CS2100-OTP Fractional-N Clock Multiplier Features General Description Clock Multiplier / Jitter Reduction The CS2100-OTP is an extremely versatile system clocking device that utilizes a programmable phase lock loop. The CS2100-OTP is based on a hybrid analogdigital PLL architecture comprised of a unique combination of a Delta-Sigma Fractional-N Frequency Synthesizer and a Digital PLL. This architecture allows for generation of a low-jitter clock relative to an external noisy synchronization clock with frequencies as low as 50 Hz. The CS2100-OTP has many configuration options which are set once prior to runtime. At runtime there are three hardware configuration pins available for mode and feature selection. – Generates a Low Jitter 6 - 75 MHz Clock from a Jittery or Intermittent 50 Hz to 30 MHz Clock Source Highly Accurate PLL Multiplication Factor – Maximum Error Less Than 1 PPM in HighResolution Mode One-Time Programmability – – Configurable Hardware Control Pins Configurable Auxiliary Output Flexible Sourcing of Reference Clock – – The CS2100-OTP is available in a 10-pin MSOP package in Commercial (-10°C to +70°C) and Automotive-D (-40°C to +85°C) and Automotive-E (-40°C to +105°C) grades. Customer development kits are also available for custom device prototyping, small production programming, and device evaluation. Please see “Ordering Information” on page 26 for complete details. External Oscillator or Clock Source Supports Inexpensive Local Crystal Minimal Board Space Required – No External Analog Loop-filter Components 3.3 V Hardware Control 8 MHz to 75 MHz Low-Jitter Timing Reference Timing Reference Frequency Reference PLL Output Lock Indicator Hardware Configuration Fractional-N Frequency Synthesizer Auxiliary Output 6 to 75 MHz PLL Output N 50 Hz to 30 MHz Frequency Reference Output to Input Clock Ratio Digital PLL & Fractional N Logic Cirrus Logic Confidential http://www.cirrus.com Copyright Cirrus Logic, Inc. 2009–2015 (All Rights Reserved) OCT '15 DS841F3 CS2100-OTP TABLE OF CONTENTS 1. PIN DESCRIPTION ................................................................................................................................. 4 2. TYPICAL CONNECTION DIAGRAM ..................................................................................................... 5 3. CHARACTERISTICS AND SPECIFICATIONS ...................................................................................... 6 RECOMMENDED OPERATING CONDITIONS .................................................................................... 6 ABSOLUTE MAXIMUM RATINGS ........................................................................................................ 6 DC ELECTRICAL CHARACTERISTICS ................................................................................................ 6 AC ELECTRICAL CHARACTERISTICS ................................................................................................ 7 PLL PERFORMANCE PLOTS ............................................................................................................... 8 4. ARCHITECTURE OVERVIEW ............................................................................................................... 9 4.1 Delta-Sigma Fractional-N Frequency Synthesizer ........................................................................... 9 4.2 Hybrid Analog-Digital Phase Locked Loop ...................................................................................... 9 5. APPLICATIONS ................................................................................................................................... 11 5.1 One Time Programmability ............................................................................................................ 11 5.2 Timing Reference Clock Input ........................................................................................................ 11 5.2.1 Internal Timing Reference Clock Divider ............................................................................... 11 5.2.2 Crystal Connections (XTI and XTO) ...................................................................................... 12 5.2.3 External Reference Clock (REF_CLK) .................................................................................. 12 5.3 Frequency Reference Clock Input, CLK_IN ................................................................................... 12 5.3.1 Adjusting the Minimum Loop Bandwidth for CLK_IN ............................................................ 13 5.4 Output to Input Frequency Ratio Configuration ............................................................................. 14 5.4.1 User Defined Ratio (RUD) ..................................................................................................... 14 5.4.2 Ratio Modifier (R-Mod) .......................................................................................................... 15 5.4.3 Effective Ratio (REFF) .......................................................................................................... 15 5.4.4 Ratio Configuration Summary ............................................................................................... 15 5.5 PLL Clock Output ........................................................................................................................... 16 5.6 Auxiliary Output .............................................................................................................................. 17 5.7 Mode Pin Functionality ................................................................................................................... 17 5.7.1 M1 and M0 Mode Pin Functionality ....................................................................................... 17 5.7.2 M2 Mode Pin Functionality .................................................................................................... 18 5.7.2.1 M2 Configured as Output Disable .............................................................................. 18 5.7.2.2 M2 Configured as R-Mod Enable .............................................................................. 18 5.7.2.3 M2 Configured as AuxOutSrc Override ..................................................................... 18 5.8 Clock Output Stability Considerations ............................................................................................ 19 5.8.1 Output Switching ................................................................................................................... 19 5.8.2 PLL Unlock Conditions .......................................................................................................... 19 5.9 Required Power Up Sequencing for Programmed Devices ........................................................... 19 6. PARAMETER DESCRIPTIONS ........................................................................................................... 20 6.1 Modal Configuration Sets ............................................................................................................... 20 6.1.1 R-Mod Selection (RModSel[1:0]) ........................................................................................... 20 6.1.2 Auxiliary Output Source Selection (AuxOutSrc[1:0]) ............................................................. 