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| ZL30409 T1/E1 System Synchronizer with Stratum 3 Holdover Data Sheet Features * * * * Supports Telcordia GR-1244-CORE Stratum 4 timing for DS1 interfaces Supports ETSI ETS 300 011, TBR 4, TBR 12 and TBR 13 timing for E1 interfaces Selectable 19.44 MHz, 2.048 MHz, 1.544 MHz or 8 kHz input reference signals Provides C1.5, C2, C4, C6, C8, C16, and C19 (STS-3/OC3 clock divided by 8) output clock signals Provides 5 styles of 8 KHz framing pulses Holdover frequency accuracy of 0.05 PPM Holdover indication Attenuates wander from 1.9 Hz Fast lock mode Provides Time Interval Error (TIE) correction Accepts reference inputs from two independent sources JTAG Boundary Scan Ordering Information ZL30409/DDE ZL30409/DDF ZL30409DDE1 ZL30409DDF1 48 48 48 48 Tubes Tape & Reel Tubes, Bake & Drypack Tape & Reel, Bake & Drypack *Pb Free Matte Tin -40C to +85C Pin Pin Pin Pin SSOP SSOP SSOP* SSOP* April 2006 Applications * * Synchronization and timing control for multitrunk T1,E1 and STS-3/OC3 systems ST-BUS clock and frame pulse sources * * * * * * * * Description The ZL30409 T1/E1 System Synchronizer contains a digital phase-locked loop (DPLL), which provides timing and synchronization signals for multitrunk T1 and E1 primary rate transmission links. The ZL30409 generates ST-BUS clock and framing signals that are phase locked to either a 19.44 MHz, 2.048 MHz, 1.544 MHz, or 8 kHz input reference. OSCi OSCo TCLR LOCK VDD GND Master Clock TCK TDI TMS TRST TDO PRI SEC IEEE 1149.1a TIE Corrector Circuit Selected Reference Virtual Reference DPLL Output Interface Circuit Reference Select MUX Reference Select TIE Corrector Enable State Select State Select Input Impairment Monitor C19o C1.5o C2o C4o C6o C8o C16o F0o F8o F16o RSP TSP RSEL Control State Machine Feedback Frequency Select MUX MS1 MS2 RST HOLDOVER PCCi FLOCK FS1 FS2 Figure 1 - Functional Block Diagram Zarlink Semiconductor US Patent No. 5,602,884, UK Patent No. 0772912, France Brevete S.G.D.G. 0772912; Germany DBP No. 69502724.7-08 1 Zarlink Semiconductor Inc. Zarlink, ZL and the Zarlink Semiconductor logo are trademarks of Zarlink Semiconductor Inc. Copyright 2003-2006, Zarlink Semiconductor Inc. All Rights Reserved. ZL30409 Data Sheet The ZL30409 is compliant with Telcordia GR-1244-CORE Stratum 4 and ETSI ETS 300 011 2048 kbit/s interfaces. It will meet the jitter/wander tolerance, jitter/wander transfer, intrinsic jitter/wander, frequency accuracy, capture range, holdover frequency and MTIE requirements for these specifications. GND RST TCLR IC SEC PRI VDD OSCo OSCi GND F16o F0o RSP TSP F8o C1.5o VDD LOCK C2o C4o C19o FLOCK GND IC 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 SSOP 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 32 31 30 29 28 27 26 25 TMS TCK TRST TDI TDO IC IC FS1 FS2 IC RSEL MS1 MS2 VDD IC IC NC GND PCCi HOLDOVER VDD C6o C16o C8o Figure 2 - Pin Connections Change Summary Changes from March 2006 Issue to April 2006 Issue. Page, section, figure and table numbers refer to this current issue. Page 1 Item Change Updated Ordering Information Changes from September 2005 Issue to March 2006 Issue. Page, section, figure and table numbers refer to this current issue. Page 1 Item Change Updated Ordering Information 2 Zarlink Semiconductor Inc. ZL30409 Pin Description Pin # 1,10, 23,31 2 Name GND RST Ground. 0 Volts. Description Data Sheet Reset (Input). A logic low at this input resets the ZL30409. To ensure proper operation, the device must be reset after reference signal frequency changes and power-up. The RST pin should be held low for a minimum of 300 ns. While the RST pin is low, all frame pulses except RSP and TSP and all clock outputs except C6o, C16o and C19o are at logic high. The RSP, TSP, C6o, C16o are at logic low during reset. The C19o is free-running during reset. Following a reset, the input reference source and output clocks and frame pulses are phase aligned as shown in Figure 13. TIE Circuit Reset (Input). A logic low at this input resets the Time Interval Error (TIE) correction circuit resulting in a realignment of input phase with output phase as shown in Figure 13. The TCLR pin should be held low for a minimum of 300 ns. This pin is internally pulled down to GND. Internal Connection. Leave unconnected. Secondary Reference (Input). This is one of two (PRI & SEC) input reference sources (falling edge) used for synchronization. One of four possible frequencies (8 kHz, 1.544 MHz, 2.048 MHz or 19.44 MHz) may be used. The selection of the input reference is based upon the MS1, MS2, RSEL, and PCCi control inputs.This pin is internally pulled up to VDD. Primary Reference (Input). See SEC pin description. This pin is internally pulled up to VDD. Positive Supply Voltage. +3.3VDC nominal. Oscillator Master Clock (CMOS Output). For crystal operation, a 20 MHz crystal is connected from this pin to OSCi, see Figure 9. Not suitable for driving other devices. For clock oscillator operation, this pin is left unconnected, see Figure 8. Oscillator Master Clock (CMOS Input). For crystal operation, a 20 MHz crystal is connected from this pin to OSCo, see Figure 9. For clock oscillator operation, this pin is connected to a clock source, see Figure 8. Frame Pulse ST-BUS 8.192 Mb/s (CMOS Output). This is an 8 kHz 61ns active low framing pulse, which marks the beginning of an ST-BUS frame. This is typically used for ST-BUS operation at 8.192 Mb/s. See Figure 14. Frame Pulse ST-BUS 2.048 Mb/s (CMOS Output). This is an 8 kHz 244 ns active low framing pulse, which marks the beginning of an ST-BUS frame. This is typically used for STBUS operation at 2.048 Mb/s and 4.096 Mb/s. See Figure 14. Receive Sync Pulse (CMOS Output). This is an 8 kHz 488 ns active high framing pulse, which marks the beginning of an ST-BUS frame. This is typically used for connection to the Siemens MUNICH-32 device. See Figure 15. Transmit Sync Pulse (CMOS Output). This is an 8 kHz 488 ns active high framing pulse, which marks the beginning of an ST-BUS frame. This is typically used for connection to the Siemens MUNICH-32 device. See Figure 15. Frame Pulse (CMOS Output). This is an 8 kHz 122 ns active high framing pulse, which marks the beginning of a frame. See Figure 14. Clock 1.544 MHz (CMOS Output). This output is used in T1 applications. 