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Inductive and AMR Head

Inductive and AMR Head. T. Stobiecki. The writting process. The magnetoresistive head depend on the written magnetization. In order to obtain the maximum output voltage , it must match properly the written magnetization transmission in the recording medium. Write head field.

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Inductive and AMR Head

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  1. Inductive and AMR Head T. Stobiecki

  2. The writting process The magnetoresistive head depend on the written magnetization. In order to obtain the maximum output voltage, it must match properly the written magnetization transmission in the recording medium.

  3. Write head field Ferrite heads the core is usually made of NiZn or MnZn. Insulators can be operated at frequency > 10MHz Thin film heads yoke (core): permalloy (81Ni19Fe) or aluminium - iron - silicon - alloy (AlFeSi) typically 2- to 4 µm thicknesses.

  4. Write head field (2.1) In high-density recording, the deep gap field required is: (2.2) where HCis the coercivity of the recording medium where BS is the saturation flux density of the pole of yoke material (2.3)

  5. Plots of the horizontal component Hx vs. distance x (2.4) Note that the trajectory closer to the head (A-B) has both a higher maximum field and higher field gradient dHx/dx.

  6. Written magnetization transition When the written current is held constant, the magnetization written in the recording medium is at one of the remanent levels MR. When the write current is suddenly changed from one polarity to the other, the written magnetization undergoes a transition from one polarity of remanent magnetization to the other. (2.5) where f is so called transition slopeparameter. As f is reduced, the transition becomes steeper. The binary ideal step function is for f=0.

  7. Bit size

  8. Written magnetization transition The write current is adjusted so that horizontal component of Hx on the midplane of the recording meets a specific criterion. This criterion, is that the horizontal position, where the field Hx=Hc, must coincidence with the position where the head field gradient, dHx/dx, is greatest. Meeting this criterion sets both the magnitude of the write current Iwand the x position of the center of the magnetization transition: The maximum head field gradient: (2.6)

  9. Written magnetization transition Note that because the magnetization increases through transition, the pole density is negative (south polarity). The maximum (slope) gradient of the demagnetizing field is: (2.7) The maximum gradient occurs at the center (M=0) of the transition. The smaller the value of the slope parameter f , the higher the magnitude of the demagnetizing field and its gradient. For digital write process, the slope equation is used: For a square loop recording medium, dM/dH is very high, and a convinient approximation is to set the maximum head field gradient equal to the maximum demagnetizing field gradient. Upon setting Eqs.(2.6) and (2.7) equal, the results is (2.8) (2.9) Plots of magnetization, „charge”density and demagnetizing field

  10. Written magnetization transition The writting problem is now completly solved because f is but the single parameter required to define fully the magnetization transition of equation: Possible ways to reduce the transition width, by reducing f, are to use higher coercivities, lower remanences, smaller flying heights, and thinner media. With the exception of lowering the remanence, all have been exploited in the past. When inductive reading heads are used, reducing the remanent magnetization is not an acceptable strategy, however, because it always reduces the signal and signal-noise ratio of the recorder. Equation for transition slope parameter f is also used in the simplified desogn of the shielded magnetoresistive head.

  11. Recording medium, fringing fields The written magnetization waveform is indicated as dashed line . The magnetic field and flux fringes equally above and below the medium, flowing from the north to the south poles. Suppose the written magnetization waveform: Where MR is the maximum amplitude of recording medium magnetization and k is the wavenumber (k=2/), where  is the sinusoidal wavelnegth. The horizontal and vertical components of fringing field at point (x,y) below the medium are: (3.1) (3.2a) (3.2b)

  12. Read-head flux The reading head has the same structure as that writing head and the poles have high magnetic permability (=dB/dH), most of the fringing flux flows deep in the head passing through coil. Very little flux flows through the air gap. The ratio of the flux passing through the coil to the flux entring the top surface of the head is called the read-head efficiency. In inductive heads the effciency 80%. The reading flux: where d is the head-to-medium spacing, g is the gap length, and W is the track width. (3.3)

  13. Output voltage The time rate of change of the flux, N, ina head coil with N turns is proportional to the read-head’s output voltage, E. whereV is the head-to-medium relative velocity. On putting Eq.(3.3) into Eq. (3.4), the result is: Note that the output voltage is proportional to the number of coil turns N, the head-to-medium velocity V, and the written remanency MR.. The term in parentheses in Eq. (3.5) is called the thickness loss and it shows that the read head is unable to sense the magnetization patterns written deep int the medium. The exponential term e-kdis called the spacing loss an it is often quoted as –55d/ dB. The factor sinkg/2/(kg/2) is called the gap loss. At the first gap null, at wavelength =g, the gap loss term is equal zero. The fact that the output voltage waveform is a cosine when a sine wave is written shows that the phase of the output signal is lagging 90o behind the written magnetization. (3.4) (3.5)

  14. Output spectrum When the reading head passes over a written magnetization transition, the coil flux,(x), and output voltage E(x). The peak amplitude of the output voltage as a function of frequency is called the spectrum. The temporal frequency f=V/ and the angular frequency =2f . The spatial frequency or wave number k= 2/ = /V, so that =Vk. The spatial frequency spectrum corresponding to Eq.(3.5) is just A(k)=E(x)/coskx. Note that it has zeros at both dc and the first gap null = g.

  15. AMR- Anisotropic magnetoreistance effect AMR effect can be described as a change of resistance in respect to the angle between sensing current and magnetization M. (4.1)

  16. Magnetoresistive sensor (4.2) (4.3) The value of demagnetizing field, avereged over the element depth, is proportionat to ratio width to length (T/D).

  17. Magnetoresistance vs. disk field The vertical field is not sufficient to saturate MR-element, that is, My<Msat at the middepth y=D/2, an exact analytical solution for the magnetization angle  as a function of element depth is: (4.4) For MR-element HK<<yHD.

  18. The work point of MR output signal The slope of this approximated characteristic is equal to –R/2yHbiasand it represents the sensitivity of the MR-element when vertical bias field is used. When the proper vertical bias field is used, the output voltage, IR, is large and linear. Typically, deviations from linearity cause about – 20dB of even harmonic distortion, which is stisfactory for a binary or digital channel, is not sufficiently linear for an analog signal channel. If vertical biasing is not used, the response is of low sensitivity and is highly nonlinear.

  19. AMR - head

  20. Write-read head

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