Inspection apparatus and inspection method of magnetic sensor

A magnetic sensor inspection apparatus has a rectangular frame including a stage, a probe card, and a plurality of magnetic field generating coils. A wafer-like array of magnetic sensors is mounted on the stage, which is movable in horizontal and vertical directions. The probe card includes a plurality of probes which are brought into contact with a plurality of magnetic sensors encompassed in a measurement area. The magnetic field generating coils are driven to generate a magnetic field toward the stage. A plurality of magnetic field environment measuring sensors is arranged in the peripheral portion of the probe card surrounding the probes. A magnetic field controller controls magnetic fields generated by the magnetic field generating coils based on the measurement result of the magnetic field environment measuring sensors. Thus, it is possible to concurrently inspect a wafer-like array of magnetic sensors with the probe card.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to an inspection apparatus and an inspection method for use in inspection routines of magnetic sensors, in particularly for use in routines of inspecting a wafer-like array of magnetic sensors in terms of their magnetic property and sensitivity via magnetic property testing under predetermined environmental conditions.

The present application claims priority on Japanese Patent Application No. 2011-175337, the content of which is incorporated herein by reference.

2. Description of the Related Art

According to conventionally-known inspection routines of magnetic properties of magnetic sensors, magnetic sensors are each placed in a magnetic field which is generated using magnetic field generating coils such as Helmholtz coils and subsequently subjected to testing to measure their output signals. Inspecting each single magnetic sensor enclosed in its package needs troublesomeness treatment and may suffer a financial loss in the assembling cost of magnetic sensors which are determined as defective ones through inspection. For this reason, it is an efficient way to collectively inspect a wafer-like array of magnetic sensors. Various technologies for inspecting a wafer-like array of magnetic sensors have been developed and disclosed in various documents such as PLT 1 and PLT 2.

PLT 1 disclosed an inspection method of a magnetic sensor chip. Herein, a test probe is brought into contact with a magnetic sensor chip, and then a magnetic field generator is moved close to the magnetic sensor chip in a preparation stage of inspection. Specifically, the distal end of a coil prober approaches a magnetic sensor so as to apply a magnetic field to the magnetic sensor, thus measuring the output signal of a magnetic sensor with a test probe. The distal end of a coil prober is able to generate a magnetic field with a single directivity. For the purpose of inspecting the output signal of a magnetic sensor exposed to an external magnetic field with multiple directivities, it is necessary to rotate the relative positioning between a coil prober and a magnetic sensor.

PLT 2 disclosed an inspection method of a magnetic sensor by use of a probe card which is brought into contact with a magnetic sensor. Specifically, a probe card including a plurality of coils is brought into contact with a wafer fabricating a magnetic sensor; electric currents are supplied to the coils of a probe card so as to apply a magnetic field to a magnetic sensor, thus detecting the output signal of a magnetic sensor with the probe card. This technology is able to change the magnitude and/or the directivity of a magnetic field applied to a magnetic sensor by changing electric currents supplied to a plurality of coils included in a probe card.

PLT 3 disclosed a weak magnetic field generator and an inspection method of a magnetic sensor, which does not necessarily relate to inspection of a magnetic sensor. Herein, an external magnetic field is applied to a geomagnetic bearing sensor with sensitivity in two directions having a rectangle angle therebetween in a single plane, and then an electric signal is supplied to a geomagnetic bearing sensor, thus analyzing the output signal of a geomagnetic sensor. Specifically, this inspection method utilizes a substrate table equipped with a socket for arranging a magnetic sensor, a magnetic field generating coil, and a magnetic field sensor, wherein the detection result of a magnetic field sensor is fed back to a magnetic field generating coil.

