In rotary-stage e-beam writer systems, an encoder is used to generate a clock for angular-position reference of the rotary stage. Patterns are recorded synchronously to the encoder clock. The eccentricity of the encoder or uneven marks of the encoder result in a frequency-shift of the encoder clock, causing the recorded pattern to have frequency-shifts.
In a following description, reference is made to the accompanying drawings, which form a part hereof, and in which is shown by way of illustration a specific example in which the invention may be practiced. It is to be understood that other embodiments may be utilized and structural changes may be made without departing from the scope of the present invention.
General Overview:
It should be noted that the descriptions that follow, for example, in terms of a method for encoder frequency-shift compensation is described for illustrative purposes and the underlying system can apply to any number and multiple types of patterned or discrete track stack or media systems. In one embodiment, the method for encoder frequency-shift compensation can be configured using a phase control system which can be a phase locked loop counter to learn the repeatable frequency-shifts. The method for encoder frequency-shift compensation can be configured to generate a frequency-shift compensated clock for use in e-beam writer systems and can be configured to generate a frequency-shift compensated clock for use in any rotary staged system.
In one embodiment the repeatable frequency-shifts 120 are learned in a phase locked loop 130. The phase locked loop generates an output signal that is related to the phase of the input signal from the encoder. The values of the repeatable frequency-shifts 120 such as the phase are processed in a synthesizer 140. The synthesizer 140 produces a signal that is broken down into the values of the repeatable frequency-shifts 120 such as the phase and frequency. The method for encoder frequency-shift compensation continues to analyze the values of the repeatable frequency-shifts 120 such as the phase and frequency.
The values of the repeatable frequency-shifts 120 learned in a phase locked loop 130 analyzed are used to compensate for the encoder eccentricity or uneven marks 110 and generate a frequency-shift compensated clock 150. The frequency-shift compensated clock signals are then used to track the rotary position of the rotary-stage e-beam writer systems 100. The increased accuracy created by the method for encoder frequency-shift compensation increases the quality of patterned or discrete track stack or media systems used for example to pattern a stack.
Detailed Description:
Phase Locked Loop:
The repeatable frequency-shifts 120 are detectable using a phase locked loop 220. The values of the repeatable frequency-shifts 120 such as phase can be learned in a phase locked loop 130 of
Synthesizer:
The values detected in the phase locked loop 220 are transmitted to a synthesizer 140. The value from the encoder index 210 of each encoder clock signals 215 is transmitted to the same synthesizer 140. The synthesizer 140 includes a voltage controlled oscillator 230. The frequency-shift elements include frequency information. The frequency information includes for example the phase difference between the encoder index 210 encoder clock signals 215 and the phase detected in the phase locked loop 220. The frequency-shift elements are valued using the feedback signal of the voltage controlled oscillator 230.
The values of the frequency-shifts are analyzed to provide the data needed to compensate for the frequency-shifts to generate a frequency-shift compensated clock 150. The frequency-shifts compensation processes are described in detail in
Frequency-Shift Compensation Process:
Feedforward Filter:
The feedforward filter 250 creates an output of the direct and delay-line signal processing elements. The feedforward filter 250 output signals pass through a feedforward gain adjust 252. The gain is the mean ratio of the signal output of a system to the signal input of the same system. The feedforward gain adjust 252 is used to increase the power or amplitude of the feedforward filter output signals. This allows analysis of the feedforward filter 250 output signals such as delay-line interpolation. The gain adjusted feedforward filter output signals are entered into sum (Σ1) 256. Sum (Σ1) 256 include other signal processing elements from the frequency-shift compensation process 240.
Frequency Phase Recovery:
The frequency-shift compensation process 240 enters into sum (Σ3) 242 the frequencies from the synthesizer 140 of
Phase Angle Compensator:
The sum (Σ2) 262 including the reference setpoint 260 zero angular degrees and the recovered phase angular degrees is processed through a compensator 274. The compensator 274 is used to adjust frequency response. The compensator 274 frequency response adjustment includes for example phase lag.