3 TCLR 4 5 IC SEC 6 7,17 28,35 8 PRI VDD OSCo 9 OSCi 11 F16o 12 F0o 13 RSP 14 TSP 15 16 F8o C1.5o 3 Zarlink Semiconductor Inc. ZL30409 Pin Description (continued) Pin # 18 19 20 21 22 24 25 26 27 29 30 Name LOCK C2o C4o C19o FLOCK IC C8o C16o C6o HOLD OVER PCCi Description Data Sheet Lock Indicator (CMOS Output). This output goes high when the PLL is frequency locked to the input reference. Clock 2.048 MHz (CMOS Output). This output is used for ST-BUS operation at 2.048 Mb/s. Clock 4.096 MHz (CMOS Output). This output is used for ST-BUS operation at 2.048 Mb/s and 4.096 Mb/s. Clock 19.44 MHz (CMOS Output). This output is used in OC3/STS3 applications. Fast Lock Mode (Input). Set high to allow the PLL to quickly lock to the input reference (less than 500 ms locking time). Internal Connection. Tie low for normal operation. Clock 8.192 MHz (CMOS Output). This output is used for ST-BUS operation at 8.192 Mb/s. Clock 16.384 MHz (CMOS Output). This output is used for ST-BUS operation with a 16.384 MHz clock. Clock 6.312 Mhz (CMOS Output). This output is used for DS2 applications. Holdover (CMOS Output). This output goes to a logic high whenever the PLL goes into holdover mode. Phase Continuity Control Input (Input). The signal at this pin affects the state changes between Primary Holdover Mode and Primary Normal Mode, and Primary Holdover Mode and Secondary Normal Mode. See State Machine control section for details. The logic level at this input is gated in by the rising edge of F8o. No connection. Leave unconnected Internal Connection. Connect to GND. Mode/Control Select 2 (Input). This input determines the state (Normal, Holdover or Freerun) of operation. See Table 3 for details. The logic level at this input is gated in by the rising edge of F8o Mode/Control Select 1 (Input). See MS2 pin description. The logic level at this input is gated in by the rising edge of F8o. This pin is internally pulled down to GND. Reference Source Select (Input). A logic low selects the PRI (primary) reference source as the input reference signal and a logic high selects the SEC (secondary) input. The logic level at this input is gated in by the rising edge of F8o. See Table 2. This pin is internally pulled down to GND. Internal Connection. Connect to GND. Frequency Select 2 (Input). This input, in conjunction with FS1, selects which of four possible frequencies (8 kHz, 1.544 MHz, 2.048 MHz or 19.44 MHz) may be input to the PRI and SEC inputs. See Table 1. Frequency Select 1 (Input). See pin description for FS2. Internal Connection. Connect to GND. Internal Connection. Leave unconnected. Test Serial Data Out (CMOS Output). JTAG serial data is output on this pin on the falling edge of TCK. This pin is held in high impedance state when JTAG scan is not enable. 32 33,34 36 NC IC MS2 37 38 MS1 RSEL 39 40 IC FS2 41 42 43 44 FS1 IC IC TDO 4 Zarlink Semiconductor Inc. ZL30409 Pin Description (continued) Pin # 45 46 47 48 Name TDI TRST TCK TMS Description Data Sheet Test Serial Data In (Input). JTAG serial test instructions and data are shifted in on this pin. This pin is internally pulled up to VDD. Test Reset (Input). Asynchronously initializes the JTAG TAP controller by putting it in the Test-Logic-Reset state. If not used, this pin should be held low. Test Clock (Input): Provides the clock to the JTAG test logic. This pin is internally pulled up to VDD. Test Mode Select (Input). JTAG signal that controls the state transitions of the TAP controller. This pin is internally pulled up to VDD. Functional Description The ZL30409 is a System Synchronizer, providing timing (clock) and synchronization (frame) signals to interface circuits for T1 and E1 Primary Rate Digital Transmission links. Figure 1 is a functional block diagram which is described in the following sections. Reference Select MUX Circuit The ZL30409 accepts two simultaneous reference input signals and operates on their falling edges. Either the primary reference (PRI) signal or the secondary reference (SEC) signal can be selected as input to the TIE Corrector Circuit. The selection is based on the Control, Mode and Reference Selection of the device. See Table 1 and Table 4. Frequency Select MUX Circuit The ZL30409 operates with one of four possible input reference frequencies (8 kHz, 1.544 MHz, 2.048 MHz or 19.44 MHz). The frequency select inputs (FS1 and FS2) determine which of the four frequencies may be used at the reference inputs (PRI and SEC). Both inputs must have the same frequency applied to them. A reset (RST) must be performed after every frequency select input change. See Table 1. FS2 0 0 1 1 FS1 0 1 0 1 Input Frequency 19.44 MHz 8 kHz 1.544 MHz 2.048 MHz Table 1 - Input Frequency Selection Time Interval Error (TIE) Corrector Circuit The TIE corrector circuit, when enabled, prevents a step change in phase on the input reference signals (PRI or SEC) from causing a step change in phase at the input of the DPLL block of Figure 1. During reference input rearrangement, such as during a switch from the primary reference (PRI) to the secondary reference (SEC), a step change in phase on the input signals will occur. A phase step at the input of the DPLL would lead to unacceptable phase changes in the output signal. 5 Zarlink Semiconductor Inc. ZL30409 TCLR Resets Delay Control Circuit Control Signal Data Sheet Delay Value PRI or SEC from Reference Select Mux Programmable Delay Circuit Compare Circuit Virtual Reference to DPLL TIE Corrector Enable from State Machine Feedback Signal from Frequency Select MUX Figure 3 - TIE Corrector Circuit As shown in Figure 3, the TIE Corrector Circuit receives one of the two reference (PRI or SEC) signals, passes the signal through a programmable delay line, and uses this delayed signal as an internal virtual reference, which is input to the DPLL. Therefore, the virtual reference is a delayed version of the selected reference. During a switch from one reference to the other, the State Machine first changes the mode of the device from Normal to Holdover. In Holdover Mode, the DPLL no longer uses the virtual reference signal, but generates an accurate clock signal using storage techniques. The Compare Circuit then measures the phase delay between the current phase (feedback signal) and the phase of the new reference signal. This delay value is passed to the Programmable Delay Circuit (See Figure 3). The new virtual reference signal is now at the same phase position as the previous reference signal would have been if the reference switch not taken place. The State Machine then returns the device to Normal Mode. The DPLL now uses the new virtual reference signal, and since no phase step took place at the input of the DPLL, no phase step occurs at the output of the DPLL. In other words, reference switching will not create a phase change at the input of the DPLL, or at the output of the DPLL. Since internal delay circuitry maintains the alignment between the old virtual reference and the new virtual reference, a phase error may exist between the selected input reference signal and the output signal of the DPLL. This phase error is a function of the difference in phase between the two input reference signals during reference rearrangements. Each time a reference switch is made, the delay between input signal and output signal will change. The value of this delay is the accumulation of the error measured during each reference switch. The programmable delay circuit can be zeroed by applying a logic low pulse to the TIE Circuit Reset (TCLR) pin. A minimum reset pulse width is 300 ns. This results in a phase alignment between the input reference signal and the output signal as shown in Figure 14. Digital Phase Lock Loop (DPLL) As shown in Figure 4, the DPLL of the ZL30409 consists of a Phase Detector, Loop Filter, Digitally Controlled Oscillator, and a Control Circuit. 