21 6.2 Ratio 0 - 3 ...................................................................................................................................... 21 6.3 Global Configuration Parameters ................................................................................................... 21 6.3.1 AUX PLL Lock Output Configuration (AuxLockCfg) .............................................................. 21 6.3.2 Reference Clock Input Divider (RefClkDiv[1:0]) .................................................................... 21 6.3.3 Enable PLL Clock Output on Unlock (ClkOutUnl) ................................................................. 22 6.3.4 Low-Frequency Ratio Configuration (LFRatioCfg) ................................................................ 22 6.3.5 M2 Pin Configuration (M2Config[2:0]) ................................................................................... 22 6.3.6 Clock Input Bandwidth (ClkIn_BW[2:0]) ................................................................................ 22 7. CALCULATING THE USER DEFINED RATIO .................................................................................... 23 7.1 High Resolution 12.20 Format ....................................................................................................... 23 7.2 High Multiplication 20.12 Format ................................................................................................... 23 8. PROGRAMMING INFORMATION ........................................................................................................ 24 DS841F3 2 CS2100-OTP 9. PACKAGE DIMENSIONS .................................................................................................................... 25 THERMAL CHARACTERISTICS ......................................................................................................... 25 10. ORDERING INFORMATION .............................................................................................................. 26 11. REVISION HISTORY .......................................................................................................................... 26 LIST OF FIGURES Figure 1. Typical Connection Diagram ........................................................................................................ 5 Figure 2. CLK_IN Sinusoidal Jitter Tolerance ............................................................................................. 8 Figure 3. CLK_IN Sinusoidal Jitter Transfer ................................................................................................ 8 Figure 4. CLK_IN Random Jitter Rejection and Tolerance ......................................................................... 8 Figure 5. Delta-Sigma Fractional-N Frequency Synthesizer ....................................................................... 9 Figure 6. Hybrid Analog-Digital PLL .......................................................................................................... 10 Figure 7. Internal Timing Reference Clock Divider ................................................................................... 11 Figure 8. REF_CLK Frequency vs a Fixed CLK_OUT .............................................................................. 12 Figure 9. External Component Requirements for Crystal Circuit .............................................................. 12 Figure 10. Low bandwidth and new clock domain .................................................................................... 13 Figure 11. High bandwidth with CLK_IN domain re-use ........................................................................... 13 Figure 12. Ratio Feature Summary ........................................................................................................... 16 Figure 13. PLL Clock Output Options ....................................................................................................... 16 Figure 14. Auxiliary Output Selection ........................................................................................................ 17 Figure 15. M2 Mapping Options ................................................................................................................ 18 Figure 16. Parameter Configuration Sets .................................................................................................. 20 LIST OF TABLES Table 1. Modal and Global Configuration .................................................................................................. 11 Table 2. Ratio Modifier .............................................................................................................................. 15 Table 3. Example 12.20 R-Values ............................................................................................................ 23 Table 4. Example 20.12 R-Values ............................................................................................................ 23 DS841F3 3 CS2100-OTP 1. PIN DESCRIPTION VD 1 10 M0 GND 2 9 M1 CLK_OUT 3 8 M2 AUX_OUT 4 7 XTI/REF_CLK CLK_IN 5 6 XTO Pin Name # Pin Description VD 1 Digital Power (Input) - Positive power supply for the digital and analog sections. GND 2 Ground (Input) - Ground reference. CLK_OUT 3 PLL Clock Output (Output) - PLL clock output. AUX_OUT 4 Auxiliary Output (Output) - This pin outputs a buffered version of one of the input or output clocks, or a status signal, depending on configuration. CLK_IN 5 Frequency Reference Clock Input (Input) - Clock input for the Digital PLL frequency reference. XTO XTI/REF_CLK 6 7 Crystal Connections (XTI/XTO) / Timing Reference Clock Input (REF_CLK) (Input/Output) XTI/XTO are I/O pins for an external crystal which may be used to generate the low-jitter PLL input clock. REF_CLK is an input for an externally generated low-jitter reference clock. M2 8 Mode Select (Input) - M2 is a configurable mode selection pin. M1 9 Mode Select (Input) - M1 is a configurable mode selection pin. M0 10 Mode Select (Input) - M0 is a configurable mode selection pin. 4 DS841F3 CS2100-OTP 2. TYPICAL CONNECTION DIAGRAM 0.1 µF 1 µF +3.3 V VD M2 System Microcontroller M1 M0 CS2100-OTP Frequency Reference CLK_IN 1 or 2 XTI/REF_CLK CLK_OUT To circuitry which requires a low-jitter clock AUX_OUT To other circuitry or Microcontroller XTO GND Low-Jitter Timing Reference 1 N.C. x REF_CLK XTO or Crystal 2 40 pF XTI XTO 40 pF Figure 1. Typical Connection Diagram DS841F3 5 CS2100-OTP 3. CHARACTERISTICS AND SPECIFICATIONS RECOMMENDED OPERATING CONDITIONS GND = 0 V; all voltages with respect to ground. (Note 1) Parameters Symbol Min Typ Max Units (Note 2) VD 3.1 3.3 3.5 V Commercial Grade Automotive Grade TAC TAD -10 -40 - +70 +85 °C °C DC Power Supply Ambient Operating Temperature (Power Applied) Notes: 1. Device functionality is not guaranteed or implied outside of these limits. Operation outside of these limits may adversely affect device reliability. 