The compensator 274 frequency response adjustments are added to the gain adjusted feedforward filter output signals in sum (Σ1) 256. The total of sum (Σ1) 256 for a number of encoder clock signals 215 of
The moving average 290 frequency results form a frequency-shift compensated clock 299. The method for encoder frequency-shift compensation produces a frequency-shift compensated clock 299 for use in patterned or discrete track stack or media systems to accurately pattern for example a high quality bit patterned or discrete track stack or media.
Encoder Frequency-Shifted Clock Signal:
Compensated Clock Signal:
Encoder Frequency-Shift Compensation Apparatus:
The method for encoder frequency-shift compensation is used to compensate for the frequency-shifts of a rotary encoder in a system. The method for encoder frequency-shift compensation in one embodiment can be components performing each function or operation in a separate device and connected by hardwire or a printed circuit board. In one embodiment one or more of the component devices are configured as analog devices or digital devices or a combination of both.
Phase Locked Loop Counter:
A phase locked loop tries to generate an output signal whose phase is related to the phase of the input “reference” signal. The phase locked loop counter 220 includes a variable frequency oscillator and a phase detector. The phase locked loop counter 220 compares the phase of the input signal from the encoder 200 with the phase of the signal derived from its output oscillator and adjusts the frequency of its oscillator to keep the phases matched. The signal from the phase detector is used to control the oscillator in a feedback loop. The information derived from the operations of the phase locked loop counter 220 provides the basis for learning the frequency-shifts of the encoder 200 encoder clock signals 215.
The direct signal from the encoder 200 pin 1 is connected to the phase locked loop counter 220 pin 1. The phase locked loop counter 220 counts the number of encoder index 210 timed encoder readings represented as N. The phase locked loop counter 220 outputs the number signal from pin 5 to the synthesizer 140 pin 1. The phase locked loop counter 220 detects the phase of the encoder frequency-shift signal. The phase detected is transmitted from phase locked loop counter 220 pin 6 to the synthesizer 140 pin 8.
Synthesizer:
The synthesizer 140 integrated circuit routes the phase detected from pin 8 to the voltage controlled oscillator 230 digital device VCO. The encoder index 210 encoder clock signals 215 is transmitted from the encoder 200 pin 3 to the synthesizer 140 pin 7. The index timed encoder reading signal from pin 7 is inputted to the voltage controlled oscillator 230 digital device VCO. The synthesizer 140 and voltage controlled oscillator 230 identify the frequency, phase and amplitude of the frequency-shift encoder clock signals 215. The voltage controlled oscillator 230 outputs a frequency, phase and amplitude signal to pin 4. The voltage controlled oscillator 230 output signal from pin 4 is routed to both pin 10 and pin 12 of the frequency-shift compensation processor 400. The voltage controlled oscillator 230 output signal to pin 12 feeds to the feedforward filter 250 shown as a digital device #7. The synthesizer 140 transmits the number of encoder index 210 timed encoder readings represented as N in the number signal from pin 2 to pin 10 of the frequency-shift compensation processor 400.
Feedforward Filter:
The feedforward filter 250 separates the direct and delay-line signal processing elements. The feedforward filter 250 processes the signals using the feedforward gain adjust 252. The feedforward gain adjust 252 increases the gain or mean ratio of the signal output to the signal input from pin 12. The feedforward gain adjust 252 is used to increase the power or amplitude of the feedforward filter output signals. This allows analysis of the feedforward filter 250 output signals such as delay-line interpolation. The feedforward gain adjust 252 magnitude can be adjusted. A feedforward gain adjust factor input 420 connected to pin 11 allows for input to modify the gain adjustment factor. The gain adjusted feedforward filter output signals are entered into sum (Σ1) 256, a digital device, allowing analysis of the signals such as delay-line interpolation. The sum (Σ1) 256 includes other signal processing elements from the frequency-shift compensation processor 400.
