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| SM560 Spread Spectrum Clock Generator Features * * * * * * * * * 25- to 108-MHz operating frequency range Wide (9) range of spread selections Accepts clock and crystal inputs Low power dissipation 3.3V = 85 mw (50 MHz) Frequency Spread disable function Center Spread modulation Low cycle-to cycle jitter Eight-pin SOIC package Applications * VGA controllers * LCD panels and monitors * Printers and multi-function devices (MFP) Benefits * Peak electromagnetic interference (EMI) reduction by 8 to 16 dB * Fast time to market * Cost reduction Block Diagram Pin Configuration 250 K Xin/ CLK 1 4 pf REFERENCE DIVIDER PD CP LF Xin/CLK VDD VSS SSCLK FEEDBACK DIVIDER VCO 1 8 Xout S0 S1 SSCC SM560 2 3 4 7 6 5 MODULATION CONTROL Xout 8 8 pF VDD VSS 2 INPUT DECODER LOGIC DIVIDER AND MUX 3 4 SSCLK 5 6 7 SSCC S1 S0 Cypress Semiconductor Corporation Document #: 38-07020 Rev. *E * 3901 North First Street * San Jose * CA 95134 * 408-943-2600 Revised June 25, 2004 SM560 Pin Definitions Pin 1 2 3 4 5 6 7 8 Name Xin/CLK VDD GND SSCLK SSCC S1 S0 Xout Type I P P O I I I O Positive power supply. Power supply ground. Modulated clock output. Spread Spectrum Clock Control (Enable/Disable) function. SSCG function is enabled when input is high and disabled when input is low. This pin is pulled high internally. Tri-level Logic input control pin used to select frequency and bandwidth. Frequency/bandwidth selection and Tri-level Logic programming. See Figure 1. Tri-level Logic input control pin used to select frequency and bandwidth. Frequency/bandwidth selection and Tri-level Logic programming. See Figure 1. Oscillator output pin connected to crystal. Leave this pin unconnected If an external clock drives Xin/CLK. Description Clock or Crystal connection input. Refer to Table 1 for input frequency range selection. Functional Description The Cypress SM560 is a Spread Spectrum Clock Generator (SSCG) IC used for the purpose of reducing Electro Magnetic Interference (EMI) found in today's high-speed digital electronic systems. The SM560 uses a Cypress-proprietary Phase-Locked Loop (PLL) and Spread Spectrum Clock (SSC) technology to synthesize and frequency modulate the input frequency of the reference clock. By frequency modulating the clock, the measured EMI at the fundamental and harmonic frequencies of Clock (SSCLK1) is greatly reduced. This reduction in radiated energy can significantly reduce the cost of complying with regulatory requirements and time to market without degrading the system performance. The SM560 is a very simple and versatile device to use. The frequency and spread% range is selected by programming S0 and S1digital inputs. These inputs use three (3) logic states including High (H), Low (L) and Middle (M) logic levels to select Table 1. Frequency and Spread% Selection (Center Spread) 2 5 - 5 4 M H z (L o w R a n g e ) In p u t F re q u e n c y (M H z ) 25 - 35 35 - 40 40 - 45 45 - 50 50 - 54 S1=M S0=M (% ) 3 .8 3 .5 3 .2 3 .0 2 .8 S1=M S0=0 (% ) 3 .2 3 .0 2 .8 2 .6 2 .4 S1=1 S0=0 (% ) 2 .8 2 .5 2 .4 2 .2 2 .0 S1=0 S0=0 (% ) 2 .3 2 .1 1 .9 1 .8 1 .7 S1=0 S0=M (% ) 1 .9 1 .7 1 .6 1 .5 1 .4 S e le c t th e F re q u e n c y a n d C e n te r S p re a d % d e s ire d an d th en set S 1, S 0 as in d ic a te d . one of the nine available Frequency Modulation and Spread% ranges. Refer to Table 1 for programming details. The SM560 is optimized for SVGA (40 MHz) and XVGA (65 MHz) Controller clocks and also suitable for the applications with the frequency range of 25 to 108 MHz. A wide range of digitally selectable spread percentages is made possible by using three-level (High, Low and Middle) logic at the S0 and S1 digital control inputs. The output spread (frequency modulation) is symmetrically centered on the input frequency. Spread Spectrum Clock Control (SSCC) function enables or disables the frequency spread and is provided for easy comparison of system performance during EMI testing. The SM560 is available in an eight-pin SOIC package with a 0 to 70C operating temperature range. 