2. CLK_IN must not be applied when these conditions are not met, including during power up. See section 5.9 on page 19 for required power up procedure. ABSOLUTE MAXIMUM RATINGS GND = 0 V; all voltages with respect to ground. Parameters Symbol Min Max Units DC Power Supply VD -0.3 6.0 V Input Current IIN - ±10 mA Digital Input Voltage (Note 3) VIN -0.3 VD + 0.4 V Ambient Operating Temperature (Power Applied) TA -55 125 °C Storage Temperature Tstg -65 150 °C WARNING: Operation at or beyond these limits may result in permanent damage to the device. Notes: 3. The maximum over/under voltage is limited by the input current except on the power supply pin. DC ELECTRICAL CHARACTERISTICS Test Conditions (unless otherwise specified): VD = 3.1 V to 3.5 V; TA = -10°C to +70°C (Commercial Grade); TA = -40°C to +85°C (Automotive-D Grade); TA = -40°C to +105°C (Automotive-E Grade). Symbol Min Typ Max Units Power Supply Current - Unloaded Parameters (Note 4) ID - 12 18 mA Power Dissipation - Unloaded (Note 4) PD - 40 60 mW IIN - - ±10 µA Input Leakage Current Input Capacitance IC - 8 - pF High-Level Input Voltage VIH 70% - - VD Low-Level Input Voltage VIL - - 30% VD High-Level Output Voltage (IOH = -1.2 mA) VOH 80% - - VD Low-Level Output Voltage (IOH = 1.2 mA) VOL - - 20% VD Notes: 4. To calculate the additional current consumption due to loading (per output pin), multiply clock output frequency by load capacitance and power supply voltage. For example, fCLK_OUT (49.152 MHz) * CL (15 pF) * VD (3.3 V) = 2.4 mA of additional current due to these loading conditions on CLK_OUT. 6 DS841F3 CS2100-OTP AC ELECTRICAL CHARACTERISTICS Test Conditions (unless otherwise specified): VD = 3.1 V to 3.5 V; TA = -10°C to +70°C (Commercial Grade); TA = -40°C to +85°C (Automotive-D Grade); TA = -40°C to +105°C (Automotive-E Grade); CL = 15 pF. Parameters Crystal Frequency Fundamental Mode XTAL Symbol Conditions Min Typ Max Units fXTAL RefClkDiv[1:0] = 10 RefClkDiv[1:0] = 01 RefClkDiv[1:0] = 00 RefClkDiv[1:0] = 10 RefClkDiv[1:0] = 01 RefClkDiv[1:0] = 00 8 16 32 - 18.75 37.5 50 MHz MHz MHz 8 16 32 - 18.75 37.5 75 MHz MHz MHz 45 - 55 % Reference Clock Input Frequency fREF_CLK Reference Clock Input Duty Cycle DREF_CLK Internal System Clock Frequency fSYS_CLK 8 18.75 MHz fCLK_IN 50 Hz - 30 MHz 2 10 - - UI ns Clock Input Frequency Clock Input Pulse Width (Note 5) pwCLK_IN fCLK_IN < fSYS_CLK/96 fCLK_IN > fSYS_CLK/96 PLL Clock Output Frequency fCLK_OUT (Note 6) 6 - 75 MHz PLL Clock Output Duty Cycle tOD Measured at VD/2 45 50 55 % Clock Output Rise Time tOR 20% to 80% of VD - 1.7 3.0 ns Clock Output Fall Time tOF 80% to 20% of VD - 1.7 3.0 ns Period Jitter tJIT Base Band Jitter (100 Hz to 40 kHz) Wide Band JItter (100 Hz Corner) (Note 7) - 70 - ps rms (Notes 7, 8) - 50 - ps rms (Notes 7, 9) - 175 - ps rms PLL Lock Time - CLK_IN (Note 10) tLC fCLK_IN < 200 kHz fCLK_IN > 200 kHz - 100 1 200 3 UI ms PLL Lock Time - REF_CLK tLR fREF_CLK = 8 to 75 MHz - 1 3 ms Output Frequency Synthesis Resolution (Note 11) ferr High Resolution High Multiplication 0 0 - ±0.5 ±112 ppm ppm Notes: 5. 1 UI (unit interval) corresponds to tSYS_CLK or 1/fSYS_CLK. 6. fCLK_OUT is ratio-limited when fCLK_IN is below 72 Hz. 7. fCLK_OUT = 24.576 MHz; Sample size = 10,000 points; AuxOutSrc[1:0] = 11. 8. In accordance with AES-12id-2006 section 3.4.2. Measurements are Time Interval Error taken with 3rd order 100 Hz to 40 kHz bandpass filter. 9. In accordance with AES-12id-2006 section 3.4.1. Measurements are Time Interval Error taken with 3rd order 100 Hz Highpass filter. 10. 1 UI (unit interval) corresponds to tCLK_IN or 1/fCLK_IN. 11. The frequency accuracy of the PLL clock output is directly proportional to the frequency accuracy of the reference clock. DS841F3 7 CS2100-OTP PLL PERFORMANCE PLOTS Test Conditions (unless otherwise specified): VD = 3.3 V; TA = 25 °C; CL = 15 pF; fCLK_OUT = 12.288 MHz; fCLK_IN = 12.288 MHz; Sample size = 10,000 points; Base Band Jitter (100 Hz to 40 kHz); AuxOutSrc[1:0] = 11. 10,000 10 1 Hz Bandwidth 128 Hz Bandwidth 1 Hz Bandwidth 128 Hz Bandwidth 0 -10 Jitter Transfer (dB) Max Input Jitter Level (usec) 1,000 100 10 -20 -30 -40 1 -50 0.1 1 10 100 1,000 -60 10,000 1 10 Input Jitter Frequency (Hz) 100 1000 10000 Input Jitter Frequency (Hz) Figure 2. CLK_IN Sinusoidal Jitter Tolerance Figure 3. CLK_IN Sinusoidal Jitter Transfer Samples size = 2.5M points; Base Band Jitter (100Hz to 40kHz). Samples size = 2.5M points; Base Band Jitter (100Hz to 40kHz). 1000 1 Hz Bandwidth 128 Hz Bandwidth Output Jitter Level (nsec) 100 Unlock 10 1 Unlock 0.1 0.01 0.01 0.1 1 10 100 1000 Input Jitter Level (nsec) Figure 4. CLK_IN Random Jitter Rejection and Tolerance 8 DS841F3 CS2100-OTP 4. ARCHITECTURE OVERVIEW 4.1 Delta-Sigma Fractional-N Frequency Synthesizer The core of the CS2100 is a Delta-Sigma Fractional-N Frequency Synthesizer which has very high-resolution for Input/Output clock ratios, low phase noise, very wide range of output frequencies and the ability to quickly tune to a new frequency. In very simplistic terms, the Fractional-N Frequency Synthesizer multiplies the Timing Reference Clock by the value of N to generate the PLL output clock. The desired output to input clock ratio is the value of N that is applied to the delta-sigma modulator (see Figure 5). The analog PLL based frequency synthesizer uses a low-jitter timing reference clock as a time and phase reference for the internal voltage controlled oscillator (VCO). The phase comparator compares the fractional-N divided clock with the original timing reference and generates a control signal. The control signal is filtered by the internal loop filter to generate the VCO’s control voltage which sets its output frequency. The delta-sigma modulator modulates the loop integer divide ratio to get the desired fractional ratio between the reference clock and the VCO output (thus the duty cycle of the modulator sets the fractional value). This allows the design to be optimized for very fast lock times for a wide range of output frequencies without the need for external filter components. As with any Fractional-N Frequency Synthesizer the timing reference clock should be stable and jitter-free. Timing Reference Clock Phase Comparator Internal Loop Filter Voltage Controlled Oscillator PLL Output Fractional-N Divider Delta-Sigma Modulator N Figure 5. Delta-Sigma Fractional-N Frequency Synthesizer 4.2 Hybrid Analog-Digital Phase Locked Loop The addition of the Digital PLL and Fractional-N Logic (shown in Figure 6) to the Fractional-N Frequency Synthesizer creates the Hybrid Analog-Digital Phase Locked Loop with many advantages over classical analog PLL techniques. These advantages include the ability to operate over extremely wide frequency ranges without the need to change external loop filter components while maintaining impressive jitter reduction performance. In the Hybrid architecture, the Digital PLL calculates the ratio of the PLL output clock to the frequency reference and compares that to the desired ratio. The digital logic generates a value of N which is then applied to the Fractional-N frequency synthesizer to generate the desired PLL output frequency. Notice that the frequency and phase of the timing reference signal do not affect the output of the PLL since the digital control loop will correct for the PLL output. A major advantage of the Digital PLL is the ease with which the loop filter bandwidth can be altered. The PLL bandwidth is set to a wide-bandwidth mode to quickly achieve lock and then reduced for optimal jitter rejection. DS841F3 9 CS2100-OTP Delta-Sigma Fractional-N Frequency Synthesizer Timing Reference Clock Phase Comparator