M. Togashi scite author profile

Pulse pattern generators (PPG) and bit error rate testers (BERT) are widely used in evaluating communications systems. Systems for telecommunications and data communications require various data rates ranging from 9.95 to 12.5Gb/s for testers, depending on encoding methods. For instance the 10 Gigabit small form factor pluggable module (XFP) specifications require 11.1Gb/s data rate with 0.45UIpp non-data-dependent jitter tolerance. This paper describes a CMOS LSI integrating PPG and BERT functions ( Fig. 9.5.1). A parallel CDR circuit allows the LSI to operate at a rate as high as 12.5Gb/s. It also provides wide jitter tolerance for high-frequency (4-80MHz) sinusoidal jitter.A CDR using linear phase detector (PD) [1] has many merits, including a jitter-transfer bandwidth independent of input-jitter amplitude, stable capture range, and quick loop design using classical control theory. However, a linear PD requires highspeed gates for up-pulse generation. The up-pulse width is reduced from T/2 (where T is the unit interval of input data) proportional to the phase error between data and clock. This limits the maximum operation rate of the CDR. The half-rate clock scheme [2] itself does not solve this problem. To extend up-pulse width, we use a parallel phase detector (P-PD) and two chargepump (CP) circuits in a double-loop architecture CDR ( Fig. 9.5.2). The P-PD separately compares the phase error between the odd-number data-transition edge and half-rate-clock rising edge, and the phase error between the even-number data-transition edge and half-rate-clock falling edge. The two CP outputs are commonly connected to a low-pass filter for detection of the whole data transition so as to eliminate the data-pattern dependency.The P-PD is shown in Fig. 9.5.3. It compares odd-and evennumber-data edge and half-rate clock edge in parallel. Latch-2 passes through the odd-number data-transition edge and outputs even-number data with the rising edge of a half-rate clock. Latch-3 outputs even-number data using the half-rate-clock rising edge. Thus, the pulse width of the Exor_1 output (Up_1) is the time between the odd-number data-transition edge and halfrate-clock rising edge. The Up_2 pulse is made in the same manner from the even-number data-transition edge and half-rateclock falling edge. As a result, the width of the up-pulse output from this P-PD is 1.25T ± T/2, which is longer than the conventional up-pulse width of T/2 ± T/2, where T is a unit interval of data and ±T/2 is the variation of the time between the data-transition edge and clock-transition edge due to input data jitter.An XOR gate made with low-f T transistors eliminates the narrow up-pulse due to the slow rise/fall time; however, when the pulse is wide, it can accurately output the width difference of the uppulse. Therefore the parallel phase detector has a wide linear response to large phase error. As shown in Fig. 9.5.4, a backannotated simulation at 11.1Gb/s indicates that the P-PD improves the linear response range to phase error from 0.33 to 0.56UI, su...

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A novel high-speed latching operation flip-flop (HLO-FF) circuit and its application to a 19-Gb/s decision circuit using a 0.2-μm GaAs MESFET

Murata

Otsuji

Sano

et al. 1995

IEEE J. Solid-State Circuits

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M. Togashi

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A novel high-speed latching operation flip-flop (HLO-FF) circuit and its application to a 19-Gb/s decision circuit using a 0.2-μm GaAs MESFET

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