As described above, it is an efficient way to collectively inspect a plurality of magnetic sensors rather than each single magnetic sensor. In this case, it is necessary to employ a large coil which is able to generate a magnetic field covering a relatively large inspection area encompassing a plurality of sensors. The foregoing technologies disclosed in PLT 1 and PLT 2 utilize a probe card equipped with a coil; hence, it is difficult to enlarge the size of a coil due to its structural limitation. Additionally, they may undergo local variation of a magnetic field which is generated to cover a large inspection area. That is, the foregoing technologies of PLT 1 and PLT 2 may be degraded in their accuracy of inspection results because they simply control an electric current to determine whether or not a desired magnetic field is generated with a coil

The other technology such as PLT 3 may be an effective solution to this problem because the detection result of a magnetic field sensor is fed back to a magnetic field generating coil. However, this technology needs a single table equipped with a magnetic field sensor, a socket, and a magnetic field generating coil, wherein for the purpose of preventing interference with the socket and the coil in their positioning, the magnetic sensor is arranged in the backside of the table opposite to the socket. This arrangement may not accurately detect a magnetic field affecting a magnetic sensor installed in the socket. That is, this technology may suffer from low inspection accuracy.

CITATION LIST

Patent Literature

SUMMARY OF THE INVENTION

It is an object of the present invention to provide an inspection apparatus and an inspection method, which are able to collectively inspect a wafer-like array of magnetic sensors with high accuracy.

The present invention relates to a magnetic sensor inspection apparatus including a stage for mounting a wafer-like array of magnetic sensors thereon, which is movable in a horizontal direction and a vertical direction; a probe card which is positioned opposite to the stage and which is equipped with a plurality of probes that are brought into contact with the magnetic sensors encompassed in the measurement area; a plurality of magnetic field generating coils which are positioned to surround the probe card and the stage so as to generate a magnetic field toward the magnetic sensors mounted on the stage; a plurality of magnetic field environment measuring sensors which are disposed in a peripheral portion of the probe card surrounding the probes; and a magnetic field controller for controlling magnetic fields generated by the magnetic field generating coils based on the measurement result of the magnetic field environment measuring sensors.

The present invention relates to a magnetic sensor inspection method using the magnetic sensor inspection apparatus including a stage, a probe card having a plurality of probes, a plurality of magnetic field generating coils surrounding the stage and the probe card, and a plurality of magnetic field environment measuring sensors disposed in the peripheral portion of the probe card surrounding the probes. Specifically, the magnetic sensor inspection method includes the steps of: mounting a wafer-like array of magnetic sensors on the stage; moving the stage in a horizontal direction and/or a vertical direction so as to bring the probes in contact with the magnetic sensors on the stage; driving the magnetic field generating coils so as to generate a magnetic field toward the magnetic sensors on the stage; adjusting magnetic fields generated by the magnetic field generating coils by way of feedback control based on the measurement result of the magnetic field environment measuring sensors; and concurrently inspecting the magnetic sensors with the probe card.

The present invention is characterized by arranging the magnetic field generating coils not on the probe card but outside of the probe card, thus generating a magnetic field covering a relatively large space encompassing the probes and their periphery. Subsequently, the probes are collectively brought into contact with the magnetic sensors so that a magnetic field is exerted concurrently on the magnetic sensors on the stage. This makes it possible to concurrently inspect the magnetic sensors with the probe card. In the inspection routine, a magnetic field exerted in the measurement area of the probe card is measured with the magnetic field environment measuring sensors, the measurement result of which is fed back to the magnetic field generating coils, thus controlling the magnetic field generating coils to accurately generate a magnetic field with desired intensity and desired directivity in the measurement area. The stage is appropriately moved horizontally and vertically so that a wafer-like array of magnetic sensors is brought in contact with the probes. This makes it possible to consecutively inspect the magnetic sensors without interruption.

Additionally, the present invention is characterized by arranging the temperature environment measuring sensors in proximity to the magnetic field environment measuring sensors in the peripheral portion of the probe card, wherein the magnetic field controller corrects (or adjusts) the measurement result of the magnetic field environment measuring sensors based on the measurement result of the temperature environment measuring sensors, thus controlling magnetic fields generated by the magnetic field generating coils based on the corrected (or adjusted) measurement result. This is because the sensitivity of the magnetic field environment measuring sensors may fluctuate depending on the temperature which may be varied or changed due to the surrounding environment or the inspection routine. Thus, it is necessary to correct (or adjust) the measurement result of the magnetic field environment measuring sensors based on the currently detected temperature in the measurement field. This realizes accurate magnetic testing (or accurate magnetic inspection) without being influenced by the surrounding temperature or the temperature-related condition.