Internal Loop Filter Voltage Controlled Oscillator PLL Output Fractional-N Divider Delta-Sigma Modulator Digital PLL and Fractional-N Logic N Digital Filter Frequency Reference Clock Frequency Comparator for Frac-N Generation Output to Input Ratio for Hybrid mode Figure 6. Hybrid Analog-Digital PLL 10 DS841F3 CS2100-OTP 5. APPLICATIONS 5.1 One Time Programmability The one time programmable (OTP) circuitry in the CS2100-OTP allows for pre-configuration of the device prior to use in a system. There are two types of parameters that are used for device pre-configuration: modal and global. The modal parameters are features which, when grouped together, create a modal configuration set (see Figure 16 on page 20). Up to four modal configuration sets can be permanently stored and then dynamically selected using the M[1:0] mode select pins (see Table 1). The global parameters are the remaining configuration settings which do not change with the mode select pins. The modal and global parameters can be pre-set at the factory or user programmed using the customer development kit, CDK2000; Please see “Programming Information” on page 24 for more details. Parameter Type M[1:0] pins = 00 M[1:0] pins = 01 M[1:0] pins = 10 M[1:0] pins = 11 Modal Configuration Set 0 Ratio 0 Configuration Set 1 Ratio 1 Configuration Set 2 Ratio 2 Configuration Set 3 Ratio 3 Global Configuration settings set once for all modes. Table 1. Modal and Global Configuration 5.2 Timing Reference Clock Input The low jitter timing reference clock (RefClk) can be provided by either an external reference clock or an external crystal in conjunction with the internal oscillator. In order to maintain a stable and low-jitter PLL output the timing reference clock must also be stable and low-jitter; the quality of the timing reference clock directly affects the performance of the PLL and hence the quality of the PLL output. 5.2.1 Internal Timing Reference Clock Divider The Internal Timing Reference Clock (SysClk) is limited to a lower maximum frequency than that allowed on the XTI/REF_CLK pin. The CS2100-OTP supports the wider external frequency range by offering an internal divider for RefClk. The RefClkDiv[1:0] global parameter should be configured such that SysClk, the divided RefClk, then falls within the valid range as indicated in “AC Electrical Characteristics” on page 7. XTI/REF_CLK Timing Reference Clock 8 MHz < RefClk < 50 MHz (XTI) 75 MHz (REF_CLK) Timing Reference Clock Divider 1 2 4 Internal Timing Reference Clock 8 MHz < SysClk < 18.75 MHz RefClkDiv[1:0] Fractional-N Frequency Synthesizer PLL Output N Figure 7. Internal Timing Reference Clock Divider It should be noted that the maximum allowable input frequency of the XTI/REF_CLK pin is dependent upon its configuration as either a crystal connection or external clock input. See the “AC Electrical Characteristics” on page 7 for more details. For the lowest possible output jitter, attention should be paid to the absolute frequency of the Timing Reference Clock relative to the PLL Output frequency (CLK_OUT). To minimize output jitter, the Timing Reference Clock frequency should be chosen such that fRefClk is at least +/-15 kHz from fCLK_OUT*N/32 where N is an integer. Figure 8 shows the effect of varying the RefClk frequency around fCLK_OUT*N/32. It should be noted that there will be a jitter null at the zero point when N = 32 (not shown in Figure 8). An DS841F3 11 CS2100-OTP example of how to determine the range of RefClk frequencies around 12 MHz to be used in order to achieve the lowest jitter PLL output at a frequency of 12.288 MHz is as follows: f L f RefClk f H where: CLK__OUT Jitter 180 *32/N f CLK__OUT Typical Base Band Jitter (psec) f L = f CLK_OUT 31 ------ + 15kHz 32 = 12.288MHz 0.96875 + 15kHz = 11.919MHz and f H = f CLK_OUT 32 ------ – 15kHz 32 = 12.288MHz 1 + 15kHz 160 140 120 100 -15 kHz 80 +15 kHz 60 40 20 -80 = 12.273MHz -60 -40 -20 0 20 40 60 80 Normalized REF__CLK Frequency (kHz) Figure 8. REF_CLK Frequency vs. a Fixed CLK_OUT Referenced Control Parameter Definition RefClkDiv[1:0] .......................“Reference Clock Input Divider (RefClkDiv[1:0])” on page 21 5.2.2 Crystal Connections (XTI and XTO) An external crystal may be used to generate RefClk. To accomplish this, a 20 pF fundamental mode parallel resonant crystal must be connected between the XTI and XTO pins as shown in Figure 9. As shown, nothing other than the crystal and its load capacitors should be connected to XTI and XTO. Please refer to the “AC Electrical Characteristics” on page 7 for the allowed crystal frequency range. XTI 40 pF XTO 40 pF Figure 9. External Component Requirements for Crystal Circuit 5.2.3 External Reference Clock (REF_CLK) For operation with an externally generated REF_CLK signal, XTI/REF_CLK should be connected to the reference clock source and XTO should be left unconnected or terminated through a 47 k resistor to GND. 5.3 Frequency Reference Clock Input, CLK_IN The frequency reference clock input (CLK_IN) is used by the Digital PLL and Fractional-N Logic block to dynamically generate a fractional-N value for the Frequency Synthesizer (see “Hybrid Analog-Digital PLL” on page 10). The Digital PLL first compares the CLK_IN frequency to the PLL output. The Fractional-N logic block then translates the desired ratio based off of CLK_IN to one based off of the internal timing reference clock (SysClk). This allows the low-jitter timing reference clock to be used as the clock which the Frequency 12 DS841F3 CS2100-OTP Synthesizer multiplies while maintaining synchronicity with the frequency reference clock through the Digital PLL. The allowable frequency range for CLK_IN is found in the “AC Electrical Characteristics” on page 7. 5.3.1 Adjusting the Minimum Loop Bandwidth for CLK_IN The CS2100 allows the minimum loop bandwidth of the Digital PLL to be adjusted between 1 Hz and 128 Hz using the ClkIn_BW[2:0] global parameter. The minimum loop bandwidth of the Digital PLL directly affects the jitter transfer function; specifically, jitter frequencies below the loop bandwidth corner are passed from the PLL input directly to the PLL output without attenuation. In some applications it is desirable to have a very low minimum loop bandwidth to reject very low jitter frequencies, commonly referred to as wander. In others it may be preferable to remove only higher frequency jitter, allowing the input wander to pass through the PLL without attenuation. Typically, applications in which the PLL_OUT signal creates a new clock domain from which all other system clocks and associated data are derived will benefit from the maximum jitter and wander rejection of the lowest PLL bandwidth setting. See Figure 10. PLL BW = 1 Hz CLK_IN Wander > 1 Hz PLL_OUT MCLK Jitter MCLK Wander and Jitter > 1 Hz Rejected Subclocks generated from new clock domain. or LRCK LRCK SCLK SCLK D0 SDATA D1 SDATA D0 D1 Figure 10. Low bandwidth and new clock domain Systems in which some clocks and data are derived from the PLL_OUT signal while other clocks and data are derived from the CLK_IN signal will often require phase alignment of all the clocks and data in the system. See Figure 11. If there is substantial wander on the CLK_IN signal in these applications, it may be necessary to increase the minimum loop bandwidth allowing this wander to pass through to the CLK_OUT signal in order to maintain phase alignment. For these applications, it is advised to experiment with the loop bandwidth settings and choose the lowest bandwidth setting that does not produce system timing errors due to wandering between the clocks and data synchronous to the CLK_IN domain and those synchronous to the PLL_OUT domain. PLL BW = 128 Hz CLK_IN Wander < 128 Hz PLL_OUT Jitter MCLK or Jitter > 128 Hz Rejected Wander < 128 Hz Passed to Output MCLK Subclocks and data re-used from previous clock domain. LRCK LRCK SCLK SCLK SDATA D0 D1 SDATA D0 D1 Figure 11. High bandwidth with CLK_IN domain re-use DS841F3 13 CS2100-OTP While acquiring lock, the digital loop bandwidth is automatically set to a large value. Once lock is achieved, the digital loop bandwidth will settle to the minimum value selected by the ClkIn_BW[2:0] parameter. Referenced Control Parameter Definition ClkIn_BW[2:0] .......................