CY22393/CY223931 CY22394 CY22395 Three-PLL Serial-Programmable Flash-Programmable Clock Generator Three-PLL Serial-Programmable Flash-Programmable Clock Generator Features Advanced Features ■ Three integrated phase-locked loops (PLLs) ■ Two-wire serial interface for in-system configurability ■ Ultra wide divide counters (8-bit Q, 11-bit P, and 7-bit post divide) ■ Configurable output buffer Improved linear crystal load capacitors ■ Digital VCXO ■ Flash programmability with external programmer ■ High frequency LVPECL output (CY22394 only) ■ Field-programmable ■ 3.3/2.5 V outputs (CY22395 only) ■ Low jitter, high accuracy outputs ■ NiPdAu lead finish (CY223931) ■ ■ Power management options (Shutdown, OE, Suspend) ■ Configurable crystal drive strength ■ Frequency select through three external LVTTL inputs ■ 3.3 V operation ■ 16-pin TSSOP package ■ CyClocksRT™ software support Functional Description The CY22393, CY22394, and CY22395 are a family of parts designed as upgrades to the existing CY22392 device. These parts have similar performance to the CY22392, but provide advanced features to meet the needs of more demanding applications. The clock family has three PLLs which, when combined with the reference, allow up to four independent frequencies to be output on up to six pins. These three PLLs are completely programmable. The CY223931 is the CY22393 with NiPdAu lead finish. For a complete list of related documentation, click here. Selector Guide Part Number Outputs Input Frequency Range Output Frequency Range Specifics CY22393_C 6 CMOS 8 MHz–30 MHz (external crystal) 1 MHz–166 MHz (reference clock) Up to 200 MHz Commercial temperature CY22393_I 6 CMOS 8 MHz–30 MHz (external crystal) 1 MHz–166 MHz (reference clock) Up to 166 MHz Industrial temperature CY223931_I 6 CMOS 8 MHz–30 MHz (external crystal) 1 MHz–166 MHz (reference clock) Up to 166 MHz Industrial temperature CY22394_C 1 PECL/ 4 CMOS 8 MHz–30 MHz (external crystal) 1 MHz–166 MHz (reference clock) 100 MHz–400 MHz (PECL) Up to 200 MHz (CMOS) Commercial temperature CY22394_I 1 PECL/ 4 CMOS 8 MHz–30 MHz (external crystal) 1 MHz–150 MHz (reference clock) 125 MHz–375 MHz (PECL) Up to 166 MHz (CMOS) Industrial temperature CY22395_C 4 LVCMOS/ 1 8 MHz–30 MHz (external crystal) CMOS 1 MHz–166 MHz (reference clock) Up to 200 MHz (3.3 V) Up to 133 MHz (2.5 V) Commercial temperature CY22395_I 4 LVCMOS/ 1 8 MHz–30 MHz (external crystal) CMOS 1 MHz–150 MHz (reference clock) Up to 166 MHz (3.3 V) Up to 133 MHz (2.5 V) Industrial temperature Cypress Semiconductor Corporation Document Number: 38-07186 Rev. *L • 198 Champion Court • San Jose, CA 95134-1709 • 408-943-2600 Revised May 17, 2016 CY22393/CY223931 CY22394 CY22395 Logic Block Diagram – CY22393 and CY223931 XTALIN XTALOUT XBUF OSC. CONFIGURATION FLASH SHUTDOWN/OE PLL1 11-Bit P 8-Bit Q PLL2 SCLK 11-Bit P 8-Bit Q SDAT 4x4 Crosspoint Switch S2/SUSPEND PLL3 11-Bit P 8-Bit Q Divider /2, /3, or /4 CLKE Divider 7-Bit CLKD Divider 7-Bit CLKC Divider 7-Bit CLKB Divider 7-Bit CLKA Logic Block Diagram – CY22394 XTALIN XTALOUT XBUF OSC. CONFIGURATION FLASH SHUTDOWN/OE SCLK SDAT S2/SUSPEND PLL1 11-Bit P 8-Bit Q PLL2 11-Bit P 8-Bit Q PLL3 0º PECL OUTPUT 180º 4x4 Crosspoint Switch P+CLK P-CLK Divider 7-Bit CLKC Divider 7-Bit CLKB Divider 7-Bit CLKA 11-Bit P 8-Bit Q Document Number: 38-07186 Rev. *L Page 2 of 25 CY22393/CY223931 CY22394 CY22395 Logic Block Diagram – CY22395 XTALIN XTALOUT OSC. CONFIGURATION FLASH SHUTDOWN/OE Divider /2, /3, or /4 LCLKE PLL1 11-Bit P 8-Bit Q Divider 7-Bit LCLKD Divider 7-Bit CLKC Divider 7-Bit LCLKB Divider 7-Bit LCLKA SCLK 4x4 Crosspoint Switch SDAT S2/SUSPEND PLL2 11-Bit P 8-Bit Q PLL3 11-Bit P 8-Bit Q LCLKA, LCLKB, LCLKD, LCLKE referenced to LVDD Document Number: 38-07186 Rev. *L Page 3 of 25 CY22393/CY223931 CY22394 CY22395 Contents Pinouts .............................................................................. 5 Pin Definitions .................................................................. 5 Functional Overview ........................................................ 6 Configurable PLLs ....................................................... 6 General Purpose Inputs .............................................. 6 Crystal Input ................................................................ 6 Crystal Drive Level and Power .................................... 6 Digital VCXO ............................................................... 6 Output Configuration ................................................... 6 Power-Saving Features ............................................... 7 Improving Jitter ............................................................ 7 Power Supply Sequencing .......................................... 7 CyClocksRT Software ...................................................... 7 Junction Temperature Limitations ............................... 7 Dynamic Updates ........................................................ 7 Memory Bitmap Definitions ............................................. 8 Clk{A–D}_Div[6:0] ........................................................ 8 ClkE_Div[1:0] ............................................................... 8 Clk*_FS[2:0] ................................................................ 8 Xbuf_OE ...................................................................... 8 PdnEn .......................................................................... 8 Clk*_ACAdj[1:0] ........................................................... 8 Clk*_DCAdj[1:0] .......................................................... 8 PLL*_Q[7:0] ................................................................. 8 PLL*_P[9:0] ................................................................. 8 PLL*_P ........................................................................ 8 PLL*_LF[2:0] ............................................................... 9 PLL*_En ...................................................................... 9 DivSel .......................................................................... 9 OscCap[5:0] ................................................................ 9 OscDrv[1:0] ................................................................. 9 Reserved ..................................................................... 9 Serial Programming Bitmaps — Summary Tables ...... 10 Serial Bus Programming Protocol and Timing ............ 