5 0 - 1 0 8 M H z (H ig h R a n g e ) In p u t F re q u e n c y (M H z ) 50 - 60 60 - 70 70 - 80 80 - 100 100 - 108 S1=1 S0=M (% ) 2 .5 2 .4 2 .3 2 .0 1 .8 S1=0 S0=1 (% ) 1 .9 1 .8 1 .6 1 .4 1 .3 S1=1 S0=1 (% ) 1 .2 1 .1 1 .1 1 .0 0 .8 S1=M S0=1 (% ) 1 .0 0 .9 0 .9 0 .8 0 .6 S e le c t th e F re q u e n c y a n d C e n te r S p re a d % d e s ire d an d th en set S 1, S 0 as in d ic a te d . Document #: 38-07020 Rev. *E Page 2 of 8 SM560 Tri-level Logic With binary logic, four states can be programmed with two control lines, whereas Tri-level Logic can program nine logic states using two control lines. Tri-level Logic in the SM560 is implemented by defining a third logic state in addition to the standard logic "1" and "0." Pins 6 and 7 of the SM560 recognize a logic state by the voltage applied to the respective pin. These states are defined as "0" (Low), "M" (Middle), and VDD = 3.3 VDC "1" (One). Each of these states has a defined voltage range that is interpreted by the SM560 as a "0," "M," or "1" logic state. Refer to Table 2 for voltage ranges for each logic state. By using two equal value resistors (typically 20K) the "M" state can be easily programmed. Pins 6 or 7 can be tied directly to ground or VDD for Logic "0" or "1" respectively. VDD = 3.3 VDC VDD = 3.3 VDC SM560 20K SM560 SM560 7 1.65 VDC 7 7 6 0 VDC 20K 6 6 5 5 5 EX. 1 EX. 2 EX. 3 Figure 1. Document #: 38-07020 Rev. *E Page 3 of 8 SM560 Absolute Maximum Ratings[1] Supply Voltage (VDD): .................................... -0.5V to +6.0V DC Input Voltage:..................................-0.5V to VDD + 0.5V Junction Temperature ................................. -40C to +140C Operating Temperature:...................................... 0C to 70C Storage Temperature .................................. -65C to +150C Static Discharge Voltage (ESD).......................... 2,000V-Min. Table 2. DC Electrical Characteristics: VDD = 3.3V, Temp. = 25C and CL (Pin 4) = 15 pF, unless otherwise noted Parameter VDD VINH VINM VINL VOH1 VOH2 VOL1 VOL2 Cin1 Cin2 Cin2 IDD1 IDD2 Description Power Supply Range Input High Voltage Input Middle Voltage Input Low Voltage Output High Voltage Output High Voltage Output Low Voltage Output Low Voltage Input Capacitance Input Capacitance Input Capacitance Power Supply Current Power Supply Current 10% S0 and S1 only S0 and S1 only S0 and S1 only IOH = 6 mA IOH = 20 mA IOH = 6 mA IOH = 20 mA Xin/CLK (Pin 1) Xout (Pin 8) S0, S1, SSCC (Pins 7,6,5) FIN = 40 MHz FIN = 65 MHz 3 6 3 4 8 4 30 35 Conditions Min. 2.97 0.85VDD 0.40VDD 0.0 2.4 2.0 0.4 1.2 5 10 5 40 45 Typ. 3.3 VDD 0.50VDD 0.0 Max. 3.63 VDD 0.60VDD 0.15VDD Unit V V V V V V V V pF pF pF mA mA Table 3. Electrical Timing Characteristics: VDD = 3.3V, T = 25C and CL = 15 pF, unless otherwise noted Parameter ICLKFR Trise Tfall DTYin DTYout JCC Description Input Clock Frequency Range Clock Rise Time (Pin 4) Clock Fall Time (Pin 4) Input Clock Duty Cycle Output Clock Duty Cycle Cycle-to-Cycle Jitter Conditions VDD = 3.30V SSCLK1 @ 0.4 - 2.4V SSCLK1 @ 0.4 - 2.4V XIN/CLK (Pin 1) SSCLK1 (Pin 4) Fin = 25 - 108 MHz Min. 25 1.2 1.2 20 45 1.4 1.4 50 50 125 Typ. Max. 108 1.6 1.6 80 55 175 Unit MHz ns ns % % ps SSCG Theory of Operation The SM560 is a PLL-type clock generator using a proprietary Cypress design. By precisely controlling the bandwidth of the output clock, the SM560 becomes a Low EMI clock generator. The theory and detailed operation of the SM560 will be discussed in the following sections. EMI All digital clocks generate unwanted energy in their harmonics. Conventional digital clocks are square waves with a duty cycle that is very close to 50%. Because of this 50/50-duty cycle, digital clocks generate most of their