“Clock Input Bandwidth (ClkIn_BW[2:0])” on page 22 5.4 5.4.1 Output to Input Frequency Ratio Configuration User Defined Ratio (RUD) The User Defined Ratio, RUD, is a 32-bit un-signed fixed-point number which determines the basis for the desired input to output clock ratio. Up to four different ratios, Ratio0-3, can be stored in the CS2100’s one time programmable memory. Selection between the four ratios is achieved by the M[1:0] mode select pins. The 32-bit RUD can be expressed in either a high resolution (12.20) or high multiplication (20.12) format selectable by the LFRatioCfg global parameter. The RUD for high resolution (12.20) format is encoded with 12 MSBs representing the integer binary portion with the remaining 20 LSBs representing the fractional binary portion. The maximum multiplication factor is approximately 4096 with a resolution of 0.954 PPM in this configuration. See “Calculating the User Defined Ratio” on page 23 for more information. The RUD for high multiplication (20.12) format is encoded with 20 MSBs representing the integer binary portion with the remaining 12 LSBs representing the fractional binary portion. In this configuration, the maximum multiplication factor is approximately 1,048,575 with a resolution of 244 PPM. It is recommended that the 12.20 High-Resolution format be utilized whenever the desired ratio is less than 4096 since the output frequency accuracy of the PLL is directly proportional to the accuracy of the timing reference clock and the resolution of the RUD. The status of internal dividers, such as the internal timing reference clock divider, are automatically taken into account. Therefore RUD is simply the desired ratio of the output to input clock frequencies. Referenced Control Parameter Definition Ratio 0-3................................“Ratio 0 - 3” on page 21 LFRatioCfg ............................“Low-Frequency Ratio Configuration (LFRatioCfg)” on page 22 M[1:0] ....................................“M1 and M0 Mode Pin Functionality” on page 17 14 DS841F3 CS2100-OTP 5.4.2 Ratio Modifier (R-Mod) The Ratio Modifier is used to internally multiply/divide the currently addressed RUD (Ratio0-3 stored in the register space remain unchanged). The available options for R-Mod are summarized in Table 2 on page 15. R-Mod is enabled via the M2 pin in conjunction with the appropriate setting of the M2Config[2:0] global parameter (see Section 5.7.2 on page 18). RModSel[1:0] R Modifier 00 0.5 01 0.25 10 0.125 11 0.0625 Table 2. Ratio Modifier Referenced Control Parameter Definition Ratio 0-3................................“Ratio 0 - 3” on page 21 RModSel[1:0] ........................“R-Mod Selection (RModSel[1:0])” section on page 20 M2Config[2:0]........................“M2 Pin Configuration (M2Config[2:0])” on page 22 5.4.3 Effective Ratio (REFF) The Effective Ratio (REFF) is an internal calculation comprised of RUD and the appropriate modifiers, as previously described. REFF is calculated as follows: REFF = RUD R-Mod To simplify operation the device handles some of the ratio calculation functions automatically (such as when the internal timing reference clock divider is set). For this reason, the Effective Ratio does not need to be altered to account for internal dividers. Ratio modifiers which would produce an overflow or truncation of REFF should not be used. In all cases, the maximum and minimum allowable values for REFF are dictated by the frequency limits for both the input and output clocks as shown in the “AC Electrical Characteristics” on page 7. Selection of the user defined ratio from the four stored ratios is made by using the M[1:0] pins. Referenced Control Parameter Definition M[1:0] pins.............................“M1 and M0 Mode Pin Functionality” on page 17 5.4.4 Ratio Configuration Summary The RUD is the user defined ratio for which up to four different values (Ratio0-3) can be stored in the one time programmable memory. The M[1:0] pins then select the user defined ratio to be used as well as the modal configuration set. The resolution/format for the RUD is selectable. R-Mod is applied accordingly. The user defined ratio, ratio modifier, and automatic ratio modifier make up the effective ratio REFF, the final calculation used to determine the output to input clock ratio. The effective ratio is then corrected for the internal dividers. The conceptual diagram in Figure 12 summarizes the features involved in the calculation of the ratio values used to generate the fractional-N value which controls the Frequency Synthesiz- DS841F3 15 CS2100-OTP er. The subscript ‘4’ indicates the modal parameters. Timing Reference Clock (XTI/REF_CLK) Divide RefClkDiv[1:0] Effective Ratio REFF M2 pin M[1:0] pins User Defined Ratio RUD SysClk RModSel[1:0]4 Ratio 0 Ratio Format Ratio 1 12.20 20.12 Ratio 2 Frequency Synthesizer PLL Output RefClkDiv[1:0] Ratio Modifier R Correction Digital PLL & Fractional N Logic Dynamic Ratio, ‘N’ Ratio 3 LFRatioCfg Frequency Reference Clock (CLK_IN) Figure 12. Ratio Feature Summary Referenced Control Parameter Definition Ratio 0-3................................“Ratio 0 - 3” on page 21 M[1:0] pins.............................“M1 and M0 Mode Pin Functionality” on page 17 LFRatioCfg ............................“Low-Frequency Ratio Configuration (LFRatioCfg)” on page 22 RModSel[1:0] ........................“R-Mod Selection (RModSel[1:0])” section on page 20 RefClkDiv[1:0] .......................“Reference Clock Input Divider (RefClkDiv[1:0])” on page 21 5.5 PLL Clock Output The PLL clock output pin (CLK_OUT) provides a buffered version of the output of the frequency synthesizer. The driver can be set to high-impedance with the M2 pin when the M2Config[1:0] global parameter is set to either 000 or 010. The output from the PLL automatically drives a static low condition while the PLL is unlocked (when the clock may be unreliable). This feature can be disabled by setting the ClkOutUnl global parameter, however the state CLK_OUT may then be unreliable during an unlock condition. ClkOutUnl PLL Locked/Unlocked 0 0 2:1 Mux 1 PLL Output M2 pin with M2Config[1:0] = 000, 010 0 2:1 Mux PLL Clock Output PLLClkOut PLL Clock Output Pin (CLK_OUT) 1 Figure 13. PLL Clock Output Options Referenced Control Parameter Definition ClkOutUnl..............................“Enable PLL Clock Output on Unlock (ClkOutUnl)” on page 22 ClkOutDis ..............................