11 Default Startup Condition for the CY22393/931/94/95 .............................................. 11 Device Address ......................................................... 11 Data Valid .................................................................. 11 Document Number: 38-07186 Rev. *L Data Frame ............................................................... 11 Acknowledge Pulse ................................................... 11 Write Operations ............................................................. 12 Writing Individual Bytes ............................................. 12 Writing Multiple Bytes ................................................ 12 Read Operations ............................................................. 12 Current Address Read ............................................... 12 Random Read ........................................................... 12 Sequential Read ........................................................ 12 Serial Programming Interface Timing ........................... 14 Serial Programming Interface Timing Specifications ................................................................. 14 Absolute Maximum Conditions ..................................... 15 Operating Conditions ..................................................... 15 Recommended Crystal Specifications ......................... 15 3.3 V Electrical Characteristics ..................................... 16 2.5 V Electrical Characteristics ..................................... 16 Thermal Resistance ........................................................ 16 3.3 V Switching Characteristics .................................... 17 2.5 V Switching Characteristics .................................... 17 Switching Waveforms .................................................... 18 Test Circuit ...................................................................... 19 Ordering Information ...................................................... 20 Possible Configurations ............................................. 20 Ordering Code Definitions ......................................... 21 Package Diagram ............................................................ 22 Acronyms ........................................................................ 23 Document Conventions ................................................. 23 Units of Measure ....................................................... 23 Document History Page ................................................. 24 Sales, Solutions, and Legal Information ...................... 25 Worldwide Sales and Design Support ....................... 25 Products .................................................................... 25 PSoC®Solutions ....................................................... 25 Cypress Developer Community ................................. 25 Technical Support ..................................................... 25 Page 4 of 25 CY22393/CY223931 CY22394 CY22395 Pinouts Figure 1. Pin Diagram: 16-pin TSSOP CY22393/CY223931/CY22394/CY22395 CLKC V DD 1 16 2 CY22393 15 AGND 3 XTALIN CY223931 SHUTDOW N /OE S2/ SUSPEND CLKC 1 V DD 2 AGND 3 16 CY22394 15 14 SHUTDOW N /OE S2/ SUSPEND 15 SHUTDOW N /OE S2/ SUSPEND 3 14 AV DD CLKC 1 V DD 2 AGND 16 CY22395 14 AV D D 4 13 SCLK(S1) XTALIN 4 13 SCLK(S1) XTALIN 4 13 SCLK(S1) XTALOUT 5 12 SDAT(S0) XTALOUT 5 12 SDAT(S0) XTALOUT 5 12 SDAT(S0) XBUF 6 11 GND XBUF 6 11 GND LV DD 6 11 GND/ LGND CLKD 7 10 CLKA P-CLK 7 10 CLKA LCLKD 7 10 LCLKA CLKE 8 P+CLK 8 9 CLKB LCLKE 8 9 LCLKB 9 CLKB AV D D Pin Definitions Pin Number CY22393 CY223931 Pin Number CY22394 Pin Number CY22395 CLKC 1 1 1 Configurable clock output C VDD 2 2 2 Power supply AGND 3 3 3 Analog Ground XTALIN 4 4 4 Reference crystal input or external reference clock input XTALOUT 5 5 5 Reference crystal feedback Name Description XBUF 6 6 N/A LVDD N/A N/A 6 Low voltage clock output power supply Configurable clock output D; LCLKD referenced to LVDD CLKD or LCLKD P– CLK CLKE or LCLKE 7 N/A 7 N/A 7 N/A Buffered reference clock output LV PECL output[1] 8 N/A 8 N/A 8 N/A CLKB or LCLKB 9 9 9 Configurable clock output B; LCLKB referenced to LVDD CLKA or LCLKA 10 10 10 Configurable clock output A; LCLKA referenced to LVDD GND/LGND 11 11 11 Ground P+ CLK Configurable clock output E; LCLKE referenced to LVDD LV PECL output[1] SDAT (S0) 12 12 12 Serial port data. S0 value latched during start up SCLK (S1) 13 13 13 Serial port clock. S1 value latched during start up AVDD 14 14 14 Analog power supply S2/ SUSPEND 15 15 15 General purpose input for frequency control; bit 2. Optionally, Suspend mode control input SHUTDOWN/ OE 16 16 16 Places outputs in tristate condition and shuts down chip when LOW. Optionally, only places outputs in tristate condition and does not shut down chip when LOW Note 1. LVPECL outputs require an external termination network. Document Number: 38-07186 Rev. *L Page 5 of 25 CY22393/CY223931 CY22394 CY22395 Functional Overview Configurable PLLs PLL1 generates a frequency that is equal to the reference divided by an 8-bit divider (Q) and multiplied by an 11-bit divider in the PLL feedback loop (P). The output of PLL1 is sent to two locations: the cross point switch and the PECL output (CY22394). The output of PLL1 is also sent to a /2, /3, or /4 synchronous post-divider that is output through CLKE. The frequency of PLL1 can be changed using serial programming or by external CMOS inputs, S0, S1, and S2. See the following section on General Purpose Inputs for more detail. PLL2 generates a frequency that is equal to the reference divided by an 8-bit divider (Q) and multiplied by an 11-bit divider in the PLL feedback loop (P). The output of PLL2 is sent to the cross point switch. The frequency of PLL2 is changed using serial programming. PLL3 generates a frequency that is equal to the reference divided by an 8-bit divider (Q) and multiplied by an 11-bit divider in the PLL feedback loop (P). The output of PLL3 is sent to the cross point switch. The frequency of PLL3 is changed using serial programming. General Purpose Inputs S2 is a general purpose input that is programmed to allow for two different frequency settings. Options that switches with this general purpose input are as follows: the frequency of PLL1, the output divider of CLKB, and the output divider of CLKA. The two frequency settings are contained