6 Zarlink Semiconductor Inc. ZL30409 Data Sheet Phase Detector - the Phase Detector compares the virtual reference signal from the TIE Corrector circuit with the feedback signal from the Frequency Select MUX circuit, and provides an error signal corresponding to the phase difference between the two. This error signal is passed to the Loop Filter. The Frequency Select MUX allows the proper feedback signal to be selected (e.g., 8 kHz, 1.544 MHz, 2.048 MHz or 19.44 MHz) from generated output clocks. Virtual Reference from TIE Corrector Phase Detector Loop Filter Digitally Controlled Oscillator DPLL Reference to Output Interface Circuit Feedback Signal from Frequency Select MUX State Select from Input Impairment Monitor Control Circuit State Select from State Machine Figure 4 - DPLL Block Diagram Loop Filter - the Loop Filter is similar to a first order low pass filter with a 1.9 Hz cutoff frequency for all four reference frequency selections (8 kHz, 1.544 MHz, 2.048 MHz or 19.44 MHz). This filter ensures that the jitter transfer requirements in ETS 300 011 and AT&T TR62411 are met. Control Circuit - the Control Circuit uses status and control information from the State Machine and the Input Impairment Circuit to set the mode of the DPLL. The three possible modes are Normal, Holdover and Freerun. Digitally Controlled Oscillator (DCO) - the DCO receives the filtered signal from the Loop Filter, and based on its value, generates a corresponding digital output signal. The synchronization method of the DCO is dependent on the state of the ZL30409. In Normal Mode, the DCO provides an output signal which is frequency and phase locked to the selected input reference signal. In Holdover Mode, the DCO is free running at a frequency equal to the last (less 30 ms to 60 ms) frequency the DCO was generating while in Normal Mode. In Freerun Mode, the DCO is free running with an accuracy equal to the accuracy of the OSCi 20 MHz source. Lock Indicator - When the ZL30409 acquires frequency lock (frequency lock means the center frequency of the PLL is identical to the line frequency), then the lock signal changes from low to high. For specific Lock Indicator design recommendations see the Applications - Lock Indicator section. Output Interface Circuit The output of the DCO (DPLL) is used by the Output Interface Circuit to generate clocks shown in Figure 5. The Output Interface Circuit uses four Tapped Delay Lines followed by a T1 Divider Circuit, an E1 Divider Circuit, and a DS2 Divider Circuit to generate the required output signals. These four tapped delay lines are designed to generate 16.384 MHz, 12.352 MHz, 12.624 MHz and 19.44 MHz signals. The E1 Divider Circuit uses the 16.384 MHz signal to generate four clock outputs (C2, C4, C8, C16) and five frame pulse outputs (F0o, F8o, F16o, RSP, TSP). The C8o, C4o and C2o clocks are generated by simply dividing the C16o clock by two, four and eight respectively. These outputs have a nominal 50% duty cycle. The T1 Divider Circuit uses the 12.384 MHz signal to generate the C1.5o clock by dividing the internal C12 clock by eight. This output has a nominal 50% duty cycle. 7 Zarlink Semiconductor Inc. ZL30409 Data Sheet The DS2 Divider Circuit uses the 12.624 MHz signal to generate the clock output C6o. This output has a nominal 50% duty cycle. T1 Divider 12 MHz Tapped Delay Line C1.5o From DPLL Tapped Delay Line E1 Divider 16 MHz Tapped Delay Line 12 MHz DS2 Divider C2o C4o C8o C16o F0o F8o F16o RSP TSP C6o Tapped Delay Line 19 MHz C19o Figure 5 - Output Interface Circuit Block Diagram The T1 and E1 signals are generated from a common DPLL signal. Consequently, all frame pulse and clock outputs are locked to one another for all operating states, and are also locked to the selected input reference in Normal Mode. See Figures 14 & 16. All frame pulse and clock outputs have limited driving capability, and should be buffered when driving high capacitance (e.g., 30 pF) loads. Input Impairment Monitor This circuit monitors the input signal to the DPLL and automatically enables the Holdover Mode (Auto-Holdover) when the frequency of the incoming signal is outside the Auto-Holdover capture range. (See AC Electrical Characteristics - Performance). This includes a complete loss of incoming signal, or a large frequency shift in the incoming signal. When the incoming signal returns to normal, the DPLL is returned to Normal Mode with the output signal locked to the input signal. The holdover output signal in the ZL30409 is based on the incoming signal 30 ms minimum to 60 ms prior to entering the Holdover Mode. The amount of phase drift while in holdover is negligible because the Holdover Mode is very accurate (e.g., 0.05 ppm). Consequently, the phase delay between the input and output after switching back to Normal Mode is preserved. State Machine Control As shown in Figure 1, this state machine controls the Reference Select MUX, the TIE Corrector Circuit and the DPLL. Control is based on the logic levels at the control inputs RSEL, MS1, MS2 and PCCi (See Figure 6). When switching from Primary Holdover to Primary Normal, the TIE Corrector Circuit is enabled when PCCi = 1, and disabled when PCCi = 0. 8 Zarlink Semiconductor Inc. ZL30409 Data Sheet All state machine changes occur synchronously on the rising edge of F8o. See the Control and Mode of Operation section for full details. To Reference Select MUX To TIE Corrector Enable To DPLL State Select RSEL Control State Machine PCCi MS1 MS2 Figure 6 - Control State Machine Block Diagram Master Clock The ZL30409 can use either a clock or crystal as the master timing source. For recommended master timing circuits, see the Applications - Master Clock section. Control and Mode of Operation The active reference input (PRI or SEC) is selected by the RSEL pin as shown in Table 2. RSEL 0 1 Input Reference PRI SEC Table 2 - Input Reference Selection MS2 0 0 1 1 MS1 0 1 0 1 Mode NORMAL HOLDOVER FREERUN Reserved Table 3 - Operating Modes and States The ZL30409 has three possible modes of operation, Normal, Holdover and Freerun. As shown in Table 3, Mode/Control Select pins MS2 and MS1 select the mode and method of control. Refer to Table 4 and Figure 7 for details of the state change sequences. Normal Mode Normal Mode is typically used when a slave clock source, synchronized to the network is required. In Normal Mode, the ZL30409 provides timing (C1.5o, C2o, C4o, C8o, C16o and C19o) and frame synchronization (F0o, F8o, F16o, TSP and RSP) signals, which are synchronized to one of two reference inputs (PRI or SEC). The input reference signal may have a nominal frequency of 8 kHz, 1.544 MHz, 2.048 MHz or 19.44 MHz. 9 Zarlink Semiconductor Inc. ZL30409 Data Sheet From a reset condition, the ZL30409 will take up to 30 seconds (see AC Electrical Characteristics) of input reference signal to output signals which are synchronized (phase locked) to the reference input. The selection of input references is control dependent as shown