“M2 Configured as Output Disable” on page 18 M2Config[2:0]........................“M2 Pin Configuration (M2Config[2:0])” on page 22 16 DS841F3 CS2100-OTP 5.6 Auxiliary Output The auxiliary output pin (AUX_OUT) can be mapped, as shown in Figure 14, to one of four signals: reference clock (RefClk), input clock (CLK_IN), additional PLL clock output (CLK_OUT), or a PLL lock indicator (Lock). The mux is controlled via the AuxOutSrc[1:0] modal parameter. If AUX_OUT is set to Lock, the AuxLockCfg global parameter is then used to control the output driver type and polarity of the LOCK signal (see section 6.3.1 on page 21). In order to indicate an unlock condition, REF_CLK must be present. If AUX_OUT is set to CLK_OUT, the phase of the PLL Clock Output signal on AUX_OUT may differ from the CLK_OUT pin. The driver for the pin can be set to high-impedance using the M2 pin when the M2Config[1:0] global parameter is set to either 001 or 010. AuxOutSrc[1:0] Timing Reference Clock (RefClk) M2 pin with M2Config[1:0] = 001, 010 Frequency Reference Clock (CLK_IN) Auxiliary Output Pin (AUX_OUT) 4:1 Mux PLL Clock Output (PLLClkOut) AuxLockCfg PLL Lock/Unlock Indication (Lock) Figure 14. Auxiliary Output Selection Referenced Control Parameter Definition AuxOutSrc[1:0]......................“Auxiliary Output Source Selection (AuxOutSrc[1:0])” on page 21 AuxOutDis .............................“M2 Configured as Output Disable” on page 18 AuxLockCfg...........................“AUX PLL Lock Output Configuration (AuxLockCfg)” section on page 21 M2Config[2:0]........................“M2 Pin Configuration (M2Config[2:0])” on page 22 5.7 Mode Pin Functionality 5.7.1 M1 and M0 Mode Pin Functionality M[1:0] determine the functional mode of the device and select both the default User Defined Ratio and the set of modal parameters. The modal parameters are RModSel[1:0], and AuxOutSrc[1:0]. By modifying one or more of the modal parameters between the 4 sets, different functional configurations can be achieved. However, global parameters are fixed and the same value will be applied to each functional configuration. Figure 16 on page 20 provides a summary of all parameters used by the device. DS841F3 17 CS2100-OTP 5.7.2 M2 Mode Pin Functionality M2 usage is mapped to one of the optional special functions via the M2Config[2:0] global parameter. Depending on what M2 is mapped to, it will either act as an output enable/disable pin or override certain modal parameters. Figure 15 summarizes the available options and the following sections will describe each option in more detail. M2Config[2:0] global parameter M2 pin 000 Disable CLK_OUT pin 001 Disable AUX_OUT pin 010 Disable CLK_OUT and AUX_OUT pins 011 RModSel[1:0] Modal Parameter Enable 100 Reserved 101 Reserved 110 Reserved 111 Force AuxOutSel[1:0] = 10 (PLL Clock Out) Figure 15. M2 Mapping Options 5.7.2.1 M2 Configured as Output Disable If M2Config[2:0] is set to either ‘000’, ‘001’, or ‘010’, M2 becomes an output disable pin for one or both output pins. If M2 is driven ‘low’, the corresponding output(s) will be enabled, if M2 is driven ‘high’, the corresponding output(s) will be disabled. 5.7.2.2 M2 Configured as R-Mod Enable If M2Config[2:0] is set to ‘011’, M2 becomes the R-Mod enable pin. It should be noted that M2 is the only way to enable R-Mod. Even though the RModSel[1:0] modal parameter can be set arbitrarily for each configuration set, it will not take effect unless enabled via M2. If M2 is driven ‘low’, R-Mod will be disabled, if M2 is driven ‘high’ R-Mod will be enabled. 5.7.2.3 M2 Configured as AuxOutSrc Override If M2Config[2:0] is set to ‘111’, M2 when driven ‘high’ will override the AuxOutSrc[1:0] modal parameter and force the AUX_OUT source to PLL Clock Output. When M2 is driven ‘low’, AUX_OUT will function according to AuxOutSrc[1:0]. 18 DS841F3 CS2100-OTP 5.8 Clock Output Stability Considerations 5.8.1 Output Switching The CS2100-OTP is designed such that re-configuration of the clock routing functions do not result in a partial clock period on any of the active outputs (CLK_OUT and/or AUX_OUT). In particular, enabling or disabling an output, changing the auxiliary output source between REF_CLK and CLK_OUT, and the automatic disabling of the output(s) during unlock will not cause a runt or partial clock period. The following exceptions/limitations exist: • Enabling/disabling AUX_OUT when AuxOutSrc[1:0] = 11 (unlock indicator). • Switching AuxOutSrc[1:0] to or from 01 (CLK_IN) and to or from 11 (unlock indicator) (Transitions between AuxOutSrc[1:0] = [00,10] will not produce a glitch). When any of these exceptions occur, a partial clock period on the output may result. 5.8.2 PLL Unlock Conditions Certain changes to the clock inputs and mode pins can cause the PLL to lose lock which will affect the presence of a clock signal on CLK_OUT. The following outlines which conditions cause the PLL to go unlocked: 5.9 • Any change in the state of the M1 and M0 pins will cause the PLL to temporarily lose lock as the new setting takes affect. • Changes made to the state of the M2 when the M2Config[2:0] global parameter is set to 011, 100, 101, or 110 can cause the PLL to temporarily lose lock as the new setting takes affect. • Any discontinuities on the Timing Reference Clock, REF_CLK. • Discontinuities on the Frequency Reference Clock, CLK_IN. • Gradual changes in CLK_IN frequency greater than ±30% from the starting frequency. • Step changes in CLK_IN frequency. Required Power Up Sequencing for Programmed Devices • Apply power. All input pins, except XTI/REF_CLK, should be held in a static logic hi or lo state until the DC Power Supply specification in the “Recommended Operating Conditions” table on page 6 are met. • Apply input clock(s) if required. • For CDK programmed devices, toggle the state of the M0, M1, or both pins at least 3 times to initialize the device. This must be done after the power supply is stable and before normal operation is expected. Note:This operation is not required for factory programmed devices. • After the specified PLL lock time on page 7 has passed, the device will output the desired clock as configured by the M0-M2 pins. DS841F3 19 CS2100-OTP 6. PARAMETER DESCRIPTIONS As mentioned in Section 5.1 on page 11, there are two different kinds of parameter configuration sets, Modal and Global. These configuration sets, shown in Figure 16, can be programmed in the field using the CDK2000 or preprogrammed at the factory. Please see “Programming Information” on page 24 for more details. M[1:0] pins Modal Configuration Set #0 Ratio 0 RModSel[1:0] AuxOutSrc[1:0] 00 RModSel[1:0] AuxOutSrc[1:0] 01 RModSel[1:0] AuxOutSrc[1:0] 10 RModSel[1:0] AuxOutSrc[1:0] 11 Ratio 1 Modal Configuration Set #2 Ratio 2 Modal Configuration Set #3 Ratio 3 Digital/PLL Core Modal Configuration Set #1 Global Configuration Set AuxLockCfg RefClkDiv[1:0] ClkOutUnl LFRatioCfg M2Config[2:0] ClkIn_BW[2:0] Figure 16. Parameter Configuration Sets 6.1 Modal Configuration Sets There are four instances of each of these configuration parameters. Selection between the four stored sets is made using the M[1:0] pins. 6.1.1 R-Mod Selection (RModSel[1:0]) Selects the R-Mod value, which is used as a factor in determining the PLL’s Fractional N. RModSel[1:0] R-Mod Selection 00 Right-shift R-value by 1 (÷ 2). 