Phase Recovery:
The voltage controlled oscillator 230 output signal that is routed to pin 9 of the frequency-shift compensation processor 400 inputs the frequency values to sum (Σ3) 242 digital device #3. The frequency 270 value from sum (Σ3) 242 is routed to a digital device #4 as a frequency 270 value (dΘ/dt). A digital device #5 recovers phase 272 value using 1/S, a time Integration of the frequency 270 received from digital device #4. Frequency is the derivative of phase and the phase recovery uses that relationship to recover the phase of the voltage controlled oscillator 230 output signal from the synthesizer 140. The phase value of the frequency 270 is entered into sum (Σ2) 262, a digital device.
The reference setpoint 260 can be set using input to pin 4. The reference setpoint 260 includes values such as zero degrees (0°) which are entered into sum (Σ2) 262. The difference between the phase angles of the reference setpoint 260 and the recovered phase value is used to determine the instantaneous phase error of the signal. The sum (Σ2) 262 is routed to the compensator 274 digital device #6.
Phase Angle Compensator:
The sum (Σ2) 262 includes the reference setpoint 260 zero angular degrees and the recovered phase angular degrees. The compensator 274 adjusts the frequency response. The frequency response adjustment includes for example phase lag. The compensator 274 frequency response adjustments are added to the gain adjusted feedforward filter 250 gain adjusted output signals in sum (Σ1) 256. The total for sum (Σ1) 256 for the number of encoder index 210 timed encoder readings is routed to the voltage controlled oscillator 258 digital device VCO.
Voltage Controlled Oscillator:
The voltage controlled oscillator 258 processes the total for sum (Σ1) 256. The oscillator generates an output signal. Voltage control can adjust the output signal. The compensated phase value is used to control the voltage. The compensated phase value may cause the frequency output signal of the voltage controlled oscillator 258 to increase or decrease relative to the reference encoder frequency-shift value. The compensated phase adjustments correct the errors caused by the frequency-shifts.
A feedback signal is generated using the voltage controlled oscillator 258. The feedback signal provides a value for the adjusted frequency elements. The values of the adjusted frequency element values of the voltage controlled oscillator 258 feedback signal are routed to sum (Σ3) 242, a digital device. The feedback signal values are added to the frequency element values from the synthesizer 140 previously entered into sum (Σ3) 242. The totals of the values in sum (Σ3) 242 are routed to the compensation index 280 digital device #8.
Compensation Index:
The compensation index 280 records the values from sum (Σ3) 242 as frequency-shift compensated values corresponding to the index timed encoder reading received through pin 10. The compensation index 280 forms an index of compensated timed frequency-shift encoder readings. The compensation index 280 routes the values of the compensated timed frequency-shift encoder readings to the moving average 290 digital device MA.
Moving Average:
The moving average 290 digital device MA computes a moving average 290. The moving average 290 includes the values of the compensated timed frequency-shift encoder readings from the compensation index 280. The moving average 290 using the formula (ΣYi(n)/N); where Yi is the ith measurement from the compensated timed frequency-shift encoder readings (n). The moving average 290 then divides the result by N the total number of index timed encoder readings.
The moving average 290 represents a frequency-shift compensated clock signal 360 compensating for the encoder frequency-shifts. The moving average 290 digital device MA outputs through pin 7 of the frequency-shift compensation processor 400 the frequency-shift compensated clock signal 360.
The method for encoder frequency-shift compensation using the encoder frequency-shift compensation apparatus does generate a frequency-shift compensated clock 150 of
The foregoing has described the principles, embodiments and modes of operation of the present invention. However, the invention should not be construed as being limited to the particular embodiments discussed. The above described embodiments should be regarded as illustrative rather than restrictive, and it should be appreciated that variations may be made in those embodiments by workers skilled in the art without departing from the scope of the present invention as defined by the following claims.
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Number | Date | Country | |
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20120274371 A1 | Nov 2012 | US |