within an eight-row frequency table. The values of SCLK (S1) and SDAT (S0) pins are latched during start up and used as the other two indexes into this array. CLKA and CLKB have seven-bit dividers that point to one of the two programmable settings (register 0 and register 1). Both clocks share a single register control and both must be set to register 0, or both must be set to register 1. For example, the part may be programmed to use S0, S1, and S2 (0,0,0 to 1,1,1) to control eight different values of P and Q on PLL1. For each PLL1 P and Q setting, one of the two CLKA and CLKB divider registers can be chosen. Any divider change as a result of switching S2 is guaranteed to be glitch free. Crystal Input The input crystal oscillator is an important feature of this family of parts because of its flexibility and performance features. The oscillator inverter has programmable drive strength. This allows for maximum compatibility with crystals from various manufacturers. Parallel resonant, fundamental mode crystals should be used. The input load capacitors are placed on-die to reduce external component cost. These capacitors are true parallel-plate capacitors for ultra-linear performance. These were chosen to reduce the frequency shift that occurs when nonlinear load capacitance interacts with load, bias, supply, and temperature changes. Nonlinear (FET gate) crystal load capacitors must not be used for MPEG, communications, or other applications that are sensitive to absolute frequency requirements. Document Number: 38-07186 Rev. *L The value of the load capacitors is determined by six bits in a programmable register. The load capacitance can be set with a resolution of 0.375 pF for a total crystal load range of 6 pF to 30 pF. Typical crystals have a CL specification in the range of 12 pF to 18 pF. For driven clock inputs, the input load capacitors can be completely bypassed. This allows the clock chip to accept driven frequency inputs up to 166 MHz. If the application requires a driven input, leave XTALOUT floating. Crystal Drive Level and Power Crystals are specified to accept a maximum drive level. Generally, larger crystals can accept more power. For a given voltage swing, power dissipation in the crystal is proportional to ESR and proportional to the square of the crystal frequency. (Note that actual ESR is sometimes much less than the value specified by the crystal manufacturer.) Power is also almost proportional to the square of CL. Power can be reduced to less than the DL specification in the table below by selecting a reduced frequency crystal with low CL and low R1 (ESR). Digital VCXO The serial programming interface is used to dynamically change the capacitor load value on the crystal. A change in crystal load capacitance corresponds with a change in the reference frequency. For special pullable crystals specified by Cypress, the capacitance pull range is +150 ppm to –150 ppm from midrange. Be aware that adjusting the frequency of the reference affects all frequencies on all PLLs in a similar manner since all frequencies are derived from the single reference. Output Configuration Under normal operation there are four internal frequency sources that are routed through a programmable cross point switch to any of the four programmable 7-bit output dividers. The four sources are: reference, PLL1, PLL2, and PLL3. The following is a description of each output. CLKA’s output originates from the cross point switch and goes through a programmable 7-bit post divider. The 7-bit post divider derives its value from one of the two programmable registers. See the section on General Purpose Inputs on page 6 for more information. CLKB’s output originates from the cross point switch and goes through a programmable 7-bit post divider. The 7-bit post divider derives its value from one of the two programmable registers. See the section on General Purpose Inputs on page 6 for more information. CLKC’s output originates from the cross point switch and goes through a programmable 7-bit post divider. The 7-bit post divider derives its value from one programmable register. CLKD’s output originates from the cross point switch and goes through a programmable 7-bit post divider. The 7-bit post divider derives its value from one programmable register. For the CY22394, CLKD is brought out as the complimentary version of a LV PECL Clock referenced to CLKE, bypassing both the cross point switch and 7-bit post divider. Page 6 of 25 CY22393/CY223931 CY22394 CY22395 CLKE’s output originates from PLL1 and goes through a post divider that may be programmed to /2, /3, or /4. For the CY22394, CLKE is brought out as a low voltage PECL Clock, bypassing the post divider. XBUF is the buffered reference. The Clock outputs have been designed to drive a single point load with a total lumped load capacitance of 15 pF. While driving multiple loads is possible with the proper termination it is generally not recommended. Power-Saving Features The SHUTDOWN/OE input tristates the outputs when pulled LOW. If system shutdown is enabled, a LOW on this pin also shuts off the PLLs, counters, reference oscillator, and all other active components. The resulting current on the VDD pins is less than 5 mA (typical). Relock the PLLs after leaving shutdown mode. CyClocksRT Software CyClocksRT is our second generation software application that allows users to configure this family of devices. The easy-to-use interface offers complete control of the many features of this family including, but not limited to, input frequency, PLL and output frequencies, and different functional options. It checks data sheet frequency range limitations and automatically applies performance tuning. CyClocksRT also has a power estimation feature that allows the user to see the power consumption of a specific configuration. You can download a free copy of CyberClocks that includes CyClocksRT for free on Cypress’s web site at www.cypress.com. CyClocksRT is used to generate P, Q, and divider values used in serial programming. There are many internal frequency rules that are not documented in this data sheet, but are required for proper operation of the device. Check these rules by using the latest version of CyClocksRT. The S2/SUSPEND input is configured to shut down a customizable set of outputs and/or PLLs, when LOW. All PLLs and any of the outputs are shut off in nearly any