Moreover, it is possible to install a temperature adjuster which is able to adjust the stage temperature at a desired temperature. This makes it possible to easily inspect variations of magnetic property at different temperatures. In this connection, it is possible to feed back the stage temperature to the magnetic field controller in addition to the measurement result of the temperature environment measuring sensors.

As described above, the present invention is designed to concurrently inspect a wafer-like array of magnetic sensors instead of individual pieces of magnetic sensors which are separated from each other, wherein a magnetic field is applied to the magnetic sensors collectively so as to concurrently inspect magnetic properties of magnetic sensors. Additionally, a magnetic field currently exerted in the measurement area is measured with the magnetic field environment measuring sensors, installed in the probe card, and fed back to the magnetic field controller, which in turn controls the magnetic field generating coils to accurately generate a desired magnetic field with desired intensity and desired directivity. Thus, it is possible to improve inspection accuracy when inspecting magnetic properties of magnetic sensors.

DESCRIPTION OF THE PREFERRED EMBODIMENT

The present invention will be described in further detail by way of examples with reference to the accompanying drawings.

FIG. 1is a perspective view of a magnetic sensor inspection apparatus1according to a preferred embodiment of the present invention. The entire structure of the magnetic sensor inspection apparatus1is defined using a frame2equipped with which six magnetic field generating coils3to8and a single probe card9. The frame2is equipped with a movable stage12for mounting a sensor aggregation11which is a wafer-like array of magnetic sensors10.

The magnetic field generating coils3to8are subdivided into plural pairs of coils, in which two coils are paired and arranged opposite to each other in an axial direction. The magnetic field generating coils3,4are paired and attached to the left and right sides of the frame2; the magnetic field generating coils5,6are paired and attached to the front and rear sides of the frame2; the magnetic field generating coils7,8are paired and attached to the upper and lower sides of the frame2. That is, three pairs of the magnetic field generating coils3to8are arranged in different axial directions perpendicularly crossing each other. The entire shape of the magnetic sensor inspection apparatus1is defined as a cube shape with the frame2.

Specifically, a pair of the magnetic field generating coils3,4is aligned in an X-axis direction (or a horizontal direction between the left and right sides of the frame2); a pair of the magnetic field generating coils5,6is aligned in a Y-axis direction (or a front-rear direction between the front and rear sides of the frame2) perpendicular to the X-axis direction; and a pair of the magnetic field generating coils7,8is aligned in a Z-axis direction (or a vertical direction between the upper and lower sides of the frame2) perpendicular to the X-axis direction and the Y-axis direction.FIG. 1shows X-axis, Y-axis, and Z-axis directions using dashed lines. The three pairs of the magnetic field generating coils3to8generate their magnetic fields in three axial directions consisting of the X-axis, Y-axis, and Z-axis directions, so that a three-axial composite magnetic field is applied to a center position C at which the axial directions of the magnetic field generating coils3to8are crossing each other.

The probe card9is fixed at the center position C in the space of the frame2surrounded by the magnetic field generating coils3to8. For the sake of simplifying illustration,FIG. 1does not show the fixing structure of the probe card9.

FIG. 2is a block diagram of the magnetic sensor inspection apparatus1. FIG.3is a plan view illustrating the positional relationship between the probe card (PROBE)9and the stage12in the magnetic sensor inspection apparatus1.FIG. 4is a front view of the probe card9.FIG. 5is a cross-sectional view of the magnetic sensor inspection apparatus1ofFIG. 1.