01 Right-shift R-value by 2 (÷ 4). 10 Right-shift R-value by 3 (÷ 8). 11 Right-shift R-value by 4 (÷ 16). Application: “Ratio Modifier (R-Mod)” on page 15 Note: This parameter does not take affect unless M2 pin is high and the M2Config[2:0] global parameter is set to ‘011’. 20 DS841F3 CS2100-OTP 6.1.2 Auxiliary Output Source Selection (AuxOutSrc[1:0]) Selects the source of the AUX_OUT signal. AuxOutSrc[1:0] Auxiliary Output Source 00 RefClk. 01 CLK_IN. 10 CLK_OUT. 11 PLL Lock Status Indicator. Application: “Auxiliary Output” on page 17 Note: When set to 11, the AuxLockCfg global parameter sets the polarity and driver type (“AUX PLL Lock Output Configuration (AuxLockCfg)” on page 21). 6.2 Ratio 0 - 3 The four 32-bit User Defined Ratios are stored in the CS2100’s one time programmable memory. See “Output to Input Frequency Ratio Configuration” on page 14 and “Calculating the User Defined Ratio” on page 23 for more details. 6.3 Global Configuration Parameters 6.3.1 AUX PLL Lock Output Configuration (AuxLockCfg) When the AUX_OUT pin is configured as a lock indicator (AuxOutSrc[1:0] modal parameter = ‘11’), this global parameter configures the AUX_OUT driver to either push-pull or open drain. It also determines the polarity of the lock signal. If AUX_OUT is configured as a clock output, the state of this parameter is disregarded. AuxLockCfg AUX_OUT Driver Configuration 0 Push-Pull, Active High (output ‘high’ for unlocked condition, ‘low’ for locked condition). 1 Open Drain, Active Low (output ‘low’ for unlocked condition, high-Z for locked condition). Application: “Auxiliary Output” on page 17 Note: AUX_OUT is an unlock indicator, signalling an error condition when the PLL is unlocked. Therefore, the pin polarity is defined relative to the unlock condition. 6.3.2 Reference Clock Input Divider (RefClkDiv[1:0]) Selects the input divider for the timing reference clock. DS841F3 RefClkDiv[1:0] Reference Clock Input Divider REF_CLK Frequency Range 00 ÷ 4. 32 MHz to 75 MHz (50 MHz with XTI) 01 ÷ 2. 16 MHz to 37.5 MHz 10 ÷ 1. 8 MHz to 18.75 MHz 11 Reserved. Application: “Internal Timing Reference Clock Divider” on page 11 21 CS2100-OTP 6.3.3 Enable PLL Clock Output on Unlock (ClkOutUnl) Defines the state of the PLL output during the PLL unlock condition. 6.3.4 ClkOutUnl Clock Output Enable Status 0 Clock outputs are driven ‘low’ when PLL is unlocked. 1 Clock outputs are always enabled (results in unpredictable output when PLL is unlocked). Application: “PLL Clock Output” on page 16 Low-Frequency Ratio Configuration (LFRatioCfg) Determines how to interpret the currently indexed 32-bit User Defined Ratio. 6.3.5 LFRatioCfg Ratio Bit Encoding Interpretation 0 20.12 - High Multiplier. 1 12.20 - High Accuracy. Application: “User Defined Ratio (RUD)” on page 14 M2 Pin Configuration (M2Config[2:0]) Controls which special function is mapped to the M2 pin. 6.3.6 M2Config[2:0] M2 pin function 000 Disable CLK_OUT pin. 001 Disable AUX_OUT pin. 010 Disable CLK_OUT and AUX_OUT. 011 RModSel[1:0] Modal Parameter Enable. 100 Reserved. 101 Reserved. 110 Reserved. 111 Force AuxOutSrc[1:0] = 10 (PLL Clock Out). Application: “M2 Mode Pin Functionality” on page 18 Clock Input Bandwidth (ClkIn_BW[2:0]) Sets the minimum loop bandwidth when locked to CLK_IN. 22 ClkIn_BW[2:0] Minimum Loop Bandwidth 000 1 Hz 001 2 Hz 010 4 Hz 011 8 Hz 100 16 Hz 101 32 Hz 110 64 Hz 111 128 Hz Application: “Adjusting the Minimum Loop Bandwidth for CLK_IN” on page 13 DS841F3 CS2100-OTP 7. CALCULATING THE USER DEFINED RATIO Note: The software for use with the evaluation kit has built in tools to aid in calculating and converting the User Defined Ratio. This section is for those who would like to know more about how the User Defined Ratio is calculated and stored. Most calculators do not interpret the fixed point binary representation which the CS2100-OTP uses to define the output to input clock ratio (see Section 5.4.1 on page 14); However, with a simple conversion we can use these tools to generate a binary or hex value for Ratio0-3 to be stored in one time programmable memory. Please see “Programming Information” on page 24 for more details on programming. 7.1 High Resolution 12.20 Format To calculate the User Defined Ratio (RUD) to store in the register(s), divide the desired output clock frequency by the given input clock (CLK_IN). Then multiply the desired ratio by the scaling factor of 220 to get the scaled decimal representation; then use the decimal to binary/hex conversion function on a calculator and write to the register. A few examples have been provided in Table 3. Scaled Decimal Representation = (output clock/input clock) 220 Hex Representation of Binary RUD 12.288 MHz/10 MHz=1.2288 1288490 00 13 A9 2A 11.2896 MHz/44.1 kHz=256 268435456 10 00 00 00 Desired Output to Input Clock Ratio (output clock/input clock) Table 3. Example 12.20 R-Values 7.2 High Multiplication 20.12 Format To calculate the User Defined Ratio (RUD) to store in the register(s), divide the desired output clock frequency by the given input clock (CLK_IN). Then multiply the desired ratio by the scaling factor of 212 to get the scaled decimal representation; then use the decimal to binary/hex conversion function on a calculator and write to the register. A few examples have been provided in Table 4. Desired Output to Input Clock Ratio (output clock/input clock) Scaled Decimal Representation = (output clock/input clock) 212 Hex Representation of Binary RUD 12.288 MHz/60 Hz=204,800 838860800 32 00 00 00 11.2896 MHz/59.97 Hz =188254.127... 771088904 2D F5 E2 08 Table 4. Example 20.12 R-Values DS841F3 23 CS2100-OTP 8. PROGRAMMING INFORMATION Field programming of the CS2100-OTP is achieved using the hardware and software tools included with the CDK2000. The software tools can be downloaded from www.cirrus.com for evaluation prior to ordering a CDK. The CDK2000 is designed with built-in features to ease the process of programming small quantities of devices for prototype and small production builds. In addition to its field programming capabilities, the CDK2000 can also be used for the complete evaluation of programmed CS2100-OTP devices. The CS2100-OTP can also be factory programmed for large quantity orders. When ordering factory programmed devices, the CDK should first be used to program and evaluate the desired configuration. When evaluation is complete, the CS2000 Configuration Wizard is used to generate a file containing all device configuration information; this file is conveyed to Cirrus Logic as a complete specification for the factory programming configuration. Please contact your local Cirrus Logic sales representative for more information regarding factory programmed parts. See the CDK2000 datasheet, available at www.cirrus.com, for detailed information on the use of the CDK2000 programming and evaluation tools. Below is a form which represents the information required for programming a device (noted in gray). The “Parameter Descriptions” section beginning on page 20 describes the functions of each parameter. This form may be used either for personal notation for device configuration or it can be filled out and given to a Cirrus representative in conjunction with the programming file from the CDK2000 as an additional check. The User Defined Ratio