combination. The only limitation is that if a PLL is shut off, all outputs derived from it must also be shut off. Suspending a PLL shuts off all associated logic, while suspending an output simply forces a tristate condition. It is possible to program this family such that the maximum Junction Temperature rating is exceeded. The package JA is 115 °C/W. Use the CyClocksRT power estimation feature to verify that the programmed configuration meets the Junction Temperature and Package Power Dissipation maximum ratings. With the serial interface, each PLL and/or output is individually disabled. This provides total control over the power savings. Dynamic Updates Improving Jitter The output divider registers are not synchronized with the output clocks. Changing the divider value of an active output is likely cause a glitch on that output. Jitter Optimization Control is useful for mitigating problems related to similar clocks switching at the same moment, causing excess jitter. If one PLL is driving more than one output, the negative phase of the PLL can be selected for one of the outputs (CLKA–CLKD). This prevents the output edges from aligning, allowing superior jitter performance. Power Supply Sequencing For parts with multiple VDD pins, there are no power supply sequencing requirements. The part is not fully operational until all VDD pins have been brought up to the voltages specified in the Operating Conditions Table on page 15. All grounds must be connected to the same ground plane. Document Number: 38-07186 Rev. *L Junction Temperature Limitations PLL P and Q data is spread between three bytes. Each byte becomes active on the acknowledge for that byte, so changing P and Q data for an active PLL is likely cause the PLL to try to lock on an out-of-bounds condition. For this reason, turn off the PLL being programmed during the update. Do this by setting the PLL*_En bit LOW. PLL1, CLKA, and CLKB each have multiple registers supplying data. To program these resources safely, always program an inactive register, and then transition to that register. This allows these resources to stay active during programming. The serial interface is active even with the SHUTDOWN/OE pin LOW as the serial interface logic uses static components and is completely self timed. The part does not meet the IDDS current limit with transitioning inputs. Page 7 of 25 CY22393/CY223931 CY22394 CY22395 Memory Bitmap Definitions Xbuf_OE Clk{A–D}_Div[6:0] This bit enables the XBUF output when HIGH. For the CY22395, Xbuf_OE = 0. Each of the four main output clocks (CLKA–CLKD) features a 7-bit linear output divider. Any divider setting between 1 and 127 may be used by programming the value of the desired divider into this register. Odd divide values are automatically duty cycle corrected. Setting a divide value of zero powers down the divider and forces the output to a tristate condition. CLKA and CLKB have two divider registers, selected by the DivSel bit (which in turn is selected by S2, S1, and S0). This allows the output divider value to change dynamically. For the CY22394 device, ClkD_Div = 000001. ClkE_Div[1:0] CLKE has a simpler divider (see Table 1). For the CY22394, set ClkE_Div = 01. Table 1. ClkE Divider PdnEn This bit selects the function of the SHUTDOWN/OE pin. When this bit is HIGH, the pin is an active LOW shutdown control. When this bit is LOW, this pin is an active HIGH output enable control. Clk*_ACAdj[1:0] These bits modify the output predrivers, changing the duty cycle through the pads. These are nominally set to 01, with a higher value shifting the duty cycle higher. The performance of the nominal setting is guaranteed. Clk*_DCAdj[1:0] These bits modify the DC drive of the outputs. The performance of the nominal setting is guaranteed. Table 3. Output Drive Strength ClkE_Div[1:0] ClkE Output 00 Off Clk*_DCAdj[1:0] 01 PLL1 0 Phase/4 00 –30% of nominal 10 PLL1 0 Phase/2 01 Nominal 11 PLL1 0 Phase/3 10 +15% of nominal 11 +50% of nominal Clk*_FS[2:0] Each of the four main output clocks (CLKA–CLKD) has a three-bit code that determines the clock sources for the output divider. The available clock sources are: Reference, PLL1, PLL2, and PLL3. Each PLL provides both positive and negative phased outputs, for a total of seven clock sources (see Table 2). Note that the phase is a relative measure of the PLL output phases. No absolute phase relation exists at the outputs. Table 2. Clock Source Clk*_FS[2:0] Clock Source 000 Reference Clock 001 Reserved 010 PLL1 0 Phase 011 PLL1 180 Phase 100 PLL2 0 Phase 101 PLL2 180 Phase 110 PLL3 0 Phase 111 PLL3 180 Phase Document Number: 38-07186 Rev. *L Output Drive Strength PLL*_Q[7:0] PLL*_P[9:0] PLL*_P These are the 8-bit Q value and 11-bit P values that determine the PLL frequency. The formula is: PT F PLL = F REF ------- QT P T = 2 P + 3 + PO Equation 1 QT = Q + 2 Page 8 of 25 CY22393/CY223931 CY22394 CY22395 PLL*_LF[2:0] OscDrv[1:0] These bits adjust the loop filter to optimize the stability of the PLL. Table 4 can be used to guarantee stability. However, CyClocksRT uses a more complicated algorithm to set the loop filter for enhanced jitter performance. Use the Print Preview function in CyClocksRT to determine the charge pump settings for optimal jitter performance. These bits control the crystal oscillator gain setting. These must always be set according to Table 5. The parameters are the Crystal Frequency, Internal Crystal Parasitic Resistance (equivalent series resistance), and the OscCap setting during crystal start up, which occurs when power is applied, or after shutdown is released. If in doubt, use the next higher setting. Table 4. Loop Filter Settings Table 5. Crystal Oscillator Gain Settings PLL*_LF[2:0] PT Min PT Max OscCap 00H–20H 20H–30H 30H–40H 000 16 231 Crystal Freq\R 30 60 30 60 30 60 001 232 626 8–15 MHz 00 01 01 10 01 10 010 627 834 15–20 MHz 01 10 01 10 10 10 011 835 1043 20–25 MHz 01 10 10 10 10 11 100 1044 1600 25–30 MHz 10 10 10 11 11 NA PLL*_En For external reference, the use Table 6. This bit enables the PLL when HIGH. If PLL2 or PLL3 are not enabled, then any output selecting the disabled PLL must have a divider setting of zero (off). Since the PLL1_En bit is dynamic, internal logic automatically turns off dependent outputs when PLL1_En goes LOW. Table 6. Osc Drv for External Reference DivSel Reserved This bit controls which register is used for the