As shown inFIG. 5, the probe card9has a printed-wiring substrate9awhich is fixed in a horizontal direction and which is equipped with a plurality of probes13on the backside thereof. These probes13are able to concurrently come in contact with the predetermined number of magnetic sensors10, which are arranged in a square-shaped measurement area F (seeFIG. 3) in plan view, among numerous magnetic sensors10which are included in the sensor aggregation11and aligned on a wafer. The probes13project downwardly from the printed-wiring substrate9a. InFIGS. 3 to 5, a set of probes (or needles) which should be concurrently brought into contact with a single magnetic sensor10is specified using the same reference sign “13”; hence, a single probe card9includes a probe aggregation including a plurality of probes13. For example, a single probe card9having a rectangular shape with a length of 10 cm for each side is equipped with twenty-five sets of probes13which can be concurrently brought into contact with twenty-five magnetic sensors10(i.e. 5×5 magnetic sensors arranged in a matrix form consisting of five rows of magnetic sensors and five columns of magnetic sensors) so as to concurrently inspect those magnetic sensors10.

As shown inFIGS. 1 and 3, the probe9is fixed to the frame2such that the intermediate positions along four sides of a probe aggregation including a plurality of probes13(i.e. the intermediate position of five rows and the intermediate position of five columns) match the X-axis and the Y-axis of the magnetic field generating coils3to8. In other words, the center position C (at which the axial directions of the magnetic field generating coils3to8are crossing each other) matches the center of a matrix consisting of three sets of probes13(i.e. the center of a matrix, i.e. third row, third column). Additionally, a plurality of magnetic field environment measuring sensors (MAG FLD)14to17and a plurality of temperature environment measuring sensors (TEMP)18to21are correspondingly paired and arranged in the peripheral portion of the probe card9externally of a probe aggregation including a plurality of probes13.

The magnetic field environment measuring sensors14to17are each configured of three sensor chips, using magnetoresistive elements, with three-axial sensitivities in X-axis, Y-axis, and Z-axis directions; hence, they are each defined as a sensor with three-axial sensitivities in three axial directions perpendicular to each other at 90 degrees. The magnetic field environment measuring sensors14to17are sequentially electrified so as to measure a magnetic field in each axial direction.

The magnetic field environment measuring sensors14to17are disposed at intermediate positions on four sides of a square area, including a plurality of probes13, in the peripheral portion of the probe card9. That is, a pair of the magnetic field environment measuring sensors14,15which are disposed at intermediate positions on the opposite sides is aligned in conformity with a pair of the magnetic field generating coils3,4generating a magnetic field in the X-axis direction, whilst a pair of the magnetic field environment measuring sensors16,17which are disposed at intermediate positions on the other opposite sides is aligned in conformity with a pair of the magnetic field generating coils5,6generating a magnetic field in the Y-axis direction. As shown inFIGS. 3 and 4, a pair of the magnetic field environment measuring sensors14,15is positioned oppositely in the X-axis direction, whilst a pair of the magnetic field environment measuring sensors16,17is positioned oppositely in the Y-axis direction. The temperature environment measuring sensors18to21are positioned in proximity to the magnetic field environment measuring sensors14to17.

The stage12is positioned under the probe card9having the probes13, wherein the sensor aggregation11including a plurality of magnetic sensors10aligned on a wafer is mounted on the upper surface of the stage12. The magnetic sensors10are produced on the surface of a wafer according to semiconductor processing and adhered together using dicing tapes, wherein the magnetic sensors10are divided into individual chips on dicing tapes and aligned in a matrix formed on dicing tapes, and wherein they are tightly held together by means of a carrier instrument (not shown) for each dicing tape. The sensor aggregation11including a plurality of magnetic sensors10tightly held together by means of a carrier instrument is mounted on the stage12and is fixed at the predetermined position by way of vacuum absorption. Additionally, the magnetic sensor inspection apparatus1is equipped with a transport part (not shown) which is able to move the stage12in the X-axis, Y-axis, and Z-axis directions.

