate the multi-functional pH meter.
The multi-functional pH meter according to the present invention immediately displays the measurement result on a liquid crystal display and saves in a compact flash card so as to have portable functionality. In addition, the multi-functional pH meter has data communication functionality with a computer. Finally, the drift and hysteresis software calibration technique is applied. Thus, this method can increase ion detection accuracy and system reliability. The device can be applied in pH value measurement. If other polymer selection substance is used, other type of ions can also be detected and applicability is also increased. It can also increase accuracy, applicability, and industrial applications in clinics, bio-signals, and environmental detection. Because the fabrication method requires only simple equipments, is also low in cost, and can be massively produced, the multi-functional pH meter according to the present invention has very high applicability in pH value measurement.
Table 1 shows measurement results in various buffer solutions by the multi-functional pH meter in a preferred example according to the present invention.
Table 2 shows the specification of the multi-functional pH meter in a preferred example according to the present invention.
DESCRIPTION OF THE PREFERRED EMBODIMENTSSome preferred embodiments of the present invention will now be described in greater detail in the following. However, it should be recognized that the present invention can be practiced in a wide range of other embodiments besides those explicitly described, that is, this invention can also be applied extensively to other embodiments, and the scope of the present invention is expressly not limited except as specified in the accompanying claims. In order to have clear description of the invention and better understanding for those who are skilled in the art, some part of the figures is not drawn in proportion, in which the size of some part has been exaggerated. Besides, some of irrelevant part is not shown for simplicity.
In a preferred example of the present invention, fabricating a separate structure extended gate ion selective sensor includes the following steps:
An indium tin oxide film (ITO film) is formed on a substrate. In a preferred example of the present invention, the thickness of the indium tin oxide film is about 230 Å, but is not limited. The substrate is an insulation substrate, such as ceramic substrate, glass substrate. Glass substrate is preferred.
The glass substrate with the ITO film is placed in a solution, especially in methanol solution and deionized water, and oscillated by an ultrasonic oscillator. A preferred oscillation period is about 15 minutes each in the methanol solution and deionized water. It is not limited to 15 minutes.
The process for fabricating a sensing film comprises depositing a tin dioxide (SnO2) film by physical vapor deposition method. A RF (radio frequency) sputtering method is preferred and the sputtering target is tin dioxide. Preferred material for the sensing film is tin dioxide, but is not limited to tin dioxide. Mixture gas is then flowing into the reaction chamber and the substrate is maintained at a constant temperature. Preferred mixture gas is mixture of argon and oxygen gas. The temperature of the substrate is preferably about 150° C. for depositing a tin dioxide (SnO2) film, the deposition pressure is preferably about 20 mTorr, the RF power is preferably about 50 W, the thickness of the film is preferably about 2000 Å , and the mixing ratio of argon and oxygen is preferably 4:1.
Following that, a conductive wire is formed and packaging a sensing electrode is carried out. The conductive wire is preferably a silver wire. The conductive wire is adhered to the tin dioxide film via silver paste. The packaging material is preferably epoxy resin but can be other suitable material. Preferably, the epoxy resin sensing widow has an area of 3×3 mm2.
A glass electrode is formed as a reference electrode to provide stable reference potential. The glass electrode is preferably a silver/silver chloride glass electrode but can be other suitable electrode.
Fabricating a sensing system according to the present invention comprises the following steps:
An amplifier is used as a front-end processing circuit and then filtering low-frequency noise is carried out. Considering interference of the low-frequency noise, a 2nd order Butterworth filter is used to filter out low-frequency noise. The signal is sent to a level adjusting circuit for adjusting the potential level and then an output signal (output signal of step 1) is outputted for next step.
The output signal of step 1 is used as an input signal and transmitted to a PIC18F452 single chip microprocessor, using an embedded system as the core. After processing by the built-in 10-bit progressive A/D converter, a two-point (pH4, pH7) calibration procedure can be carried out and a quantized absolute pH value in the measurement range is calculated. The numerical value in each measurement interval is complete.