harmonic energy in the odd harmonics, i.e.; third, fifth, seventh, etc. It is possible to reduce the amount of energy contained in the fundamental and odd harmonics by increasing the bandwidth of the fundamental clock frequency. Conventional digital clocks have a very high Q factor, which means that all of the energy at that frequency is concentrated in a very narrow bandwidth, consequently, higher energy peaks. Regulatory agencies test electronic equipment by the amount of peak energy radiated from the equipment. By reducing the peak energy at the fundamental and harmonic frequencies, the equipment under test is able to satisfy agency requirements for EMI. Conventional methods of reducing EMI have been to use shielding, filtering, multi-layer PCBs, etc. The SM560 uses the approach of reducing the peak energy in the clock by increasing the clock bandwidth, and lowering the Q. SSCG SSCG uses a patented technology of modulating the clock over a very narrow bandwidth and controlled rate of change, both peak and cycle to cycle. The SM560 takes a narrow band digital reference clock in the range of 25-108 MHz and produces a clock that sweeps between a controlled start and stop frequency and precise rate of change. To understand what happens to a clock when SSCG is applied, consider a 65-MHz clock with a 50% duty cycle. From a 65-MHz clock we know the following: Note: 1. Single Power Supply: The Voltage on any input or I/O pin cannot exceed the power pin during power up. Document #: 38-07020 Rev. *E Page 4 of 8 SM560 Clock Frequency = fc = 65MHz Clock Period = Tc =1/65 MHz = 15.4 ns 50 % 50 % can see a 6.48-dB reduction in the peak RF energy when using the SSCG clock. Tc = 15.4 ns Modulation Rate Spectrum Spread Clock Generators utilize frequency modulation (FM) to distribute energy over a specific band of frequencies. The maximum frequency of the clock (Fmax) and minimum frequency of the clock (Fmin) determine this band of frequencies. The time required to transition from Fmin to Fmax and back to Fmin is the period of the Modulation Rate, Tmr. Modulation Rates of SSCG clocks are generally referred to in terms of frequency or Fmod = 1/Tmod. The input clock frequency, Fin, and the internal divider count, Cdiv, determine the Modulation Rate. In some SSCG clock generators, the selected range determines the internal divider count. In other SSCG clocks, the internal divider count is fixed over the operating range of the part. The SM560 and SM561 have a fixed divider count, as listed below. If this clock is applied to the Xin/CLK pin of the SM560, the output clock at pin 4 (SSCLK) will be sweeping back and forth between two frequencies. These two frequencies, F1 and F2, are used to calculate to total amount of spread or bandwidth applied to the reference clock at pin 1. As the clock is making the transition from f1 to f2, the amount of time and sweep waveform play a very important role in the amount of EMI reduction realized from an SSCG clock. The modulation domain analyzer is used to visualize the sweep waveform and sweep period. The left side of Figure 2 shows the modulation profile of a 65-MHz SSCG clock. Notice that the actual sweep waveform is not a simple sine or sawtooth waveform. The right side of Figure 2 is a scan of the same SSCG clock using a spectrum analyzer. In this scan you Device SM560 SM561 Cdiv 1166 2332 (All Ranges) (All Ranges) SM560 65 MHz S1 = 1, S0 = M Example: Device = Fin = Range = Then; Modulation Rate = Fmod = 65 MHz/1166 = 55.8 kHz. Spectrum2.46% Modulation Profile BW = Analyzer -6.58 dB Figure 2. SSCG Clock, SM560, Fin = 65 MHz Document #: 38-07020 Rev. *E Page 5 of 8 SM560 SM560 Application Schematic 3.3 uH. L1 NOTE 1. C2 Y1 C3 27 pF 40 MHz 27 pF C4 .01 uF. VDD 1 VDD 2 Xin/CLK Xout 8 R2 20 K VDD S0 7 C5 22 uF. C6 0.1 uF 3 GND S1 6 R4 20 K R5 4 Application Load 22 SM560 SSCLK SSCC 5 VDD Figure 3. Application