Abstract: A Magnetoresistive Random Access Memory (MRAM) device is tested using a high repetition test that detects one or more low-likelihood failures, such as a failure to properly switch between a high or low resistive state. A series of write and read operations are performed for a large number of test cycles at high frequency. A first tier measurement is used to determine if a switching failure occurred, e.g. by comparing the read signal to target level(s) after each operation. When a switching failure event is detected, a second tier measurement is used to measure and store switching performance parameters, for example, the value of the read signal, while the MRAM device is in a failure state. The high frequency testing may be paused during the second tier measurements. Additional performance parameters may be measured during the second tier measurements.

Abstract: A Magnetoresistive Random Access Memory (MRAM) device is tested using a high repetition test that detects one or more low-likelihood failures, such as a failure to properly switch between a high or low resistive state. A series of write and read operations are performed for a large number of test cycles at high frequency. A first tier measurement is used to determine if a switching failure occurred, e.g. by comparing the read signal to target level(s) after each operation. When a switching failure event is detected, a second tier measurement is used to measure and store switching performance parameters, for example, the value of the read signal, while the MRAM device is in a failure state. The high frequency testing may be paused during the second tier measurements. Additional performance parameters may be measured during the second tier measurements.

Abstract: A read head is tested by measuring the thermal magnetic fluctuation noise spectrum. A non-uniformity in the magnetic field of the free layer is produced and the thermal magnetic fluctuation noise spectrum is measured, with and/or without an external magnetic field applied. A peak in the thermal magnetic fluctuation noise spectrum can be used to derive the desired dimension of the free layer, such as track width and stripe height. The resulting measurement may then be fed back into the process control for the production of the read heads if desired. Additionally, the stiffness of the free layer and the strength of the reference layer may be determined using ferromagnetic resonance peaks in the thermal magnetic fluctuation noise spectrum.

Abstract: A tester for a testing a Hard Disk Drive (HDD) flex circuit prior to electrical installation of a Head Gimbal Assembly (HGA) includes a shorting block that makes electrical contact to the bondpads on the sample. The shorting block includes one or more electrical contacts that are electrically grounded and have a size and/or configuration to contact the bondpads as well as the surface of the sample around the bondpads to accommodate positioning tolerances of the sample under test, without need for optics, precise probes, or precision stages. The electrical contacts of the shorting block may be, e.g., a matrix of pogopins or a flexible electrically-conductive material. During testing, the bondpads are shorted together and to ground with the shorting block while it is determined whether Short failures are properly detected. While the shorting block is not engaged with the bondpads, it is determined whether open failures are properly detected.

Abstract: A property, such as a quality parameter, of a write pole in a write head is determined using an optical metrology device, where the write pole is smaller than the optical resolution limit of the metrology device. The metrology device produces polarized light that is reflected off the write pole while the write pole is magnetized either during or after excitation with a write current. The magnetization alters the polarization state of the light, which can be analyzed to transform the altered polarization state into intensity. The intensity of the light is detected over the point spread function of the optics in the metrology device and an intensity value is generated. The intensity value is used to determine the quality parameter of the write pole, e.g., by comparison to a threshold or reference intensity value, which may be generated empirically or theoretically.

Abstract: A property, such as a quality parameter, of a write pole in a write head is determined using an optical metrology device, where the write pole is smaller than the optical resolution limit of the metrology device. The metrology device produces polarized light that is reflected off the write pole while the write pole is magnetized either during or after excitation with a write current. The magnetization alters the polarization state of the light, which can be analyzed to transform the altered polarization state into intensity. The intensity of the light is detected over the point spread function of the optics in the metrology device and an intensity value is generated. The intensity value is used to determine the quality parameter of the write pole, e.g., by comparison to a threshold or reference intensity value, which may be generated empirically or theoretically.

Abstract: A tester for a testing a Hard Disk Drive (HDD) flex circuit prior to electrical installation of a Head Gimbal Assembly (HGA) includes a shorting block that makes electrical contact to the bondpads on the sample. The shorting block includes one or more electrical contacts that are electrically grounded and have a size and/or configuration to contact the bondpads as well as the surface of the sample around the bondpads to accommodate positioning tolerances of the sample under test, without need for optics, precise probes, or precision stages. The electrical contacts of the shorting block may be, e.g., a matrix of pogopins or a flexible electrically-conductive material. During testing, the bondpads are shorted together and to ground with the shorting block while it is determined whether Short failures are properly detected. While the shorting block is not engaged with the bondpads, it is determined whether open failures are properly detected.

Abstract: A magnetic recording head tester uses closed loop control to accurately control the magnetic field that is generated to test the magnetic recording head. The closed loop control compares the value of the sensed magnetic field to the desired value of the magnetic field and adjusts the magnetic field accordingly. A magnetic field sensor used in the tester may be located in a position that has a substantially different magnetic field magnitude than is experienced by the magnetic recording head. The value of the output signal from the magnetic field sensor is correlated to the magnitude of the magnetic field at the location of the magnetic recording head through calibration. The correlation can then be used to accurately produce the desired magnitude magnetic field at the location of the magnetic recording head.