in state Table 4. The reference frequencies are selected by the frequency control pins FS2 and FS1 as shown in Table 1. Fast Lock Mode Fast Lock Mode is a submode of Normal Mode, it is used to allow the ZL30409 to lock to a reference more quickly than Normal Mode will allow. Typically, the PLL will lock to the incoming reference within 500 ms if the FLOCK pin is set high. Holdover Mode Holdover Mode is typically used for short durations (e.g., 2 seconds) while network synchronization is temporarily disrupted. In Holdover Mode, the ZL30409 provides timing and synchronization signals, which are not locked to an external reference signal, but are based on storage techniques. The storage value is determined while the device is in Normal Mode and locked to an external reference signal. When in Normal Mode, and locked to the input reference signal, a numerical value corresponding to the ZL30409 output reference frequency is stored alternately in two memory locations every 30 ms. When the device is switched into Holdover Mode, the value in memory from between 30 ms and 60 ms is used to set the output frequency of the device. The frequency accuracy of Holdover Mode is 0.05ppm, which translates to a worst case 35 frame (125 us) slips in 24 hours. This satisfies the AT&T TR62411 and Telcordia GR-1244-CORE Stratum 3 requirement of 0.37ppm (255 frame slips per 24 hours). Two factors affect the accuracy of Holdover Mode. One is drift on the Master Clock while in Holdover Mode, drift on the Master Clock directly affects the Holdover Mode accuracy. Note that the absolute Master Clock (OSCi) accuracy does not affect Holdover accuracy, only the change in OSCi accuracy while in Holdover. For example, a 32 ppm master clock may have a temperature coefficient of 0.1 ppm per degree C. So a 10 degree change in temperature, while the ZL30409 is in Holdover Mode may result in an additional offset (over the 0.05 ppm) in frequency accuracy of 1 ppm. Which is much greater than the 0.05 ppm of the ZL30409. The other factor affecting accuracy is large jitter on the reference input prior (30 ms to 60 ms) to the mode switch. For instance, jitter of 7.5UI at 700 Hz may reduce the Holdover Mode accuracy from 0.05 ppm to 0.10 ppm. Freerun Mode Freerun Mode is typically used when a master clock source is required, or immediately following system power-up before network synchronization is achieved. In Freerun Mode, the ZL30409 provides timing and synchronization signals which are based on the master clock frequency (OSCi) only, and are not synchronized to the reference signals (PRI and SEC). The accuracy of the output clock is equal to the accuracy of the master clock (OSCi). So if a 32 ppm output clock is required, the master clock must also be 32 ppm. See Applications - Crystal and Clock Oscillator sections. 10 Zarlink Semiconductor Inc. ZL30409 ZL30409 Measures of Performance The following are some synchronizer performance indicators and their corresponding definitions. Intrinsic Jitter Data Sheet Intrinsic jitter is the jitter produced by the synchronizing circuit and is measured at its output. It is measured by applying a reference signal with no jitter to the input of the device, and measuring its output jitter. Intrinsic jitter may also be measured when the device is in a non-synchronizing mode, such as free running or holdover, by measuring the output jitter of the device. Intrinsic jitter is usually measured with various bandlimiting filters depending on the applicable standards. In the ZL30409, the intrinsic Jitter is limited to less than 0.02UI on the 2.048 MHz and 1.544 MHz clocks. Jitter Tolerance Jitter tolerance is a measure of the ability of a PLL to operate properly (i.e., remain in lock and or regain lock in the presence of large jitter magnitudes at various jitter frequencies) when jitter is applied to its reference. The applied jitter magnitude and jitter frequency depends on the applicable standards. Jitter Transfer Jitter transfer or jitter attenuation refers to the magnitude of jitter at the output of a device for a given amount of jitter at the input of the device. Input jitter is applied at various amplitudes and frequencies, and output jitter is measured with various filters depending on the applicable standards. The ZL30409 jitter transfer is determined by the Loop Filter corner frequency (1.9 Hz). The ZL30409 has twelve outputs with three possible input frequencies (except for 19.44 MHz, which is internally divided to 8 KHz) for a total of 36 possible jitter transfer functions. Since all outputs are derived from the same signal, the jitter transfer values for the four cases, 8 kHz to 8 kHz, 1.544 MHz to 1.544 MHz and 2.048 MHz to 2.048 MHz can be applied to all outputs. It should be noted that 1UI at 1.544 MHz is 644 ns, which is not equal to 1UI at 2.048 MHz, which is 488 ns. Consequently, a transfer value using different input and output frequencies must be calculated in common units (e.g., seconds) as shown in the following example. What is the T1 and E1 output jitter when the T1 input jitter is 20UI (T1 UI Units) and the T1 to T1 jitter attenuation is 18 dB? - A ----- 20 OutputT1 = InputT1 x10 OutputT1 = 20 x10 - 18 ------- 20 = 2.5UI ( T1 ) ( 1UIT1 ) OutputE1 = OutputT1 x --------------------( 1UIE1 ) ( 644ns ) OutputE1 = OutputT1 x ------------------- = 3.3UI ( T1 ) ( 488ns ) Using the above method, the jitter attenuation can be calculated for all combinations of inputs and outputs based on the three jitter transfer functions provided. Note that the resulting jitter transfer functions for all combinations of inputs (8 kHz, 1.544 MHz, 2.048 MHz and 19.44 MHz) and outputs (8 kHz, 1.544 MHz, 2.048 MHz, 4.096 MHz, 8.192 MHz, 16.384 MHz, 19.44 MHz) for a given input signal (jitter frequency and jitter amplitude) are the same. 11 Zarlink Semiconductor Inc. ZL30409 Data Sheet Since intrinsic jitter is always present, jitter attenuation will appear to be lower for small input jitter signals than for large ones. Consequently, accurate jitter transfer function measurements are usually made with large input jitter signals (e.g., 75% of the specified maximum jitter tolerance). Frequency Accuracy Frequency accuracy is defined as the absolute tolerance of an output clock signal when it is not locked to an external reference, but is operating in a free running mode. For the ZL30409, the Freerun accuracy is equal to the Master Clock (OSCi) accuracy. Holdover Accuracy Holdover accuracy is defined as the absolute tolerance of an output clock signal, when it is not locked to an external reference signal, but is operating using storage techniques. For the ZL30409, the storage value is determined while the device is in Normal Mode and locked to an external reference signal. The absolute Master Clock (OSCi) accuracy of the ZL30409 does not affect Holdover accuracy, but the change in OSCi accuracy while in Holdover Mode does. Capture Range Also referred to as pull-in range. This is the input frequency range over which the synchronizer must be able to pull into synchronization. The ZL30409 capture range is equal to 230 ppm minus the accuracy of the master clock (OSCi). For example, a 32 ppm master clock results in a capture range of 198 ppm. If there are no clock transitions at the active reference pin, the ZL30409 will automatically go to Holdover Mode and indicate this condition with the Holdover pin. Lock Range This is the input frequency range over which the synchronizer must be able to maintain synchronization. The lock range is equal to the capture range for the ZL30409. Time Interval Error (TIE) TIE is the time delay between a given timing signal and an ideal timing signal. 