may be filled out in decimal or it may be entered as hex as outlined in “Calculating the User Defined Ratio” on page 23. For all other parameters mark a ‘0’ or ‘1’ below the parameter name. OTP Modal and Global Configuration Parameters Form Modal Configuration Set #0 Ratio 0 (dec) Ratio 0 (hex) __ __ : __ __ : __ __ : __ __ RModSel1 RModSel0 AuxOutSrc1 AuxOutSrc0 Modal Configuration Set #1 Ratio 1 (dec) Ratio 1 (hex) __ __ : __ __ : __ __ : __ __ RModSel1 RModSel0 AuxOutSrc1 AuxOutSrc0 Modal Configuration Set #2 Ratio 2 (dec) Ratio 2 (hex) __ __ : __ __ : __ __ : __ __ RModSel1 RModSel0 AuxOutSrc1 AuxOutSrc0 Modal Configuration Set #3 Ratio 3 (dec) Ratio 3 (hex) __ __ : __ __ : __ __ : __ __ RModSel1 RModSel0 AuxOutSrc1 AuxOutSrc0 Global Configuration Set AuxLockCfg RefClkDiv1 ClkIn_BW2 24 ClkIn_BW1 RefClkDiv0 ClkOutUnl LFRatioCfg M2Cfg2 M2Cfg1 M2Cfg0 ClkIn_BW0 DS841F3 CS2100-OTP 9. PACKAGE DIMENSIONS 10L MSOP (3 mm BODY) PACKAGE DRAWING (Note 1) N D E11 c E A2 A e b A1 SIDE VIEW 1 2 3 END VIEW L SEATING PLANE L1 TOP VIEW DIM MIN INCHES NOM A A1 A2 b c D E E1 e L L1 -0 0.0295 0.0059 0.0031 ----0.0157 -- -----0.1181 BSC 0.1929 BSC 0.1181 BSC 0.0197 BSC 0.0236 0.0374 REF MAX 0.0433 0.0059 0.0374 0.0118 0.0091 ----0.0315 -- MIN MILLIMETERS NOM NOTE MAX -0 0.75 0.15 0.08 ----0.40 -- -----3.00 BSC 4.90 BSC 3.00 BSC 0.50 BSC 0.60 0.95 REF 1.10 0.15 0.95 0.30 0.23 ----0.80 -- 4, 5 2 3 Notes: 1. Reference document: JEDEC MO-187 2. D does not include mold flash or protrusions which is 0.15 mm max. per side. 3. E1 does not include inter-lead flash or protrusions which is 0.15 mm max per side. 4. Dimension b does not include a total allowable dambar protrusion of 0.08 mm max. 5. Exceptions to JEDEC dimension. THERMAL CHARACTERISTICS Parameter Symbol Min Typ Max Units JA JA - 170 100 - °C/W °C/W Junction to Case Thermal Impedance JC - 30.2 - °C/W Junction to Top Thermal Characteristic (Center of Package) ΨJT - 6 - °C/W Junction to Ambient Thermal Impedance DS841F3 JEDEC 2-Layer JEDEC 4-Layer 25 CS2100-OTP 10.ORDERING INFORMATION The CS2100-OTP is ordered as an un-programmed device. The CS2100-OTP can also be factory programmed for large quantity orders. Please see “Programming Information” on page 24 for more details. Product Description Package Pb-Free CS2100-OTP Clocking Device 10L-MSOP Yes CS2100-OTP Clocking Device 10L-MSOP Yes CS2100-OTP Clocking Device 10L-MSOP Yes CS2100-OTP Clocking Device 10L-MSOP Yes CS2100-OTP Clocking Device 10L-MSOP Yes CS2100-OTP Clocking Device 10L-MSOP Yes CDK2000 Evaluation Platform - Yes Grade Commercial Automotive-D Automotive-E - Temp Range Container Order# -10° to +70°C Rail CS2100P-CZZ -10° to +70°C Tape and Reel CS2100P-CZZR -40° to +85°C Rail CS2100P-DZZ -40° to +85°C Tape and Reel CS2100P-DZZR -40° to +105°C Rail CS2100P-EZZ -40° to +105°C Tape and Reel CS2100P-EZZR - - CDK2000-CLK 11.REVISION HISTORY Release Changes F1 AUG ‘09 Updated Period Jitter specification in “AC Electrical Characteristics” on page 7. Updated Crystal and Ref Clock Frequency specifications in “AC Electrical Characteristics” on page 7. Added “PLL Performance Plots” section on page 8. Updated “Internal Timing Reference Clock Divider” on page 11 and added Figure 8 on page 12. Removed CLK_IN Skipping Mode. Removed Auto R-Mod. Added Mode pin toggle requirement to startup for CDK programmed devices to “Required Power Up Sequencing for Programmed Devices” on page 19. F2 MAY ‘10 Updated to add Automotive Grade temperature ranges and ordering options. F3 OCT ‘15 Updated to add Automotive-E grade temperature ranges and ordering options. Added Note 6 regarding ratio-limited fCLK_OUT in “AC Electrical Characteristics” on page 7. Updated frequency ranges in Figure 2 on page 8 and Figure 3 on page 8. Added unlock conditions to “Auxiliary Output” on page 17. Added two thermal characteristics in “Thermal Characteristics” on page 25. Updated legal verbiage. Important: Please check www.Cirrus.com to confirm that you are using the latest revision of this document and to determine whether there are errata associated with this device. 26 DS841F3 CS2100-OTP Contacting Cirrus Logic Support For all product questions and inquiries, contact a Cirrus Logic Sales Representative. To find one nearest you, go to www.cirrus.com IMPORTANT NOTICE The products and services of Cirrus Logic International (UK) Limited; Cirrus Logic, Inc.; and other companies in the Cirrus Logic group (collectively either “Cirrus Logic” or “Cirrus”) are sold subject to Cirrus’s terms and conditions of sale supplied at the time of order acknowledgment, including those pertaining to warranty, indemnification, and limitation of liability. Software is provided pursuant to applicable license terms. Cirrus reserves the right to make changes to its products and specifications or to discontinue any product or service without notice. Customers should therefore obtain the latest version of relevant information from Cirrus to verify that the information is current and complete. Testing and other quality control techniques are utilized to the extent Cirrus deems necessary. Specific testing of all parameters of each device is not necessarily performed. In order to minimize risks associated with customer applications, the customer must use adequate design and operating safeguards to minimize inherent or procedural hazards. Cirrus is not liable for applications assistance or customer product design. The customer is solely responsible for its selection and use of Cirrus products. Use of Cirrus products may entail a choice between many different modes of operation, some or all of which may require action by the user, and some or all of which may be optional. Nothing in these materials should be interpreted as instructions or suggestions to choose one mode over another. Likewise, description of a single mode should not be interpreted as a suggestion that other modes should not be used or that they would not be suitable for operation. Features and operations described herein are for illustrative purposes only. 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Cirrus gives consent for copies to be made of the information contained herein only for use within your organization with respect to Cirrus integrated circuits or other products of Cirrus, and only if the reproduction is without alteration and is accompanied by all associated copyright, proprietary and other notices and conditions (including this notice). This consent does not extend to other copying such as copying for general distribution, advertising or promotional purposes, or for creating any work for resale. This document and its information is provided “AS IS” without warranty of any kind (express or implied). All statutory warranties and conditions are excluded to the fullest extent possible. No responsibility is assumed by Cirrus for the use of information herein, including use of this information as the basis for manufacture or sale of any items, or for infringement of patents or other rights of third parties. Cirrus Logic, Cirrus, the Cirrus Logic logo design, and SoundClear are among the trademarks of Cirrus. Other brand and product names may be trademarks or service marks of their respective owners. Copyright © 2009–2015 Cirrus Logic, Inc. All rights reserved. SPI is a trademark of Motorola. DS841F3 27