Optimal design of a noncoherent second-order delay-locked loop using the exit-time criterion

Bernhard, U.P.; Welti, A.L.

doi:10.1109/icc.1993.397383

Cited by 10 publications

(8 citation statements)

References 11 publications

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“…It is therefore sufficient to maximize The dependence of E,oPt on yd occurs because G ( E ) depends on y& It is interesting to note that the optimal loop parameters are pure constants, independent of the others. This agrees with earlier results of other tracking loops, [3,28,29,31,32,33], and shows also the importance of the time scaling which led to such a specific loop description (10). Together with (9), (1 1) and (31) the optimum rescaled MTLL normalized by the bit time Tb turns out to be 60pt = 0.373, Knowing IuoPtI we can immediately deduce the relationship for the optimal loop bandwidth Bk, (1 1): (33) Hence, the optimal bandwidth must be chosen according to the processing gain and the velocity vo.…”

Section: Theoretical Resultssupporting

confidence: 92%

“…it is easy to show that the state equation of the first-or-Vol.5, No. 3 May-Jun. 1994 der MCTL can be related to the Langevin equation of motion which describes a specific second-order system.…”

Section: By Using the Smoluchowski -Kramers Approximationmentioning

confidence: 99%

“…Furthermore, it was also used to calculate the MTLL of the coherent second-and third-order DLL, [27,29,32]. In this paper, we extend the concepts and ideas of [3] and [32] to analyze the second-order MCTL. We calculate its MTLL under the constraint of a channel noise and a Doppler rate caused by an acceleration of the transmitter relative to the receiver.…”

Section: By Using the Smoluchowski -Kramers Approximationmentioning

confidence: 99%

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Mean time to lose lock of the first‐and second‐order modified code tracking loop used in spread spectrum systems

Welti¹,

Bernhard²

1994

Trans Emerging Tel Tech

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Pseudonoise (PN) code tracking loops are essential in various direct‐sequence spread‐spectrum (DSSS) systems for both, communication and navigation applications. This paper shows how to optimize the so‐called modified code tracking loop (MCTL) of first‐ and second‐order by using the mean time to lose lock (MTLL) as a performance criterion. The state equation of the first‐order MCTL is related to the Smoluchowski ‐ Kramers approximation of a second‐order system described by the Langevin equation of motion. For such a specific system, the MTLL is known by the work of Kramers. In case of the second‐order type II loop (having two perfect integrators), which cannot be described by the Langevin equation, the computation of the MTLL is based on the singular perturbation method. Optimal parameters maximizing the MTLL under the constraint of Doppler effects and the channel noise are derived for both type of loops, resulting in very simple expressions that can be used immediately for a practical loop design. Measurements performed for the first‐order MCTL verify the theoretical optimal loop parameters and indicate that the time to lose lock is exponentially distributed. Monte Carlo simulations confirm also very well the theoretical results in case of a second‐order loop and hence, show that the application of the singular perturbation method yields an excellent approximation of the MTLL.

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Section: Theoretical Resultssupporting

confidence: 92%

Section: By Using the Smoluchowski -Kramers Approximationmentioning

confidence: 99%

Section: By Using the Smoluchowski -Kramers Approximationmentioning

confidence: 99%

See 1 more Smart Citation

Mean time to lose lock of the first‐and second‐order modified code tracking loop used in spread spectrum systems

Welti¹,

Bernhard²

1994

Trans Emerging Tel Tech

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“…Threshold extension by optimal loop design was shown. This method can be extended to solve the second order loop case, similarly to [13,17,18] and can also be used for the modified DDLL [7] in DSSS systems over frequency selective fading channels.…”

Section: Discussionmentioning

confidence: 99%

“…The normalised equation is preferred since only in this equation one can properly compare the noise intensity with the restoring force. We will show below that in many (as a matter of fact almost all) practical cases, the noise intensity is small compared to the restoring force, even in the threshold region [13][14][15][16][17][18], thus allowing us to use the singular perturbation method in our analysis. For the Brownian motion wðtÞ, we have [12] ðdwðtÞÞ 2 $ dt, due to the quadratic variation of the Brownian motion.…”

Section: Mtll Calculationmentioning

confidence: 98%

Optimal design of an all-digital chip timing recovery loop for direct-sequence spread-spectrum systems

Hasson

Bobrovsky

2005

Eur. Trans. Telecomm.

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SUMMARYNoncoherent digital delay lock loops (DDLL) are suited for chip timing synchronisation in band-limited direct-sequence spread-spectrum (DSSS) demodulators. The diffusion approximation and the singular perturbation method are used in this paper to calculate the mean time to lose lock (MTLL) of the DDLL. Loop bandwidth optimisation for first order loop with severe Doppler is presented. A simple design rule for the loop bandwidth and a systematic approach for the loop threshold calculation are presented.

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Mean time to lose lock for the "Langevin"-type delay-locked loop

Welti

Bobrovsky

1994

IEEE Trans. Commun.

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Optimal design of a noncoherent second-order delay-locked loop using the exit-time criterion

Cited by 10 publications

References 11 publications

Mean time to lose lock of the first‐and second‐order modified code tracking loop used in spread spectrum systems

Mean time to lose lock of the first‐and second‐order modified code tracking loop used in spread spectrum systems

Optimal design of an all-digital chip timing recovery loop for direct-sequence spread-spectrum systems

Mean time to lose lock for the "Langevin"-type delay-locked loop

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