CLKA and CLKB dividers. These bits must be programmed LOW for proper operation of the device. External Freq (MHz) 1–25 25–50 50–90 90–166 OscDrv[1:0] 00 01 10 11 OscCap[5:0] This controls the internal capacitive load of the oscillator. The approximate effective crystal load capacitance is: C LOAD = 6pF + OscCap 0.375pF Equation 2 Set to zero for external reference clock. Document Number: 38-07186 Rev. *L Page 9 of 25 CY22393/CY223931 CY22394 CY22395 Serial Programming Bitmaps — Summary Tables Addr 08H 09H 0AH 0BH 0CH 0DH 0EH 0FH 10H 11H 12H 13H 14H 15H 16H 17H DivSel 0 1 0 1 – – – – – – – – – – – – Addr S2 (1, 0) 40H 000 41H 42H 43H 001 44H 45H 46H 010 47H 48H 49H 011 4AH 4BH 4CH 100 4DH 4EH 4FH 101 50H 51H 52H 110 53H 54H 55H 56H 57H b7 b6 ClkA_FS[0] ClkA_FS[0] ClkB_FS[0] ClkB_FS[0] ClkC_FS[0] ClkD_FS[0] ClkD_FS[2:1] Clk{C,X}_ACAdj[1:0] ClkX_DCAdj[1] Reserved PLL2_En Reserved PLL3_En b7 b6 DivSel PLL1_En DivSel PLL1_En DivSel PLL1_En DivSel PLL1_En DivSel PLL1_En DivSel PLL1_En DivSel PLL1_En DivSel PLL1_En 111 Document Number: 38-07186 Rev. *L b5 b3 b2 ClkA_Div[6:0] ClkA_Div[6:0] ClkB_Div[6:0] ClkB_Div[6:0] ClkC_Div[6:0] ClkD_Div[6:0] ClkC_FS[2:1] ClkB_FS[2:1] Clk{A,B,D,E}_ACAdj[1:0] PdnEn Xbuf_OE Clk{D,E}_DCAdj[1] ClkC_DCAdj[1] PLL2_Q[7:0] PLL2_P[7:0] PLL2_LF[2:0] PLL2_PO PLL3_Q[7:0] PLL3_P[7:0] PLL3_LF[2:0] PLL3_PO Osc_Cap[5:0] b5 b4 b4 b3 PLL1_Q[7:0] PLL1_P[7:0] PLL1_LF[2:0] PLL1_Q[7:0] PLL1_P[7:0] PLL1_LF[2:0] PLL1_Q[7:0] PLL1_P[7:0] PLL1_LF[2:0] PLL1_Q[7:0] PLL1_P[7:0] PLL1_LF[2:0] PLL1_Q[7:0] PLL1_P[7:0] PLL1_LF[2:0] PLL1_Q[7:0] PLL1_P[7:0] PLL1_LF[2:0] PLL1_Q[7:0] PLL1_P[7:0] PLL1_LF[2:0] PLL1_Q[7:0] PLL1_P[7:0] PLL1_LF[2:0] b2 b1 b0 ClkA_FS[2:1] ClkE_Div[1:0] Clk{A,B}_DCAdj[1] PLL2_P[9:8] PLL3_P[9:8] Osc_Drv[1:0] b1 b0 PLL1_PO PLL1_P[9:8] PLL1_PO PLL1_P[9:8] PLL1_PO PLL1_P[9:8] PLL1_PO PLL1_P[9:8] PLL1_PO PLL1_P[9:8] PLL1_PO PLL1_P[9:8] PLL1_PO PLL1_P[9:8] PLL1_PO PLL1_P[9:8] Page 10 of 25 CY22393/CY223931 CY22394 CY22395 Serial Bus Programming Protocol and Timing The CY22393, CY22394 and CY22395 have a 2-wire serial interface for in-system programming. They use the SDAT and SCLK pins, and operate up to 400 kbit/s in Read or Write mode. Except for the data hold time, it is compliant with the I2C bus standard. The basic Write serial format is as follows: Start Bit; 7-bit Device Address (DA); R/W Bit; Slave Clock Acknowledge (ACK); 8-bit Memory Address (MA); ACK; 8-bit Data; ACK; 8-bit Data in MA+1 if desired; ACK; 8-bit Data in MA+2; ACK; etc. until STOP Bit. The basic serial format is illustrated in Figure 2 on page 13. Default Startup Condition for the CY22393/931/94/95 Data Valid Data is valid when the clock is HIGH, and can only be transitioned when the clock is LOW as illustrated in Figure 3 on page 13. Data Frame Every new data frame is indicated by a start and stop sequence, as illustrated in Figure 4 on page 14. Start Sequence - Start Frame is indicated by SDAT going LOW when SCLK is HIGH. Every time a start signal is given, the next 8-bit data must be the device address (seven bits) and a R/W bit, followed by register address (eight bits) and register data (eight bits). The default (programmed) condition of each device is generally set by the distributor, who programs the device using a customer specified JEDEC file produced by CyClocksRT, Cypress’s proprietary development software. Parts shipped by the factory are blank and unprogrammed. In this condition, all bits are set to 0, all outputs are tristated, and the crystal oscillator circuit is active. Stop Sequence - Stop Frame is indicated by SDAT going HIGH when SCLK is HIGH. A Stop Frame frees the bus for writing to another part on the same bus or writing to another random register address. While users can develop their own subroutine to program any or all of the individual registers as described in the following pages, it may be easier to simply use CyClocksRT to produce the required register setting file. During Write Mode the CY22393, CY22394, and CY22395 respond with an Acknowledge pulse after every eight bits. To do this, they pull the SDAT line LOW during the N*9th clock cycle, as illustrated in Figure 5 on page 14. (N = the number of bytes transmitted). During Read Mode, the master generates the acknowledge pulse after the data packet is read. Device Address Acknowledge Pulse The device address is a 7-bit value that is configured during Field Programming. By programming different device addresses, two or more parts are connected to the serial interface and can be independently controlled. The device address is combined with a read/write bit as the LSB and is sent after each start bit. The default serial interface address is 69H, but must there be a conflict with any other devices in your system, this can also be changed using CyClocksRT. Document Number: 38-07186 Rev. *L Page 11 of 25 CY22393/CY223931 CY22394 CY22395 Write Operations Writing Individual Bytes A valid write operation must have a full 8-bit register address after the device address word from the master, which is followed by an acknowledge bit from the slave (ack = 0/LOW). The next eight bits must contain the data word intended for storage. After the data word is received, the slave responds with another acknowledge bit (ack = 0/LOW), and the master must end the write sequence with a STOP condition. Writing Multiple Bytes To write multiple bytes at a time, the master must not end the write sequence with a STOP condition. Instead, the master sends multiple contiguous bytes of data to be stored. After each byte, the slave responds with an acknowledge bit, the same as after the first byte, and accepts data until the STOP condition responds to the acknowledge bit. When receiving multiple bytes, the CY22393, CY223931, CY22394, and CY22395 internally increment the register address. Read Operations Read operations are initiated the same way as Write operations except that the R/W bit of the slave address is set to ‘1’ (HIGH). There are three basic read operations: current address read, random read, and sequential read. Current Address Read Random Read Through random read operations, the master may access any memory location. To perform this type of read operation, first set the word address. Do this by sending the address to the CY22393, CY22394 and CY22395 as part of a write operation. After the word address is sent, the master generates a START condition