As shown inFIG. 2, the magnetic field generating coils3to8are connected to a magnetic field controller (MAG FLD CONTROLLER)25equipped with a driver power source (not shown). The magnetic field controller25controls currents or voltages applied to magnetic field generating coils3to8, thus controlling their magnetic fields. The probe card9is connected to a test controller26that sequentially electrifies the probes13according to the preprogrammed testing procedure so as to check the detection properties of the magnetic sensors10based on their output signals. The test controller26sends an instruction, regarding the magnitude and the directivity of a magnetic field, to the magnetic field controller25. Based on the instruction of the test controller26, the magnetic field controller25applies drive voltages to the magnetic field generating coils3to8. Based on the measurement result of the magnetic field environment measuring sensors14to17, the magnetic field controller25performs feedback control on drive voltages applied to the magnetic field generating coils3to8. Based on the measurement result of the temperature environment measuring sensors18to21which are installed in the probe card9in proximity to the magnetic field environment measuring sensors14to17, the magnetic field controller25corrects the measurement result of the magnetic field environment measuring sensors14to17, which may fluctuate depending on the surrounding temperature, so as to control the magnetic intensity of the magnetic field generating coils3to8based on the corrected measurement result of the magnetic field environment measuring sensors14to17.

The transport part of the stage12is connected to a stage controller27which controls the movement of the stage12in the X-axis, Y-axis, and Z-axis directions. As shown inFIG. 4, a heating medium circulation tube (HTG MED)28is embedded inside the stage12. A temperature controller (TEMP CONTROLLER)29controls the temperature of a heating medium circulating through the heating medium circulation tube28, thus heating the surface of the stage12at a desired temperature. In response to an instruction from the test controller26, the temperature controller29controls the stage12at a desired temperature. The temperature controller29is subjected to feedback control based on either the detection result of a stage temperature sensor30embedded in the stage12or the detection results of the temperature environment measuring sensors18to21installed in the probe card9.

InFIG. 1, a control box31encapsulates the magnetic field controller25, the test controller26, the stage controller27, and the temperature controller29therein. Non-magnetic materials are selectively used for the constituent elements of the magnetic sensor inspection apparatus1so as not to influence the output signals of the magnetic sensors10undergoing a magnetic field. For example, the probes13are composed of phosphor bronze exhibiting spring property. The frame2, the stage12, and the carrier instrument are composed of titanium (Ti).

Next, a magnetic sensor inspection method for inspecting the magnetic properties of the magnetic sensors10with the magnetic sensor inspection apparatus1will be described.

A plurality of magnetic sensors10is formed on a wafer and already subjected to dicing on a dicing tape, which is tightly held by a carrier instrument. In this state, the magnetic sensors10are divided into individual pieces which are separated from each other and aligned in a matrix on a dicing tape, thus forming the sensor aggregation11. In other words, the sensor aggregation11is a wafer-like array of magnetic sensors10.

An inspection procedure for inspecting the magnetic property of each individual magnetic sensor10is carried out with respect to the sensor aggregation11(which is a wafer-like array of magnetic sensors10) by way of the following steps (1) through (6), which will be described with reference to a flowchart ofFIG. 6.