Schematic[2] The schematic in Figure 3 above demonstrates how the Figure 3 also demonstrates how to properly use the tri-level SM560 is configured in a typical application. This application logic employed in the SM560. Notice that resistors R2 and R4 is using a 40-MHz reference derived from a third overtone create a voltage divider that places VDD/2 on pin 7 to satisfy crystal connected to pins 1 and 8. Since Y1 is a third overtone the voltage requirement for an "M" state. crystal a notch filter is created with L1 and C3 to dampen the With this configuration, the SM560 will produce an SSCG gain of the oscillator at the fundamental frequency of this clock that is at a center frequency of 40 MHz. Referring to crystal which is 13.33 MHz. Table 2, range "0, M" at 40 MHz will generate a modulation profile that has a 1.7% peak to peak spread. Ordering Information[3] Package Type 8-pin SOIC 8-pin SOIC-Tape and Reel 8-pin SOIC 8-pin SOIC-Tape and Reel Marking: Example: IMI SM560BS Date Code, Lot# Part Number IMISM560BZ IMISM560BZT Lead Free Devices CYISM560BSXC CYISM560BSXCT Product Flow Commercial, 0 to 70C Commercial, 0 to 70C Commercial, 0 to 70C Commercial, 0 to 70C SM560 B S Package S = SOIC Revision IMI Device Number Note: 2. The value of L1 is calculated such that L1 and C3 are tuned to a frequency that is 130% higher than the fundamental frequency of the crystal. 3. The ordering part number differs from the marking on the actual device. ZC1 = 1/2fC ZC1 = 1/6.28 (17.33 MHz) (27 pF) ZC1 = 340 ZL1 = 2FL L = ZL1/2f L = 340/6.28(17.33 MHz) L = 3.12 H Document #: 38-07020 Rev. *E Page 6 of 8 SM560 Package Drawing and Dimensions 8-lead (150-Mil) SOIC S8 8 Lead (150 Mil) SOIC - S08 PIN 1 ID 4 1 1. DIMENSIONS IN INCHES[MM] MIN. MAX. 2. PIN 1 ID IS OPTIONAL, ROUND ON SINGLE LEADFRAME RECTANGULAR ON MATRIX LEADFRAME 3. REFERENCE JEDEC MS-012 0.230[5.842] 0.244[6.197] 0.150[3.810] 0.157[3.987] 4. PACKAGE WEIGHT 0.07gms PART # S08.15 STANDARD PKG. 5 8 SZ08.15 LEAD FREE PKG. 0.189[4.800] 0.196[4.978] SEATING PLANE 0.010[0.254] 0.016[0.406] X 45 0.061[1.549] 0.068[1.727] 0.004[0.102] 0.050[1.270] BSC 0.004[0.102] 0.0098[0.249] 0~8 0.016[0.406] 0.035[0.889] 0.0075[0.190] 0.0098[0.249] 0.0138[0.350] 0.0192[0.487] 51-85066-*C Document #: 38-07020 Rev. *E Page 7 of 8 (c) Cypress Semiconductor Corporation, 2004. The information contained herein is subject to change without notice. Cypress Semiconductor Corporation assumes no responsibility for the use of any circuitry other than circuitry embodied in a Cypress product. Nor does it convey or imply any license under patent or other rights. Cypress products are not warranted nor intended to be used for medical, life support, life saving, critical control or safety applications, unless pursuant to an express written agreement with Cypress. Furthermore, Cypress does not authorize its products for use as critical components in life-support systems where a malfunction or failure may reasonably be expected to result in significant injury to the user. The inclusion of Cypress products in life-support systems application implies that the manufacturer assumes all risk of such use and in doing so indemnifies Cypress against all charges. SM560 Document History Page Document Title: SM560 Spread Spectrum Clock Generator Document Number: 38-07020 Rev. ** *A *B *C *D *E ECN No. 106948 113520 119445 122675 231055 237630 Issue Date 06/07/01 04/10/02 10/16/02 12/14/02 See ECN See ECN Orig. of Change IKA DMG RGL RBI RGL RGL Description of Change Convert from IMI to Cypress Package suffix changed (per Cypress standard) Corrected the values in the Absolute Maximum Ratings to match the device. Added power up requirements to operating conditions information. Added Lead Free Devices Minor Change: Added letter C in the ordering for Lead Free Document #: 38-07020 Rev. *E Page 8 of 8 |
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