following the acknowledge. This terminates the write operation before any data is stored in the address, but not before setting the internal address pointer. Next, the master reissues the control byte with the R/W byte set to ‘1’. The CY22393, CY22394 and CY22395 then issue an acknowledge and transmit the 8-bit word. The master device does not acknowledge the transfer, but generates a STOP condition which causes the CY22393, CY22394 and CY22395 to stop transmission. Sequential Read Sequential read operations follow the same process as random reads except that the master issues an acknowledge instead of a STOP condition after transmitting the first 8-bit data word. This action increments the internal address pointer, and subsequently outputs the next 8-bit data word. By continuing to issue acknowledges instead of STOP conditions, the master serially reads the entire contents of the slave device memory. Note that register addresses outside of 08H to 1BH and 40H to 57H can be read from but are not real registers and do not contain configuration information. When the internal address pointer points to the FFH register, after the next increment, the pointer points to the 00H register. The CY22393, CY22394 and CY22395 have an onboard address counter that retains “1” more than the address of the last word access. If the last word written or read was word ‘n’, then a current address read operation returns the value stored in location ‘n+1’. When the CY22393, CY22394 and CY22395 receive the slave address with the R/W bit set to a ‘1’, they issue an acknowledge and transmit the 8-bit word. The master device does not acknowledge the transfer, but generates a STOP condition, which causes the CY22393, CY22394 and CY22395 to stop transmission. Document Number: 38-07186 Rev. *L Page 12 of 25 CY22393/CY223931 CY22394 CY22395 Figure 2. Data Frame Architecture SDAT Write Multiple Contiguous Registers 1 Bit 1 Bit Slave R/W = 0 ACK 7-bit Device Address 1 Bit Slave ACK 8-bit Register Address (XXH) 1 Bit Slave ACK 8-bit Register Data (XXH) 1 Bit Slave ACK 8-bit Register Data (XXH+1) 1 Bit Slave ACK 8-bit Register Data (XXH+2) 1 Bit Slave ACK 8-bit Register Data (FFH) 1 Bit Slave ACK 8-bit Register Data (00H) Stop Signal Start Signal SDAT Read Current Address Read Start Signal SDAT Read Multiple Contiguous Registers 1 Bit Slave ACK 1 Bit 1 Bit Slave R/W = 1 ACK 7-bit Device Address 1 Bit Slave ACK 1 Bit Master NACK 8-bit Register Data Stop Signal 1 Bit 1 Bit Slave R/W = 0 ACK 7-bit Device Address 1 Bit Slave ACK 8-bit Register Address (XXH) 1 Bit Master ACK 7-bit Device Address +R/W=1 8-bit Register Data (XXH) 1 Bit Master ACK 1 Bit Master ACK 8-bit Register Data (XXH+1) 8-bit Register Data (FFH) 1 Bit Master ACK 1 Bit Master ACK 1 Bit Master NACK 8-bit Register Data (00H) Stop Signal Start Signal Repeated Start bit Figure 3. Data Valid and Data Transition Periods Data Valid Transition to next Bit SDAT tSU:DAT tHD:DAT tHIGH VIH SCLK Document Number: 38-07186 Rev. *L VIL tLOW Page 13 of 25 CY22393/CY223931 CY22394 CY22395 Serial Programming Interface Timing Figure 4. Start and Stop Frame SDAT SCLK Transition to next Bit START STOP Figure 5. Frame Format (Device Address, R/W, Register Address, Register Data) SDAT + START DA6 DA5 DA0 + R/W ACK RA7 RA6 RA1 RA0 ACK D7 D6 + + SCLK + D1 D0 ACK STOP + Figure 6. Definition for Timing on the Serial BUS SDAT tf tLOW tr tSU;DAT tf tHD;STA tr tBUF SCLK S tHD;STA tHD;DAT tHIGH tSU;STA tSU;STO Sr P S Serial Programming Interface Timing Specifications Parameter Description Min Max Unit fSCLK Frequency of SCLK – 400 kHz tHD:STA Hold time START condition 0.6 – s tLOW Low period of the SCLK clock 1.3 – s tHIGH High period of the SCLK clock 0.6 – s tSU:STA Setup time for a repeated START condition 0.6 – s tHD:DAT Data hold time 100 – ns tSU:DAT Data setup time 100 – ns tR Rise time – 300 ns tF Fall time – 300 ns tSU:STO Setup time for STOP condition 0.6 – s tBUF Bus-free time between STOP and START conditions 1.3 – s Document Number: 38-07186 Rev. *L Page 14 of 25 CY22393/CY223931 CY22394 CY22395 Absolute Maximum Conditions Package power dissipation ...................................... 350 mW Supply voltage .............................................–0.5 V to +7.0 V Static discharge voltage (per MIL-STD-883, Method 3015) ......................... > 2000 V DC input voltage ......................... –0.5 V to + (AVDD + 0.5 V) Latch up (per JEDEC 17) ................................... > ±200 mA Storage temperature ................................ –65 °C to +125 °C Stresses exceeding absolute maximum conditions may cause permanent damage to the device. These conditions are stress ratings only. Functional operation of the device at these or any other conditions beyond those indicated in the operation sections of this data sheet is not implied. Extended exposure to Absolute Maximum Conditions may affect reliability. Junction temperature ................................................. 125 °C Data retention at Tj = 125 °C ................................> 10 years Maximum programming cycles ....................................... 100 Operating Conditions Min Typ Max Unit VDD/AVDD/LVDD Parameter Supply voltage Description All Part Numbers 3.135 3.3 3.465 V LVDD 2.5 V output supply voltage CY22395 2.375 2.5 2.625 V TA Commercial operating temperature, Ambient All 0 – +70 C –40 – +85 C All – – 15 pF 8 – 30 MHz 1 – 166 MHz 1 – 150 MHz Min Typ Max Unit Industrial operating temperature, All Ambient CLOAD_OUT Maximum load capacitance fREF External reference crystal All External reference clock,[2] Commercial All clock,[2] All External reference Industrial Recommended Crystal Specifications Parameter Description Conditions FNOM Nominal crystal frequency Parallel resonance, fundamental mode 8 – 30 MHz CLNOM Nominal load capacitance – 8 – 20 pF R1 Equivalent series resistance (ESR) Fundamental mode – – 50 DL Crystal drive level No external series resistor assumed – 0.5 2 mW Note 2. External input reference clock must have a duty cycle between 40% and 60%, measured at VDD/2. Document Number: 38-07186 Rev. *L Page 15 of 25 CY22393/CY223931 CY22394 CY22395 3.3 V Electrical Characteristics Parameter IOH Description Conditions[3] Min Typ Max Unit current[4] VOH = (L)VDD – 0.5, (L)VDD = 3.3 V 12 24 – mA Output high current[4] IOL Output low VOL = 0.5, (L)VDD = 3.3 V 12 24 – mA CXTAL_MIN Crystal load