(1) The sensor aggregation11(which is a wafer-like array of magnetic sensors) is fixed onto the surface of the stage12by way of vacuum absorption (step S1). The temperature controller29controls a heating medium to circulate through the heating medium circulation tube28such that the surface temperature of the stage12is set to a predetermined temperature Ta (e.g. a high temperature) (steps S2, S3). The temperature controller29changes the temperature of a heating medium based on the temperature of the stage12which is detected with the stage temperature sensor30, thus controlling the surface temperature of the stage12to match the predetermined temperature Ta.
(2) The transport part of the magnetic sensor inspection apparatus1moves the stage12so as to locate the probes13of the probe card9opposite to the magnetic sensors10concurrently subjected to inspection (step S4). Specifically, the probes13are positioned to oppositely face the twenty-five magnetic sensors10(i.e. the magnetic sensors10aligned in a matrix consisting of five rows and five columns). Subsequently, the transport part raises the stage12upwardly so that the probes13are brought into contact with the magnetic sensors10(step S5).
(3) Next, a magnetic test is conducted on the sensor aggregation11which is a wafer-like array of magnetic sensors10(step S6). Upon receiving an instruction from the test controller26, the magnetic field controller25drives the magnetic field generating coils3to8so as to generate a desired magnetic field (i.e. a composite magnetic field in the X-axis, Y-axis, and Z-axis directions) inside the measurement area F (covering the specific magnetic sensors10in the sensor aggregation11). At this time, the measurement result of the magnetic field environment measuring sensors14to17(which are disposed in the peripheral portion of the probe card9externally of the probes13) are fed back to the magnetic field controller25. The magnetic field controller25compares the measurement result of the magnetic field environment measuring sensors14to17to the preset values included in an instruction from the test controller26, thus appropriately driving the magnetic field generating coils3to8. Additionally, the temperature environment measuring sensors18to21(which are juxtaposed with the magnetic field environment measuring sensors14to17in the peripheral portion of the probe card9) measure a temperature currently occurring in the probes13in contact with the magnetic sensors10. Based on the measurement result of the temperature environment measuring sensors18to21, the magnetic field controller25corrects sensitivity variation of the magnetic field environment measuring sensors14to17depending on the surrounding temperature, thus appropriately controlling drive voltages applied to the magnetic field generating coils3to8based on the corrected measurement result. That is, the magnetic sensor inspection apparatus1checks whether or not the magnetic intensity of a magnetic field currently applied to the measurement area F matches with a specified magnetic intensity before conducting a magnetic test. If the current magnetic intensity does not match with the specified magnetic intensity, the magnetic field controller25adjusts currents or voltages applied to the magnetic field generating coils3to8, thus controlling their magnetic fields.
(4) Upon confirming the predetermined situation where a magnetic field having a specified magnetic intensity occurs in the measurement area F at the predetermined temperature Ta, the test controller26electrifies the probes13so as to conduct a magnetic test on each of the magnetic sensors10encompassed inside the measurement area F.
(5) Upon completing a magnetic test on one block of magnetic sensors10(i.e. twenty-five magnetic sensors10aligned in a matrix consisting of five rows and five columns), the transport part moves the stage12downwardly so as to release the contacts established between the probes13and the magnetic sensors10.
(6) The transport part horizontally moves the stage12so as to locate the probes13oppositely to the next block of magnetic sensors10(step S7). Then, the foregoing operations (2) to (5) are repeatedly performed (step S8). By repeating a series of operations (2) to (5), the magnetic sensor inspection apparatus1repeatedly performs a magnetic test at the predetermined temperature Ta while moving the probes13to concurrently come in contact with the magnetic sensors10of each block, thus completing magnetic testing on a wafer-like array of magnetic sensors10(steps S7to S9).

After completing magnetic testing on a wafer-like array of magnetic sensors10at the predetermined temperature Ta, the temperature controller29changes the temperature of the stage12with another temperature Tb (e.g. a low temperature) (step S10). Then, the magnetic sensor repeats a series of operations (2) to (6) so as to conduct magnetic testing on a wafer-like array of magnetic sensors10at the temperature Tb (steps S11to S17corresponding to steps S3to S9). After completing magnetic testing at the temperature Tb, the magnetic sensor inspection apparatus1exits the flowchart ofFIG. 6, wherein the tested wafer (including the magnetic sensors10) is removed from the stage12(step S18).

The magnetic sensor inspection method is not necessarily limited in terms of the feedback control of a magnetic field described in the operation (3). However, it is possible to achieve the feedback control of a magnetic field as follows.

A magnetic field exerted on the measurement area F is a composite magnetic field appropriately combining magnetic fields generated with the magnetic field generating coils3to8in the X-axis, Y-axis, and Z-axis directions. The magnetic field environment measuring sensors14to17, each of which is able to measure a magnetic field in three axial directions, measure the composite magnetic field combining magnetic fields in axial directions. Among the four magnetic field environment measuring sensors14to17installed in the probe card9, the two magnetic field environment measuring sensors14,15aligned in the X-axis direction, produce X-axis measurement results, which are averaged to determine magnetic field intensity in the X-axis direction. Additionally, the two magnetic field environment measuring sensors16,17aligned in the Y-axis direction, produce Y-axis measurement results, which are averaged to determine magnetic field intensity in the Y-axis direction. Moreover, it is possible to determine magnetic field intensity in the Z-axis direction by averaging the measurement results of the four magnetic field environment measuring sensors14to17. The reason why the probe card9does not install magnetic field environment measuring sensors aligned in the Z-axis direction is (a) physical constraint and (b) difficulty of determining magnetic field intensity in the Z-axis direction which may be significantly varied in the plane of the stage12and among a plurality of chips subjected to measurement. The reason (a) is a prominent factor in which it is difficult to additionally arrange magnetic field environment measuring sensors in a small space between the probe card9and the stage12which sandwich a wafer subjected to magnetic testing. Considering this factor, however, the four magnetic field environment measuring sensors14to17, each configured of a three-axis sensor, are aligned on the probe card9in four directions. This makes it possible to virtually measure the Z-axis magnetic field intensity by averaging the measurement results of the four magnetic field environment measuring sensors13to17. The magnetic field controller25compares the measured magnetic field intensities of two or three axial directions with the desired values included in an instruction from the test controller26so as to determine variants, based on which the magnetic field controller25controls the magnetic field generating coils3to8so as to correct their magnetic fields.