12 Zarlink Semiconductor Inc. ZL30409 Maximum Time Interval Error (MTIE) Data Sheet MTIE is the maximum peak to peak delay between a given timing signal and an ideal timing signal within a particular observation period. MTIE ( S ) = TIEmax ( t ) - TIEmin ( t ) Phase Continuity Phase continuity is the phase difference between a given timing signal and an ideal timing signal at the end of a particular observation period. Usually, the given timing signal and the ideal timing signal are of the same frequency. Phase continuity applies to the output of the synchronizer after a signal disturbance due to a reference switch or a mode change. The observation period is usually the time from the disturbance, to just after the synchronizer has settled to a steady state. Phase Lock Time This is the time it takes the synchronizer to phase lock to the input signal. Phase lock occurs when the input signal and output signal are not changing in phase with respect to each other (not including jitter). Lock time is very difficult to determine because it is affected by many factors which include: * * * initial input to output phase difference initial input to output frequency difference synchronizer loop filter Although a short lock time is desirable, it is not always possible to achieve due to other synchronizer requirements. For instance, better jitter transfer performance is achieved with a lower frequency loop filter which increases lock time. See AC Electrical Characteristics - Performance for Maximum Phase Lock TIme. ZL30409 provides a fast lock pin (FLOCK), which, when set high enables the PLL to lock to an incoming reference within approximately 500 ms. ZL30409 and Network Specifications The ZL30409 meets applicable PLL requirements (intrinsic jitter/wander, jitter/wander tolerance, jitter/wander transfer, frequency accuracy, frequency holdover accuracy, capture range and MTIE during reference rearrangement) for the following specifications. 1. Telcordia GR-1244-CORE for Stratum 4 2. AT&T TR62411 (DS1) December 1990 for Stratum 4 3. ANSI T1.101 (DS1) February 1994 for Stratum 4 4. ETSI 300 011 (E1) April 1992 for Single Access and Multi Access 5. TBR 4 November 1995 6. TBR 12 December 1993 7. TBR 13 January 1996 13 Zarlink Semiconductor Inc. ZL30409 Description Input Controls MS2 0 0 0 0 0 1 MS1 0 0 0 1 1 0 RSEL 0 0 1 0 1 X PCCi 0 1 X X X X Freerun S0 S1 S1 S2 / / Normal (PRI) S1 S2 MTIE S1H S2H S0 State Normal (SEC) S2 S1 MTIE S1 MTIE / S2H S0 Holdover (PRI) S1H S1 S1 MTIE S2 MTIE / S0 Data Sheet Holdover (SEC) S2H S1 MTIE S1 MTIE S2 MTIE / S0 Legend: No Change / Not Valid MTIE State change occurs with TIE Corrector Circuit Refer to Control State Diagram for state changes to and from Auto-Holdover State Table 4 - Control State Table S0 Freerun (10X) S1 Normal Primary (000) {A} S1A Auto-Holdover Primary (000) S2A Auto-Holdover Secondary (001) {A} S2 Normal Secondary (001) (PCCi=0) (PCCi=1) S1H Holdover Primary (010) S2H Holdover Secondary (011) NOTES: (XXX) {A} MS2 MS1 RSEL Invalid Reference Signal Phase Re-Alignment Phase Continuity Maintained (without TIE Corrector Circuit) Phase Continuity Maintained (with TIE Corrector Circuit) Movement to Normal State from any state requires a valid input signal Figure 7 - Control State Diagram 14 Zarlink Semiconductor Inc. ZL30409 Applications Data Sheet This section contains ZL30409 application specific details for clock and crystal operation, reset operation, power supply decoupling, and control operation. Master Clock The ZL30409 can use either a clock or crystal as the master timing source. In Freerun Mode, the frequency tolerance at the clock outputs is identical to the frequency tolerance of the source at the OSCi pin. For applications not requiring an accurate Freerun Mode, tolerance of the master timing source may be 100 ppm. For applications requiring an accurate Freerun Mode, such as AT&T TR62411, the tolerance of the master timing source must be no greater than 32 ppm. Another consideration in determining the accuracy of the master timing source is the desired capture range. The sum of the accuracy of the master timing source and the capture range of the ZL30409 will always equal 230 ppm. For example, if the master timing source is 100 ppm, then the capture range will be 130 ppm. Clock Oscillator - when selecting a Clock Oscillator, numerous parameters must be considered. This includes absolute frequency, frequency change over temperature, output rise and fall times, output levels and duty cycle. ZL30409 OSCi +3.3V +3.3V 20MHz OUT GND 0.1uF OSCo No Connection Figure 8 - Clock Oscillator Circuit For applications requiring 32 ppm clock accuracy, the following clock oscillator module may be used. FOX F7C-2E3-20.0MHz Frequency: Tolerance: Rise & Fall Time: Duty Cycle: 20 MHz 25 ppm 0C to 70C 10 ns (0.33 V 2.97 V 15 pF) 40% to 60% The output clock should be connected directly (not AC coupled) to the OSCi input of the ZL30409, and the OSCo output should be left open as shown in Figure 8. Crystal Oscillator - Alternatively, a Crystal Oscillator may be used. A complete oscillator circuit made up of a crystal, resistor and capacitors is shown in Figure 9. 15 Zarlink Semiconductor Inc. ZL30409 ZL30409 OSCi 20MHz 1M Data Sheet 56pF OSCo 100 39pF 3-50pF 1uH 1uH inductor: may improve stability and is optional Figure 9 - Crystal Oscillator Circuit The accuracy of a crystal oscillator depends on the crystal tolerance as well as the load capacitance tolerance. Typically, for a 20 MHz crystal specified with a 32 pF load capacitance, each 1 pF change in load capacitance contributes approximately 9 ppm to the frequency deviation. Consequently, capacitor tolerances, and stray capacitances have a major effect on the accuracy of the oscillator frequency. The trimmer capacitor shown in Figure 9 may be used to compensate for capacitive effects. If accuracy is not a concern, then the trimmer may be removed, the 39 pF capacitor may be increased to 56 pF, and a wider tolerance crystal may be substituted. The crystal should be a fundamental mode type - not an overtone. The fundamental mode crystal permits a simpler oscillator circuit with no additional filter components and is less likely to generate spurious responses. The crystal specification is as follows. Frequency: 20 MHz Tolerance: As required Oscillation Mode: Fundamental Resonance Mode: Parallel Load Capacitance: 32 pF Maximum Series Resistance: 35 