capacitance[4] Capload at minimum setting – 6 – pF CXTAL_MAX Crystal load capacitance[5] Capload at maximum setting – 30 – pF CIN Input pin capacitance[4] Except crystal pins – 7 – pF VIH High-level input voltage CMOS levels,% of AVDD 70% – – AVDD VIL Low-level input voltage CMOS levels,% of AVDD – – 30% AVDD IIH Input high current VIN = AVDD – 0.3 V – <1 10 A IIL Input low current VIN = +0.3 V – <1 10 A IOZ Output leakage current Three-state outputs – 10 A IDD Total power supply current 3.3-V power supply; 2 outputs at 20 MHz; 4 outputs at 40 MHz – 50 – mA 3.3-V power supply; 2 outputs at 166 MHz; 4 outputs at 83 MHz – 100 – mA Shutdown active – 5 20 A IDDS Total power supply current in shutdown mode 2.5 V Electrical Characteristics (CY22395 only)[6] Parameter IOH_2.5 IOL_2.5 Description Output high current[4] Output low current[4] Min Typ Max Unit VOH = LVDD – 0.5, LVDD = 2.5 V Conditions 8 16 – mA VOL = 0.5, LVDD = 2.5 V 8 16 – mA Thermal Resistance Parameter [7] Description θJA Thermal resistance (junction to ambient) θJC Thermal resistance (junction to case) Test Conditions Test conditions follow standard test methods and procedures for measuring thermal impedance, in accordance with EIA/JESD51. 16-pin TSSOP Unit 90 °C/W 14 °C/W Notes 3. Unless otherwise noted, Electrical and Switching Characteristics are guaranteed across these operating conditions. 4. Guaranteed by design, not 100% tested. 5. External input reference clock must have a duty cycle between 40% and 60%, measured at VDD/2. 6. VDDL is only specified and characterized at 3.3 V ± 5% and 2.5 V ± 5%. VDDL may be powered at any value between 3.465 and 2.375. 7. These parameters are guaranteed by design and are not tested. Document Number: 38-07186 Rev. *L Page 16 of 25 CY22393/CY223931 CY22394 CY22395 3.3 V Switching Characteristics Parameter 1/t1 Description Output frequency[8, 9] Output duty cycle[8, 10] t2 Min Typ Max Unit Clock output limit, CMOS, Commercial Conditions – – 200 MHz Clock output limit, CMOS, Industrial – – 166 MHz Clock output limit, PECL, Commercial (CY22394 only) 100 – 400 MHz Clock output limit, PECL, Industrial (CY22394 only) 125 – 375 MHz Duty cycle for outputs, defined as t2 t1, Fout < 100 MHz, divider >= 2, measured at VDD/2 45% 50% 55% Duty cycle for outputs, defined as t2 t1, Fout > 100 MHz or divider = 1, measured at VDD/2 40% 50% 60% t3 Rising edge slew rate[8] Output clock rise time, 20% to 80% of VDD 0.75 1.4 – V/ns t4 Falling edge slew rate[8] Output clock fall time, 20% to 80% of VDD 0.75 1.4 – V/ns t5 Output three-state timing[8] Time for output to enter or leave three-state mode after SHUTDOWN/OE switches – 150 300 ns t6 Clock jitter[8, 11] Peak-to-peak period jitter, CLK outputs measured at VDD/2 – 400 – ps v7 P+/P– crossing point[8] Crossing point referenced to Vdd/2, balanced resistor network (CY22394 only) –0.2 0 0.2 V t8 P+/P– jitter[8, 11] Peak-to-peak period jitter, P+/P– outputs measured at crossing point (CY22394 only) – 200 – ps t9 Lock time[8] PLL Lock Time from Power up – 1.0 3 ms Min Typ Max Unit – – 133 MHz 40% 50% 60% 2.5 V Switching Characteristics (CY22395 only)[12] Parameter Description Conditions 1/t1_2.5 Output frequency[8, 9] Clock output limit, LVCMOS t2_2.5 Output duty cycle[8, 10] Duty cycle for outputs, defined as t2 t1 measured at LVDD/2 t3_2.5 Rising edge slew rate[8] Output clock rise time, 20% to 80% of LVDD 0.5 1.0 – V/ns t4_2.5 Falling edge slew rate[8] Output clock fall time, 20% to 80% of LVDD 0.5 1.0 – V/ns Notes 8. Guaranteed by design, not 100% tested. 9. Guaranteed to meet 20%–80% output thresholds, duty cycle, and crossing point specifications. 10. Reference Output duty cycle depends on XTALIN duty cycle. 11. Jitter varies significantly with configuration. Reference Output jitter depends on XTALIN jitter and edge rate. 12. VDDL is only specified and characterized at 3.3 V ± 5% and 2.5 V ± 5%. VDDL may be powered at any value between 3.465 and 2.375. Document Number: 38-07186 Rev. *L Page 17 of 25 CY22393/CY223931 CY22394 CY22395 Switching Waveforms Figure 7. All Outputs, Duty Cycle and Rise and Fall Time t1 t2 OUTPUT t3 t4 Figure 8. Output Tristate Timing OE t5 t5 ALL TRISTATE OUTPUTS Figure 9. CLK Output Jitter t6 CLK OUTPUT Figure 10. P+/P– Crossing Point and Jitter t8 P– v7 VDD/2 P+ Figure 11. CPU Frequency Change SELECT OLD SELECT Fold NEW SELECT STABLE t9 Fnew CPU Document Number: 38-07186 Rev. *L Page 18 of 25 CY22393/CY223931 CY22394 CY22395 Test Circuit Figure 12. Test Circuit AV DD CLK out C LOAD 0.1 F (L)V V DD P+/P- out DD 0.1 F GND Document Number: 38-07186 Rev. *L Page 19 of 25 CY22393/CY223931 CY22394 CY22395 Ordering Information Ordering Code Package Type Product Flow Pb-free CY22393FXC 16-pin TSSOP Commercial, 0 °C to 70 °C CY22393FXCT 16-pin TSSOP - Tape and Reel Commercial, 0 °C to 70 °C CY22393FXI 16-pin TSSOP Industrial, –40 °C to 85 °C CY22393FXIT 16-pin TSSOP - Tape and Reel Industrial, –40 °C to 85 °C CY223931FXI 16-pin TSSOP with NiPdAu lead finish Industrial, –40 °C to 85 °C CY22394FXC 16-pin TSSOP Commercial, 0 °C to 70 °C CY22394FXCT 16-pin TSSOP - Tape and Reel Commercial, 0 °C to 70 °C CY22394FXI 16-pin TSSOP Industrial, –40 °C to 85 °C CY22394FXIT 16-pin TSSOP - Tape and Reel Industrial, –40 °C to 85 °C CY22395FXC 16-pin TSSOP Commercial, 0 °C to 70 °C CY22395FXCT 16-pin TSSOP - Tape and Reel Commercial, 0 °C to 70 °C CY22395FXI 16-pin TSSOP Industrial, –40 °C to 85 °C CY22395FXIT 16-pin TSSOP - Tape and Reel Industrial, –40 °C to 85 °C Programmer CY3672-USB Programmer CY3698 CY22392F, CY22393F, CY22394F, and CY22395F Adapter for CY3672-USB Possible Configurations Some product offerings are factory programmed customer specific devices with customized part numbers. The Possible Configurations table shows the available device types, but not complete part numbers. Contact your local Cypress FAE or sales representative for more information. Ordering Code Package Type Product Flow Pb-free CY22393ZXC-xxx 16-pin TSSOP Commercial, 0 °C to 70 °C CY22393ZXC-xxxT 16-pin TSSOP - Tape and Reel Commercial, 0 °C to 70 °C CY22393ZXI-xxx 16-pin TSSOP Industrial, –40 °C to 85 °C CY22393ZXI-xxxT 16-pin TSSOP - Tape and Reel Industrial, –40 °C to 85 °C CY22394ZXC-xxx 16-pin TSSOP Commercial, 0 °C to 70 °C CY22394ZXC-xxxT 16-pin TSSOP - Tape and Reel Commercial, 0 °C to 70 °C CY22394ZXI-xxx 16-pin TSSOP Industrial, –40 °C to 85 °C CY22394ZXI-xxxT 16-pin