Abstract: A read head is tested by measuring the thermal magnetic fluctuation noise spectrum. A non-uniformity in the magnetic field of the free layer is produced and the thermal magnetic fluctuation noise spectrum is measured, with and/or without an external magnetic field applied. A peak in the thermal magnetic fluctuation noise spectrum can be used to derive the desired dimension of the free layer, such as track width and stripe height. The resulting measurement may then be fed back into the process control for the production of the read heads if desired. Additionally, the stiffness of the free layer and the strength of the reference layer may be determined using ferromagnetic resonance peaks in the thermal magnetic fluctuation noise spectrum.

Abstract: A set of magnets, e.g., electromagnets, are used to produce an in-plane magnetic field with respect to an article under test or manufacture. The set of electromagnets includes electromagnets that are positioned above and below the plane of symmetry respectively. The bottom electromagnets may be positioned below the surface of the chuck for example. The plane of the article and/or set of electromagnets are positioned so that the plane of symmetry approximately coincides with the article. The set of electromagnets may include individual electromagnets or C-core electromagnets, which may produce magnetic fields with complementary polarities near the field of symmetry both above and below the field of symmetry. Magnetic fields with the same polarity are positioned near each other on opposite sides of the plane of symmetry to produce the in-plane magnetic field. A second set of electromagnets may be used to provide field rotation if desired.

Abstract: A set of magnets, e.g., electromagnets, are used to produce an in-plane magnetic field with respect to an article under test or manufacture. The set of electromagnets includes electromagnets that are positioned above and below the plane of symmetry respectively. The bottom electromagnets may be positioned below the surface of the chuck for example. The plane of the article and/or set of electromagnets are positioned so that the plane of symmetry approximately coincides with the article. The set of electromagnets may include individual electromagnets or C-core electromagnets, which may produce magnetic fields with complementary polarities near the field of symmetry both above and below the field of symmetry. Magnetic fields with the same polarity are positioned near each other on opposite sides of the plane of symmetry to produce the in-plane magnetic field. A second set of electromagnets may be used to provide field rotation if desired.

Abstract: A lifecycle analyzer includes a temperature control element for controlling the temperature of a plurality of magnetoresistive (MR) elements, which may be, e.g., in bar, slider, head gimbal assembly, or head stack assembly form. The MR elements are in electrical contact with a stress probe element for applying a bias voltage or current stress. The MR elements and/or a magnetic field generator are moved to place one or more MR elements within the magnetic field of the magnetic field generator for testing. During testing, the MR elements are in electrical contact with a test probe element. The temperature of the MR elements may be controlled during both the stressing and testing.

Abstract: A lifecycle analyzer includes a temperature control element for controlling the temperature of a plurality of magnetoresistive (MR) elements, which may be, e.g., in bar, slider, head gimbal assembly, or head stack assembly form. The MR elements are in electrical contact with a stress probe element for applying a bias voltage or current stress. The MR elements and/or a magnetic field generator are moved to place one or more MR elements within the magnetic field of the magnetic field generator for testing. During testing, the MR elements are in electrical contact with a test probe element. The temperature of the MR elements may be controlled during both the stressing and testing.

Abstract: A magnetic head that includes a magnetoresistive effect read head element is tested by applying a varying magnetic field and measuring the resulting output signals from the read head element. The output signals are digitized and a processor calculates, e.g., the root mean square (RMS) of the signals or performs a Fast Fourier Transform or Autocorrelation on the data to determine if there is noise present. If desired, write and delay events may be performed prior to digitizing the output signals from the read head element to determine if additional noise, which is introduced to the magnetoresistive head from the write element, is present. In one embodiment, the digitizer may be replaced with an RMS meter.

Abstract: A lifecycle analyzer includes a heating element for heating a plurality of magnetoresistive (MR) elements, which maybe, e.g., in bar form. At one location the MR elements are in contact with a stress probe card for applying a bias voltage or current stress. The MR elements are moved to a separate location, where there is a test probe card and magnetic field generator for testing the MR elements after being stressed. In one embodiment, a subset of the plurality of MR elements is tested at a time. The lifecycle analyzer includes an in-situ abrasive element that is used to abrade the probe pins of the stress probe card to remove oxidation that results from extended contact with the heated MR elements.

Abstract: A lifecycle analyzer includes a heating element for heating a plurality of magnetoresistive (MR) elements, which maybe, e.g., in bar form. At one location the MR elements are in contact with a stress probe card for applying a bias voltage or current stress. The MR elements are moved to a separate location, where there is a test probe card and magnetic field generator for testing the MR elements after being stressed. In one embodiment, a subset of the plurality of MR elements is tested at a time. The lifecycle analyzer includes an in-situ abrasive element that is used to abrade the probe pins of the stress probe card to remove oxidation that results from extended contact with the heated MR elements.

Abstract: A magnetic head that includes a magnetoresistive effect read head element is tested by applying a varying magnetic field and measuring the resulting output signals from the read head element. The output signals are digitized and a processor calculates, e.g., the root mean square (RMS) of the signals or performs a Fast Fourier Transform or Autocorrelation on the data to determine if there is noise present. If desired, write and delay events may be performed prior to digitizing the output signals from the read head element to determine if additional noise, which is introduced to the magnetoresistive head from the write element, is present. In one embodiment, the digitizer may be replaced with an RMS meter.