Approximate Drive Level: 1 mW e.g., R1B23B32-20.0MHz (20 ppm absolute, 6 ppm 0C to 50C, 32 pF, 25 ) TIE Correction (using PCCi) When Primary Holdover Mode is entered for short time periods, TIE correction should not be enabled. This will prevent unwanted accumulated phase change between the input and output. For instance, 10 Normal to Holdover to Normal mode change sequences occur, and in each case Holdover was entered for 2 s. Each mode change sequence could account for a phase change as large as 350 ns. Thus, the accumulated phase change could be as large as 3.5 us, and, the overall MTIE could be as large as 3.5 us. Phase hold = 0.05ppm x 2s = 100ns Phase state = 50ns + 200ns = 250ns Phase 10 = 10 x ( 250ns + 100ns ) = 3.5us 16 Zarlink Semiconductor Inc. ZL30409 * * * 0.05 ppm is the accuracy of Holdover Mode 50 ns is the maximum phase continuity of the ZL30409 from Normal Mode to Holdover Mode Data Sheet 200 ns is the maximum phase continuity of the ZL30409 from Holdover Mode to Normal Mode (with or without TIE Corrector Circuit) When 10 Normal to Holdover to Normal mode change sequences occur without MTIE enabled, and in each case holdover was entered for 2 s, each mode change sequence could still account for a phase change as large as 350 ns. However, there would be no accumulated phase change, since the input to output phase is re-aligned after every Holdover to Normal state change. The overall MTIE would only be 350 ns. Reset Circuit A simple power up reset circuit with about a 50 us reset low time is shown in Figure 10. Resistor RP is for protection only and limits current into the RST pin during power down conditions. The reset low time is not critical but should be greater than 300 ns. ZL30409 +3.3V R 10k RST RP 1k C 10nF Figure 10 - Power-Up Reset Circuit 17 Zarlink Semiconductor Inc. ZL30409 Lock Indicator Data Sheet The LOCK pin toggles at a random rate when the PLL is frequency locked to the input reference. In Figure 11 the RC-time-constant circuit can be used to hold the high state of the LOCK pin. Once the PLL is frequency locked to the input reference, the minimum duration of LOCK pin's high state would be 32 ms and the maximum duration of LOCK pin's low state would not exceed 1 second. The following equations can be used to calculate the charge and discharge times of the capacitor. tC = - RD C ln(1 - VT+ /VDD) = 240 s tC = Capacitor's charge time RD = Dynamic resistance of the diode (100 ) C = Capacitor value (1 F) VT+ = Positive going threshold voltage of the Schmidt Trigger (3.0 V) VDD = 3.3 V tD = - R C ln(VT- /VDD) = 1.65 seconds tD = Capacitor's discharge time R = Resistor value (3.3 M) C = Capacitor value (1 F) VT- = Negative going threshold voltage of the Schmidt Trigger (2.0 V) VDD = 3.3 V R=3.3 M ZL30409 LOCK 74HC14 74HC14 LOCK IN4148 + C=1 f Figure 11 - Time-constant Circuit A digital alternative to the RC-time-constant circuit is presented in Figure 12. The circuit in Figure 12 can be used to generate a steady lock signal. The circuit monitors the ZL30409's LOCK pin, as long as it detects a positive pulse every 1.024 seconds or less, the Advanced Lock output will remain high. If no positive pulse is detected on the LOCK output within 1.024 seconds, the Advanced LOCK output will go low. 18 Zarlink Semiconductor Inc. ZL30409 ZL30409 Data Sheet Figure 12 - Digital Lock Pin Circuit 19 Zarlink Semiconductor Inc. ZL30409 Absolute Maximum Ratings* - Voltages are with respect to ground (GND) unless otherwise stated. Parameter 1 2 3 4 Supply voltage Voltage on any pin Current on any pin Storage temperature Symbol VDD VPIN IPIN TST -55 Min. -0.3 -0.3 Max. 7.0 Data Sheet Units V V mA C mW VDD+ 0.3 30 125 200 5 48 SSOP package power dissipation PPD * Exceeding these values may cause permanent damage. Functional operation under these conditions is not implied. Recommended Operating Conditions - Voltages are with respect to ground (GND) unless otherwise stated. Characteristics 1 2 Supply voltage Operating temperature Sym. VDD TA Min. 3.0 -40 Max. 3.6 85 Units V C DC Electrical Characteristics* - Voltages are with respect to ground (GND) unless otherwise stated. Characteristics 1 2 3 4 5 6 7 Supply current with: OSCi = 0 V OSCi = Clock CMOS high-level input voltage CMOS low-level input voltage Input leakage current High-level output voltage Low-level output voltage Sym. IDDS IDD VCIH VCIL IIL VOH VOL -15 2.4 0.4 0.7VDD 0.3VDD 15 Min. Max. 1.8 50 Units mA mA V V A V V VI=VDD or 0 V IOH= 10 mA IOL= 10 mA Conditions/Notes Outputs unloaded Outputs unloaded * Supply voltage and operating temperature are as per Recommended Operating Conditions. 20 Zarlink Semiconductor Inc. ZL30409 AC Electrical Characteristics - Performance Characteristics 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 See "Notes" following AC Electrical Characteristics tables. Data Sheet Sym. 0 ppm 32 ppm 100 ppm Min. -0 -32 -100 -0.05 -0.05 -0.05 -230 -198 -130 Max. +0 +32 +100 +0.05 +0.05 +0.05 +230 +198 +130 30 200 200 200 50 600 Units ppm ppm ppm ppm ppm ppm ppm ppm ppm s ns ns ns ns ns ppm ppm ppm Conditions/ Notes 5-9 5-9 5-9 1,2,4,6-9,41 1,2,4,6-9,41 1,2,4,6-9,41 1-3,6-9 1-3,6-9 1-3,6-9 1-3,6-15 1-3,6-15 1-2,4-15 1-,4,6-15 1-3,6-15 1-15,28 1-3,6,9,10-12 1-3,7,10-12 1-3,8,10-12 Freerun Mode accuracy with OSCi at: Holdover Mode accuracy with OSCi at: 0 ppm 32 ppm 100 ppm Capture range with OSCi at: 0 ppm 32 ppm 100 ppm Phase lock time Output phase continuity with: reference switch mode switch to Normal mode switch to Freerun mode switch to Holdover MTIE (maximum time interval error) Reference input for Auto-Holdover with: 8 kHz or 19.44 MHz 1.544 MHz 2.048 MHz -30k -30k -30k +30k +30k +30k 21 Zarlink Semiconductor Inc. ZL30409 Data Sheet AC Electrical Characteristics - Timing Parameter Measurement Voltage Levels* - Voltages are with respect to ground (GND) unless otherwise stated Characteristics 1 2 Threshold Voltage Rise and Fall Threshold Voltage High Sym. VT VHM CMOS 0.5VDD 0.7VDD 0.3VDD Units V V V 3 Rise and Fall Threshold Voltage Low VLM * Supply voltage and operating temperature are as per Recommended Operating Conditions. * Timing for input and output signals is based on the worst case result of the CMOS thresholds. * See Figure 12. Timing Reference Points ALL SIGNALS tIRF, tORF tIRF, tORF V HM VT V LM Figure 13 - Timing Parameter Measurement Voltage Levels 22 Zarlink Semiconductor Inc. ZL30409 AC Electrical Characteristics - Input/Output Timing Characteristics 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 Reference input pulse width high or low Reference input rise or fall time 8 kHz reference input to F8o delay 1.544 MHz reference input to F8o delay 2.048 MHz reference input to F8o delay 19.44 MHz reference input to F8o delay F8o to F0o delay F16o setup to C16o falling F16o hold to C16o rising F8o to C1.5o delay F8o to C6o delay F8o to C2o delay F8o to C4o delay F8o to C8o delay F8o to C16o delay F8o to TSP delay F8o to RSP delay F8o to C19o delay C1.5o pulse width high or low C6o pulse width high or low C2o pulse width high or low C4o