TSSOP - Tape and Reel Industrial, –40 °C to 85 °C CY22395ZXC-xxx 16-pin TSSOP Commercial, 0 °C to 70 °C CY22395ZXC-xxxT 16-pin TSSOP - Tape and Reel Commercial, 0 °C to 70 °C CY22395ZXI-xxx 16-pin TSSOP Industrial, –40 °C to 85 °C CY22395ZXI-xxxT 16-pin TSSOP - Tape and Reel Industrial, –40 °C to 85 °C Document Number: 38-07186 Rev. *L Page 20 of 25 CY22393/CY223931 CY22394 CY22395 Ordering Code Definitions CY 22393 (1) (F) ZX C (-xxx) (T) T = tape and reel, blank = tube Configuration specific identifier (factory programmed) Temperature Range: C = Commercial, I = Industrial Package: ZX = TSSOP, Pb-free (factory programmed) X = TSSOP, Pb-free (field programmable) F = field programmable, blank = factory programmed Lead finish:1 = NiPdAu, blank = unspecified Part Identifier: CY22393: 3.3 V CMOS clock generator CY22394: CMOS and LVPECL clock generator CY22395: 3.3 V/2.5 V CMOS clock generator Company Code: CY = Cypress Semiconductor Document Number: 38-07186 Rev. *L Page 21 of 25 CY22393/CY223931 CY22394 CY22395 Package Diagram Figure 13. 16-Pin TSSOP 4.40 mm Body Z16.173 51-85091 *E Document Number: 38-07186 Rev. *L Page 22 of 25 CY22393/CY223931 CY22394 CY22395 Acronyms Acronym Document Conventions Description Units of Measure CMOS complementary metal oxide semiconductor ESR equivalent series resistance °C degree Celsius FAE field application engineer MHz megahertz FET field effect transistor A microampere LVCMOS low voltage complementary metal oxide semiconductor F microfarad mA milliampere LVPECL low voltage positive emitter coupled logic mm millimeter LVTTL low voltage transistor-transistor logic ms millisecond MPEG motion picture experts group mW milliwatt OE output enable ns nanosecond PECL positive emitter coupled logic ppm parts per million PLL phase-locked loop TSSOP thin shrink small outline package Document Number: 38-07186 Rev. *L Symbol Unit of Measure pF picofarad ps picosecond V volt Page 23 of 25 CY22393/CY223931 CY22394 CY22395 Document History Page Document Title: CY22393/CY223931/CY22394/CY22395, Three-PLL Serial-Programmable Flash-Programmable Clock Generator Document Number: 38-07186 Rev. ECN Orig. of Change Submission Date Description of Change ** 111984 DSG 12/09/2001 Change from Spec number: 38-01144 to 38-07186 *A 129388 RGL 10/13/2003 Added timing information *B 237755 RGL See ECN Added Lead-Free Devices *C 848580 RGL See ECN Added references to I2C; removed all references to SPI *D 2584052 AESA / KVM 10/10/2008 Updated template. Added Note “Not recommended for new designs.” Added part number CY22393FC, and CY22393FCT in Ordering Information table. Removed part number CY22393FI, CY22393FIT, CY22393ZI-XXX, CY22393ZI-XXXT, CY22393FC, CY22393FCT, CY22392FI, CY22392FIT, CY22394ZC-XXX, CY22394ZC-XXXT, CY22394ZI-XXX, CY22394ZI-XXXT, CY22394FI, CY22394FIT, CY22395ZC-XXX, CY22395ZC-XXXT, CY22395ZI-XXX, CY22395ZI-XXXT, CY22395FC, CY22395FCT, and CY22395FI in Ordering Information table. Changed Lead-Free to Pb-Free. Changed serial interface hold time (TDH) from 0ns to 100ns. Replaced I2C references with “2-wire serial interface” *E 2634202 KVM / AESA 01/09/2009 Changed title to include CY223931. Added CY223931 to page 1 features list. Added part number CY223931FXI. Added CY22393_I to the Selector Guide (p.2), and changed the format of the part numbers. Added overbar to SUSPEND in Pin Definitions table *F 2748211 TSAI 08/10/2009 Posting to external web. *G 2897775 KVM 03/23/2010 Removed inactive parts. Moved xxx part numbers to Possible Configurations table. *H 3048452 BASH 10/05/2010 Added table of contents, crystal parameter table, ordering code definition, acronym and units tables. Added section Crystal Drive Level and Power. Removed FTG from CY3672. Updated Package Diagram. Removed Benefits from page 1. Updated Figure 1 on page 5. *I 3562729 PURU 03/27/2012 Updated Package Diagram. *J 4576237 PURU 11/21/2014 Updated Functional Description: Added “For a complete list of related documentation, click here.” at the end. Updated Serial Bus Programming Protocol and Timing: Updated Figure 2 (Updated last ACK in SDAT Read-Current Address Read and SDAT Read-Multiple Contiguous Registers to “NACK”). Updated Package Diagram: spec 51-85091 – Changed revision from *D to *E. *K 4669878 XHT 02/25/2015 Updated Serial Bus Programming Protocol and Timing: Removed Figure 2 “Data Transfer Sequence on the Serial Bus”. Updated Serial Programming Interface Timing: Added Figure 6. Updated Serial Programming Interface Timing Specifications: Updated details in “Parameter” and “Description” columns. *L 5274688 PSR 05/17/2016 Updated Functional Overview: Updated General Purpose Inputs: Updated description. Added Thermal Resistance. Updated to new template. Document Number: 38-07186 Rev. *L Page 24 of 25 CY22393/CY223931 CY22394 CY22395 Sales, Solutions, and Legal Information Worldwide Sales and Design Support Cypress maintains a worldwide network of offices, solution centers, manufacturer’s representatives, and distributors. To find the office closest to you, visit us at Cypress Locations. PSoC®Solutions Products ARM® Cortex® Microcontrollers Automotive cypress.com/arm cypress.com/automotive Clocks & Buffers cypress.com/clocks Interface Lighting & Power Control cypress.com/interface cypress.com/powerpsoc Memory PSoC Touch Sensing USB Controllers Wireless/RF cypress.com/memory PSoC 1 | PSoC 3 | PSoC 4 | PSoC 5LP Cypress Developer Community Forums | Projects | Video | Blogs | Training | Components Technical Support cypress.com/support cypress.com/psoc cypress.com/touch cypress.com/usb cypress.com/wireless © Cypress Semiconductor Corporation, 2001-2016. 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You shall indemnify and hold Cypress harmless from and against all claims, costs, damages, and other liabilities, including claims for personal injury or death, arising from or related to any Unintended Uses of Cypress products. Cypress, the Cypress logo, Spansion, the Spansion logo, and combinations thereof, PSoC, CapSense, EZ-USB, F-RAM, and Traveo are trademarks or registered trademarks of Cypress in the United States and other countries. For a more complete list of Cypress trademarks, visit cypress.com. Other names and brands may be claimed as property of their respective owners. Document Number: 38-07186 Rev. *L CyClocksRT is a trademark of Cypress Semiconductor. Revised May 17, 2016 Page 25 of 25