The sensor is placed in an unknown solution. Software calibration is carried out to improve the problems of hysteresis effect and drift phenomena in the sensor unit. Following that, the two-point (pH4, pH7) calibration procedure is performed to eliminate the error so as to provide more accurate sensing signal. Finally, the pH value measurement result is displayed on a liquid crystal display (LCD) immediately and saved in a memory card, such as a compact flash card (CF card). In a readout procedure from a CF card, data can be read to a computer via a card reader. In addition, the device according to the present invention can transmit the measurement result to a personal computer or a laptop computer via the transmission interface, such as universal serial bus (USB) and universal asynchronous receiver/transmitter (UART) interfaces, so as to enhance the flexibility of the system. By the above described method, the pH value of the unknown solution is informed to the user.
starting a drift program 25 (using a PIC18F452 microprocessor as a processing core);
recording every measurement value in a data memory as a data base 26;
comparing the data base with the reference pH value (pHref) and calculating the difference 27 for each measurement;
determining if the difference is caused by drift phenomena and then carrying out a drift procedure 28, or if the difference is caused by variation in the unknown solution and then carrying out an appropriate calibration, i.e. processing with a reaction procedure 29;
outputting the result from the drift calibration procedure, i.e. output 30.
Working zone→Zone A: normal zone; Zone B: calibration zone; Zone C: Reaction zone.
Zone A: if the output pH value is between (pHref−0.005) (pH) and (pHref+0.005) (pH), the calibration procedure is not executed.
Zone B: if the output pH value is smaller than (pHref−0.005) (pH) or greater than (pHref+0.005) (pH), the calibration procedure is executed.
Zone C: if the output pH value is smaller than (pHref−0.01) (pH) or greater than (pHref+0.01) (pH), the unknown solution is varied.
starting a hysteresis calibration program 31 (using a PIC18F452 microprocessor as a processing core);
recording every measurement value in a data memory as a data base 32;
calculating the slope 33 for every measurement;
comparing the data base 34 with the sensitivity 35 calculated from the two-point calibration and determining the process is either on an acid side or a base side 36;
calculating the difference (hysteresis quantity) and eliminating the hysteresis quantity 37;
outputting the result 38 from the hysteresis calibration.
L1: standard curve (result from the two-point calibration)
y=ax+b
L2: measurement curve (result from the hysteresis effect)
y=cx+d
If m1≠m2, Error=y2−y1=Δy=Hysteresis
>Hysteresis=(m2−m1)×x
→Output′=Output−Hysteresis
A compact flash card is organized as the following:
memory cell array: 528×16K×8 bytes;
register: 528×8 bytes;
page: 528 bytes;
block: 8K+256 bytes;
a block comprises 16 pages and a page comprises 528 bytes.
In order to be compatible with the conventional disk drive configuration, byte 0˜511 (first 512 bytes) is treated as one sector and byte 512-528 (last 16 bytes) is treated as a spare region.
Procedure for reading the sector:
Step 1: setting CHS parameters in Cylinder Low, Cylinder High, Sector Number, and Sector Count registers in which data in the Sector Count register is set to be 01H in order to request 256 times of data reading and the total capacity is one sector;
Step 2: sending a reading command to the command register in which the command code is 20H and the address of the register to write in is 07H;
Step 3: reading the parameters in the status register in which the memory card is ready for data transmission (DRQ=1) between the CPU and the memory card if BUSY=0, RDY=1, DSC=1, and DRQ=1 in the status register, i.e. 58H status code;
Step 4: reading the parameters at the memory address in the data register and writing in the data buffer for 256 times in which the memory address pointer in the data buffer increases progressively after each writing in; and,
Step 5: confirming if the memory card returns to the ready status and the data request status is finished after data reading is complete, that is, the parameters BUSY=0, RDY=1, DSC=1, and DRQ=0 in the status register, i.e. 50H status code, representing the memory card is ready for next command input.
The procedure for writing into the sector is similar to that for reading except that the command code is 30H in the step 2 for writing instead of 20H for reading. According to the above described reading and writing procedure flow, data access can be complete.
Table 1 shows measurement results in various buffer solutions (from pH 2 to pH 12) by the multi-functional pH meter in a preferred example according to the present invention. Compared to the commercial pH meter, the multi-functional pH meter according to the present invention has very small errors, in the range between 2% to 4%. It has excellent functionality and potential in commercialization.
Table 2 shows the specification of the multi-functional pH meter in a preferred example according to the present invention.
Obviously many modifications and variations are possible in light of the above teachings. It is therefore to be understood that within the scope of the appended claims the present invention can be practiced otherwise than as specifically described herein. Although specific embodiments have been illustrated and described herein, it is obvious to those skilled in the art that many modifications of the present invention may be made without departing from what is intended to be limited solely by the appended claims.