pulse width high or low C8o pulse width high or low C16o pulse width high or low TSP pulse width high RSP pulse width high C19o pulse width high C19o pulse width low F0o pulse width low F8o pulse width high F16o pulse width low Output clock and frame pulse rise or fall time Input Controls Setup Time Input Controls Hold Time Sym. tRW tIRF tR8D tR15D tR2D tR19D tF0D tF16S tF16H tC15D tC6D tC2D tC4D tC8D tC16D tTSPD tRSPD tC19D tC15W tC6W tC2W tC4W tC8W tC16WL tTSPW tRSPW tC19WH tC19WL tF0WL tF8WH tF16WL tORF tS tH 100 100 -21 337 222 46 111 25 -10 -45 -10 -11 -11 -11 -11 -6 -8 -15 309 70 230 111 52 24 478 474 25 17 234 109 47 Min. 100 10 6 363 238 57 130 40 10 -25 10 5 5 5 5 10 8 5 339 86 258 133 70 35 494 491 35 25 254 135 75 9 Data Sheet Max. Units ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns 23 Zarlink Semiconductor Inc. ZL30409 tR8D PRI/SEC 8kHz PRI/SEC 1.544MHz PRI/SEC 2.048MHz PRI/SEC 19.44MHz F8o NOTES: 1. Input to output delay values are valid after a TCLR or RST with no further state changes tR15D tRW Data Sheet VT tRW VT tRW tR19D VT tR2D tRW VT VT Figure 14 - Input to Output Timing (Normal Mode) 24 Zarlink Semiconductor Inc. ZL30409 tF8WH F8o tFOWL F0o tF16WL F16o tC16WL C16o tC8W C8o tC4W C4o tC2W C2o tC6W C6o tC15W tC15D C1.5o tC19W tC19D tC6W tC6D tC2D tC4W tC4D tC8W tC8D tF16S tF16D tF0D Data Sheet VT VT VT tC16D tF16H VT VT VT VT VT VT C19o VT Figure 15 - Output Timing 1 F8o VT C2o VT tRSPD RSP tTSPW TSP tTSPD tRSPW VT VT Figure 16 - Output Timing 2 25 Zarlink Semiconductor Inc. ZL30409 Data Sheet F8o VT tS tH VT MS1,2, RSEL, PCCi Figure 17 - Input Controls Setup and Hold Timing AC Electrical Characteristics - Intrinsic Jitter Unfiltered Characteristics 1 2 3 4 5 6 7 8 9 10 11 12 Intrinsic jitter at F8o (8 kHz) Intrinsic jitter at F0o (8 kHz) Intrinsic jitter at F16o (8 kHz) Intrinsic jitter at C1.5o (1.544 MHz) Intrinsic jitter at C2o (2.048 MHz) Intrinsic jitter at C6o (6.312 MHz) Intrinsic jitter at C4o (4.096 MHz) Intrinsic jitter at C8o (8.192 MHz) Intrinsic jitter at C16o (16.384 MHz) Intrinsic jitter at TSP (8 kHz) Intrinsic jitter at RSP (8 kHz) Intrinsic jitter at C19o (19.44 MHz) Sym. Max. 0.0002 0.0002 0.0002 0.030 0.040 0.120 0.080 0.104 0.104 0.0002 0.0002 0.27 Units UIpp UIpp UIpp UIpp UIpp UIpp UIpp UIpp UIpp UIpp UIpp UIpp Conditions/Notes 1-15,22-25,29 1-15,22-25,29 1-15,22-25,29 1-15,22-25,30 1-15,22-25,31 1-15,22-25,32 1-15,22-25,33 1-15,22-25,34 1-15,22-25,35 1-15,22-25,35 1-15,22-25,35 1-15,22-25,36 See "Notes" following AC Electrical Characteristics tables. AC Electrical Characteristics - C1.5o (1.544 MHz) Intrinsic Jitter Filtered Characteristics 1 2 3 4 Intrinsic jitter (4 Hz to 100 kHz filter) Intrinsic jitter (10 Hz to 40 kHz filter) Intrinsic jitter (8 kHz to 40 kHz filter) Intrinsic jitter (10 Hz to 8 kHz filter) Sym. Min. Max. 0.015 0.010 0.010 0.005 Units UIpp UIpp UIpp UIpp Conditions/Notes 1-15,22-25,30 1-15,22-25,30 1-15,22-25,30 1-15,22-25,30 See "Notes" following AC Electrical Characteristics tables. AC Electrical Characteristics - C2o (2.048 MHz) Intrinsic Jitter Filtered Characteristics 1 2 3 4 Intrinsic jitter (4 Hz to 100 kHz filter) Intrinsic jitter (10 Hz to 40 kHz filter) Intrinsic jitter (8 kHz to 40 kHz filter) Intrinsic jitter (10 Hz to 8 kHz filter) Sym. Min. Max. 0.015 0.010 0.010 0.005 Units UIpp UIpp UIpp UIpp Conditions/Notes 1-15,22-25,31 1-15,22-25,31 1-15,22-25,31 1-15,22-25,31 See "Notes" following AC Electrical Characteristics tables. 26 Zarlink Semiconductor Inc. ZL30409 AC Electrical Characteristics - 8 kHz Input to 8 kHz Output Jitter Transfer Characteristics 1 2 3 4 5 6 Jitter attenuation for 1 Hz@0.01 UIpp input Jitter attenuation for 1 Hz@0.54 UIpp input Jitter attenuation for 10 Hz@0.10 UIpp input Jitter attenuation for 60 Hz@0.10 UIpp input Jitter attenuation for 300 Hz@0.10 UIpp input Jitter attenuation for 3600 Hz@0.005 UIpp input Sym. Min. 0 6 12 28 42 45 Max. 6 16 22 38 Units dB dB dB dB dB dB Data Sheet Conditions/Notes 1-3, 6, 10 -15, 22-23, 25, 29, 37 1-3,6,10 -15, 22-23, 25, 29, 37 1-3, 6,10 -15, 22-23,25,29,37 1-3,6,10-15, 22-23,25,29,37 1-3,6,10 -15, 22-23,25,29,37 1-3,6,10 -15, 22-23,25,29,37 See "Notes" following AC Electrical Characteristics tables. AC Electrical Characteristics - 1.544 MHz Input to 1.544 MHz Output Jitter Transfer Characteristics 1 2 3 4 5 6 7 Jitter attenuation for 1 Hz@20 UIpp input Jitter attenuation for 1 Hz@104 UIpp input Jitter attenuation for 10 Hz@20 UIpp input Jitter attenuation for 60 Hz@20 UIpp input Jitter attenuation for 300 Hz@20 UIpp input Jitter attenuation for 10 kHz@0.3 UIpp input Jitter attenuation for 100 kHz@0.3 UIpp input Sym. Min. 0 6 12 28 42 45 45 Max. 6 16 22 38 Units dB dB dB dB dB dB dB Conditions/Notes 1-3,7,10 -15, 22-23,25,30,37 1-3,7,10 -15, 22-23,25,30,37 1-3,7,10 -15, 22-23,25,30,37 1-3,7,10 -15, 22-23,25,30,37 1-3,7,10-15, 22-23,25,30,37 1-3,7,10-15, 22-23,25,30,37 1-3,7,10-15, 22-23,25,30,37 See "Notes" following AC Electrical Characteristics tables. 27 Zarlink Semiconductor Inc. ZL30409 AC Electrical Characteristics - 2.048 MHz Input to 2.048 MHz Output Jitter Transfer Characteristics 1 2 3 4 5 6 7 8 9 10 11 12 13 14 Jitter at output for 1 Hz@3.00 UIpp input with 40 Hz to 100 kHz filter Jitter at output for 3 Hz@2.33 UIpp input with 40 Hz to 100 kHz filter Jitter at output for 5 Hz@2.07 UIpp input with 40 Hz to 100 kHz filter Jitter at output for 10 Hz@1.76 UIpp input with 40 Hz to 100 kHz filter Jitter at output for 100 Hz@1.50 UIpp input with 40 Hz to 100 kHz filter Jitter at output for 2400 Hz@1.50 UIpp input with 40 Hz to 100 kHz filter Jitter at output for 100 kHz@0.20 UIpp input with 40 Hz to 100 kHz filter Sym. Min. Max. 2.9 0.09 1.3 0.10 0.80 0.10 0.40 0.10 0.06 0.05 0.04 0.03 0.04 0.02 Units UIpp UIpp UIpp UIpp UIpp UIpp UIpp UIpp UIpp UIpp UIpp UIpp UIpp UIpp Data Sheet Conditions/Notes 1-3,8,10 -15, 22-23,25,31,37 1-3,8,10 -15, 22-23,25,31,38 1-3,8,10 -15, 22-23,25,31,37 1-3,8,10 -15, 22-23,25,31,38 1-3,8,10-15, 22-23,25,31,37 1-3,8,10-15, 22-23,25,31,38 1-3,8,10-15, 22-23,25,31,37 1-3,8,10-15, 22-23,25,31,38 1-3,8,10-15, 22-23,25,31,37 1-3,8,10-15, 22-23,25,31,38 1-3,8,10-15, 22-23,25,31,37 1-3,8,10-15, 22-23,25,31,38 1-3,8,10-15, 22-23,25,31,37 1-3,8,10-15, 22-23,25,31,36 See "Notes" following AC Electrical Characteristics tables. 