The feedback control is performed every time the transport part of the magnetic sensor inspection apparatus1moves the stage12so as to bring the probes13in contact with the next block of magnetic sensors10.

It is presumed that a magnetic field may not greatly fluctuate due to the movement of the stage12because the constituent elements of the magnetic sensor inspection apparatus1are formed using non-magnetic materials. Due to the arrangement of a power source driving motors which may be separated from the measurement area F, however, it is necessary to perform feedback control in response to a magnetic field measured every time the stage12is moved from one place to another. At this time, it is necessary to correct the measurement result of the magnetic field environment measuring sensors14to17based on the measurement result of the temperature environment measuring sensors18to21, thus controlling drive signals supplied to the magnetic field generating coils3to8based on the corrected measurement result regarding a magnetic field.

It is possible to confirm the temperature of the stage12with either the stage temperature sensor30(embedded in the stage12) of the temperature environment measuring sensors18to21installed in the probe card9, wherein the temperature controller29controls a heating medium to circulate through the heating temperature circulation tube28in response to an instruction from the test controller26. Herein, a temperature adjuster for adjusting the temperature of the stage12is formed using a combination of the heating medium circulation tube28and the stage temperature sensor30or a combination of the temperature environment measuring sensors18to21and the temperature controller29.

As described above, the magnetic sensor inspection apparatus1is designed to inspect a wafer-like array of magnetic sensors10instead of individual pieces of magnetic sensors10, wherein it is possible to concurrently inspect a plurality of magnetic sensors10in a magnetic field concurrently exerted on these magnetic sensors10. This improves a handling scheme of magnetic sensors, thus improving productivity in manufacturing magnetic sensors precluding defective ones.

During the inspection procedure, the magnetic field environment measuring sensors14to17(installed in the probe card9) measure a magnetic field exerted on the measurement area F so as to feed it back to the magnetic field controller25. This helps accurately generate a desired magnetic field in the measurement area F, thus improving inspection accuracy. During the inspection procedure, the measurement result of the magnetic field environment measuring sensors14to17which may fluctuate depending on the surrounding temperature is corrected (or adjusted) based on the measurement result of the temperature environment measuring sensors18to21. This makes it possible to accurately control a magnetic field based on the corrected measurement result (regarding a magnetic field); hence, it is possible to conduct magnetic testing with high accuracy.

As described heretofore, the present invention is not necessarily limited to the present embodiment, which can be further modified within the scope of the invention as defined in the appended claims.

For example, the present embodiment arranges the four magnetic field environment measuring sensors14to17surrounding the measurement area F; but this is not a restriction. It is possible to arrange a single magnetic field environment measuring sensor, two or more magnetic field environment measuring sensors. The present embodiment employs three-axis sensors, but it is possible to employ combinations of two-axis sensors and one-axis sensors.FIG. 5shows the probes13which perpendicularly project from the probe9, but it is possible to incline the probes13which thus project with slanted angles from the probe9. The present embodiment is designed to concurrently inspect a plurality of magnetic sensors10adhered to a dicing tape, but it is possible to inspect a wafer which is not subjected to dicing so that the magnetic sensors10are not adhered to a dicing tape.