Claims
1. A multi-functional pH meter, comprising:
- a sensor unit comprising a substrate, an indium tin oxide film on said substrate, a sensing film on said indium tin oxide film and connecting to a conductive wire, an electrode, and a package material covering said sensing film, said indium tin oxide film, and a portion of said substrate and exposing the sensing film via a sensing window;
- an analog signal processing unit for processing analog signals from said sensing unit via said conductive wire;
- a microprocessor unit for receiving the signals from said analog signal processing unit and generating a pH value of a solution being detected;
- a liquid crystal display unit for displaying the pH value;
- a compact flash card unit for storing the pH value; and
- a data transmission unit for transmitting the pH value to a computer via Universal Serial Bus (USB) and Universal Asynchronous Receiver/Transmitter (UART) interfaces;
- an amplifier used as a front-end processing circuit for a sensing signal to increase the signal-to-noise ratio of said sensing signal:
- a low pass filter for filtering low frequency noises and suppressing the interference of the 60 Hz AC mains frequency to said sensing signal: and
- a level adjusting circuit for adjusting the potential level of the processed sensing signal to fit the input range and specification of a analog/digital converter.
2. The meter according to claim 1, wherein said sensing film comprises a tin dioxide film.
3. The meter according to claim 2, wherein said tin dioxide film is deposited on said indium tin oxide film and said substrate by a RF (radio frequency) sputtering method.
4. The meter according to claim 3, wherein the thickness of said tin dioxide film is about 2000 Å.
5. The meter according to claim 1, wherein said substrate comprises a ceramic substrate.
6. The meter according to claim 1, wherein said substrate comprises a glass substrate.
7. The meter according to claim 1, wherein said conductive wire comprises a silver wire.
8. The meter according to claim 7, wherein said silver wire is adhered to said sensing film via silver paste.
9. The meter according to claim 1, wherein said package material comprises epoxy resin.
10. The meter according to claim 1, wherein said electrode comprises a silver/silver chloride glass electrode.
11. The meter according to claim 1, wherein said sensing window has an area of 3 mm×3 mm on said package material.
12. (canceled)
13. The meter according to claim 1, wherein said microprocessor unit comprises:
- a firmware of analog/digital converting procedure for controlling 10-bit analog/digital converter built in said microprocessor unit, comprising controls of sampling rate, channel selection, and reference potential;
- a firmware of two-point calibration procedure for completing said two-point calibration procedure; and,
- a firmware of drift and hysteresis calibration procedure for calibrating drift phenomena and hysteresis effect.
14. The meter according to claim 1, wherein the transmission interface of said data transmission unit comprises Universal Serial Bus (USB) and Universal Asynchronous Receiver/Transmitter (UART) interfaces.
15. The meter according to claim 1, wherein said microprocessor unit receives the signals from said analog signal processing unit and thereby calculates the procedure of processing the pH value, comprising:
- carrying out analog signal quantization by a analog/digital converter;
- performing a two-point calibration procedure and calculating the pH value;
- performing a drift and hysteresis calibration procedure for the pH value;
- immediately displaying the pH value on said liquid crystal display unit;
- saving the pH value in said compact flash card unit;
- transmitting the pH value to a computer.
16. The meter according to claim 15, wherein the procedure of processing the pH value calculated by said microprocessor unit further comprises: reading out the pH value from said compact flash card unit by a card reader and into a computer
17. The meter according to claim 15, wherein said drift calibration procedure comprises:
- starting a drift program;
- recording every measurement value in a data memory as a data base;
- comparing the data base with the reference pH value (pH ref) and calculating the difference for every measurement;
- determining if the difference is caused by drift phenomena or variation in the tested solution and carrying out calibration; and
- outputting the result from the calibration procedure.
18. The meter according to claim 15, wherein said hysteresis calibration procedure comprises:
- starting a hysteresis calibration program;
- recording every measurement value in a data memory as a data base;
- calculating the slope for every measurement;
- comparing the data base with the sensitivity calculated from the two-point calibration and determining the process is either on an acid side or a base side;
- calculating the difference (hysteresis quantity) and eliminating the hysteresis quantity;
- outputting the result from the hysteresis calibration.
Type: Application
Filed: Aug 18, 2006
Publication Date: Mar 13, 2008
Applicant: CHUNG YUAN CHRISTIAN UNIVERSITY (Tao-Yuan)
Inventors: Shen-Kan Hsiung (Tao-Yuan), Jung-Chuan Chou (Tao-Yuan), Tai-Ping Sun (Tao-Yuan), Nien-Hsuan Chou (Tao-Yuan), Gin-Chou Yang (Tao-Yuan)
Application Number: 11/465,776
International Classification: G01N 27/416 (20060101);