28 Zarlink Semiconductor Inc. ZL30409 AC Electrical Characteristics - 8 kHz Input Jitter Tolerance Characteristics 1 2 3 4 5 6 7 8 Jitter tolerance for 1 Hz input Jitter tolerance for 5 Hz input Jitter tolerance for 20 Hz input Jitter tolerance for 300 Hz input Jitter tolerance for 400 Hz input Jitter tolerance for 700 Hz input Jitter tolerance for 2400 Hz input Jitter tolerance for 3600 Hz input Sym. Min. 0.80 0.70 0.60 0.20 0.15 0.08 0.02 0.01 Max. Units UIpp UIpp UIpp UIpp UIpp UIpp UIpp UIpp Data Sheet Conditions/Notes 1-3,6,10 -15,22-23,25-27,29 1-3,6,10 -15,22-23,25-27,29 1-3,6,10 -15,22-23,25-27,29 1-3,6,10 -15,22-23,25-27,29 1-3,6,10 -15,22-23,25-27,29 1-3,6,10 -15,22-23,25-27,29 1-3,6,10 -15,22-23,25-27,29 1-3,6,10 -15,22-23,25-27,29 See "Notes" following AC Electrical Characteristics tables. AC Electrical Characteristics - 1.544 MHz Input Jitter Tolerance Characteristics 1 2 3 4 5 6 7 8 9 Jitter tolerance for 1 Hz input Jitter tolerance for 5 Hz input Jitter tolerance for 20 Hz input Jitter tolerance for 300 Hz input Jitter tolerance for 400 Hz input Jitter tolerance for 700 Hz input Jitter tolerance for 2400 Hz input Jitter tolerance for 10 kHz input Jitter tolerance for 100 kHz input Sym. Min. 150 140 130 35 25 15 4 1 0.5 Max. Units UIpp UIpp UIpp UIpp UIpp UIpp UIpp UIpp UIpp Conditions/Notes 1-3,7,10 -15,22-23,25-27,30 1-3,7,10 -15,22-23,25-27,30 1-3,7,10 -15,22-23,25-27,30 1-3,7,10 -15,22-23,25-27,30 1-3,7,10 -15,22-23,25-27,30 1-3,7,10 -15,22-23,25-27,30 1-3,7,10 -15,22-23,25-27,30 1-3,7,10 -15,22-23,25-27,30 1-3,7,10 -15,22-23,25-27,30 See "Notes" following AC Electrical Characteristics tables. AC Electrical Characteristics - 2.048 MHz Input Jitter Tolerance Characteristics 1 2 3 4 5 6 7 8 9 Jitter tolerance for 1 Hz input Jitter tolerance for 5 Hz input Jitter tolerance for 20 Hz input Jitter tolerance for 300 Hz input Jitter tolerance for 400 Hz input Jitter tolerance for 700 Hz input Jitter tolerance for 2400 Hz input Jitter tolerance for 10 kHz input Jitter tolerance for 100 kHz input Sym. Min. 150 140 130 50 40 20 5 1 1 Max. Units UIpp UIpp UIpp UIpp UIpp UIpp UIpp UIpp UIpp Conditions/Notes 1-3,8,10 -15,22-23,25-27,31 1-3,8,10 -15,22-23,25-27,31 1-3,8,10 -15,22-23,25-27,31 1-3,8,10 -15,22-23,25-27,31 1-3,8,10 -15,22-23,25-27,31 1-3,8,10 -15,22-23,25-27,31 1-3,8,10 -15,22-23,25-27,31 1-3,8,10 -15,22-23,25-27,31 1-3,8,10 -15,22-23,25-27,31 See "Notes" following AC Electrical Characteristics tables. 29 Zarlink Semiconductor Inc. ZL30409 AC Electrical Characteristics - OSCi 20 MHz Master Clock Input Characteristics 1 2 3 4 5 6 Duty cycle Rise time Fall time Tolerance Sym. Min. -0 -32 -100 40 Max. +0 +32 +100 60 10 10 Units ppm ppm ppm % ns ns Data Sheet Conditions/Notes 16,19 17,20 18,21 See "Notes" following AC Electrical Characteristics tables. Notes: Voltages are with respect to ground (GND) unless otherwise stated. Supply voltage and operating temperature are as per Recommended Operating Conditions. Timing parameters are as per AC Electrical Characteristics - Timing Parameter Measurement Voltage Levels 1. PRI reference input selected. 2. SEC reference input selected. 3. Normal Mode selected. 4. Holdover Mode selected. 5. Freerun Mode selected. 6. 8 kHz Frequency Mode selected. 7. 1.544 MHz Frequency Mode selected. 8. 2.048 MHz Frequency Mode selected. 9. 19.44 MHz Frequency Mode selected. 10. Master clock input OSCi at 20 MHz 0 ppm. 11. Master clock input OSCi at 20 MHz 32 ppm. 12. Master clock input OSCi at 20 MHz 100 ppm. 13. Selected reference input at 0 ppm. 14. Selected reference input at 32 ppm. 15. Selected reference input at 100 ppm. 16. For Freerun Mode of 0 ppm. 17. For Freerun Mode of 32 ppm. 18. For Freerun Mode of 100 ppm. 19. For capture range of 230 ppm. 20. For capture range of 198 ppm. 21. For capture range of 130 ppm. 22. 25 pF capacitive load. 23. OSCi Master Clock jitter is less than 2 nspp, or 0.04 UIpp where1 UIpp=1/20 MHz. 24. Jitter on reference input is less than 7 nspp. 25. Applied jitter is sinusoidal. 26. Minimum applied input jitter magnitude to regain synchronization. 27. Loss of synchronization is obtained at slightly higher input jitter amplitudes. 28. Within 10 ms of the state, reference or input change. 29. 1 UIpp = 125 us for 8 kHz signals. 30. 1 UIpp = 648 ns for 1.544 MHz signals. 31. 1 UIpp = 488 ns for 2.048 MHz signals. 32. 1 UIpp = 323 ns for 3.088 MHz signals. 33. 1 UIpp = 244 ns for 4.096 MHz signals. 34. 1 UIpp = 122 ns for 8.192 MHz signals. 35. 1 UIpp = 61 ns for 16.384 MHz signals. 36. 1 UIpp = 51.44 ns for 19.44 MHz signals. 37. No filter. 38. 40 Hz to 100 kHz bandpass filter. 39. With respect to reference input signal frequency. 40. After a RST or TCLR. 41. Master clock duty cycle 40% to 60%. 42. Prior to Holdover Mode, device was in Normal Mode and phase locked. 30 Zarlink Semiconductor Inc. c Zarlink Semiconductor 2003 All rights reserved. Package Code Previous package codes ISSUE ACN DATE APPRD. For more information about all Zarlink products visit our Web Site at www.zarlink.com Information relating to products and services furnished herein by Zarlink Semiconductor Inc. or its subsidiaries (collectively "Zarlink") is believed to be reliable. However, Zarlink assumes no liability for errors that may appear in this publication, or for liability otherwise arising from the application or use of any such information, product or service or for any infringement of patents or other intellectual property rights owned by third parties which may result from such application or use. Neither the supply of such information or purchase of product or service conveys any license, either express or implied, under patents or other intellectual property rights owned by Zarlink or licensed from third parties by Zarlink, whatsoever. Purchasers of products are also hereby notified that the use of product in certain ways or in combination with Zarlink, or non-Zarlink furnished goods or services may infringe patents or other intellectual property rights owned by Zarlink. This publication is issued to provide information only and (unless agreed by Zarlink in writing) may not be used, applied or reproduced for any purpose nor form part of any order or contract nor to be regarded as a representation relating to the products or services concerned. The products, their specifications, services and other information appearing in this publication are subject to change by Zarlink without notice. No warranty or guarantee express or implied is made regarding the capability, performance or suitability of any product or service. Information concerning possible methods of use is provided as a guide only and does not constitute any guarantee that such methods of use will be satisfactory in a specific piece of equipment. It is the user's responsibility to fully determine the performance and suitability of any equipment using such information and to ensure that any publication or data used is up to date and has not been superseded. Manufacturing does not necessarily include testing of all functions or parameters. These products are not suitable for use in any medical products whose failure to perform may result in significant injury or death to the user. All products and materials are sold and services provided subject to Zarlink's conditions of sale which are available on request. Purchase of Zarlink's I2C components conveys a licence under the Philips I2C Patent rights to use these components in and I2C System, provided that the system conforms to the I2C Standard Specification as defined by Philips. Zarlink, ZL and the Zarlink Semiconductor logo are trademarks of Zarlink Semiconductor Inc. Copyright Zarlink Semiconductor Inc. All Rights Reserved. TECHNICAL DOCUMENTATION - NOT FOR RESALE |
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