CMT2150A-ESR

CMT2150A CMT2150A 240 – 480 MHz OOK Stand-Alone Transmitter with Encoder Features Applications   Low-Cost Consumer Electronics Applications  Very Easy Development with RFPDK  Home and Building Automation  All Features Programmable  Remote Fan Controllers Embedded EEPROM  Frequency Range: 240 to 480 MHz  Infrared Transmitter Replacements  Symbol Rate: 0.5 to 40 ksps  Industrial Monitoring and Controls  Output Power: -10 to +13 dBm  Remote Lighting Control  Current Consumption: 8.5 mA @ +10 dBm  Wireless Alarm and Security Systems  Sleep Current: < 20 nA  Remote Keyless Entry (RKE)  Stand-Alone, No External MCU Control Required  Embedded 1920, 1527 and 2262 Data Encoder  Up to 7 Configurable Data Pins for Push Buttons  LED Indicator for Low Battery Detection and Transmission  Sync ID Auto-Study with CMOSTEK Receiver  FCC / ETSI Compliant  RoHS Compliant CMT2150A-ESR 433.92 MHz T&R 2,500 pcs  14-pin SOP Package CMT2150A-ESB 433.92 MHz Tube 1,000 pcs Ordering Information Package Part Number MOQ Frequency Option More Ordering Info: See Page 26 Descriptions The CMT2150A is a true single-chip, highly flexible, high performance, OOK RF transmitter with embedded data encoder ideal for 240 to 480 MHz wireless applications. The device integrates a data encoder that is not only compatible with the most common used encoding format of 1527 and 2262, but also a more efficient, flexible and powerful format of 1920 designed by CMOSTEK. Up to 7 configurable push buttons are supported in multiple button SOP14 modes. When pairing the device to CMOSTEK receiver, the synchronization ID can be programmed into both of the transmitter and receiver during the manufacturing phase, or studied by the receiver from the transmitter remotely by LED 1 14 XTAL end customers. An embedded EEPROM allows the RF and VDD 2 13 CLK GND 3 12 DATA Alternatively, in stock product of 433.92 MHz is available RFO 4 11 K1 for immediate demands without the need of EEPROM K7 5 10 K2 K6 6 9 K3 K5 7 8 K4 encoder parameters to be programmed into the chip using the CMOSTEK USB Programmer and the RFPDK. programming. The CMT2150A is part of the CMOSTEK NextGenRFTM family, together with CMT225x series receivers, they enable ultra low cost, low power consumption RF links. Copyright © By CMOSTEK CMT2150A Rev 0.8 | Page 1/31 www.hoperf.com CMT2150A Typical Application CMT2150A X1 D1 VDD 1 ANT XTAL LED 2 L1 L2 C2 C0 C1 3 4 SW7 5 SW6 6 SW5 7 VDD CLK GND DATA RFO U1 K1 K7 K2 K6 K3 K5 K4 14 J1 1 VDD 13 CLK 12 DATA CLK 2 DATA 11 SW1 3 10 SW2 4 9 SW3 8 SW4 Note: Connector J1 is for EEPROM Programming Figure 1. CMT2150A Typical Application Schematic Table 1. BOM of 315/433.92 MHz Typical Application Value Designator Unit Manufacturer - - CMOSTEK 26 MHz EPSON Descriptions 315 MHz U1 CMT2150A, 240 – 480 MHz OOK stand-alone transmitter with encoder 433.92 MHz X1 ±20 ppm, SMD32*25 mm crystal C0 ±20%, 0402 X7R, 25 V uF Murata GRM15 C1 ±5%, 0402 NP0, 50 V 82 82 pF Murata GRM15 C2 ±5%, 0402 NP0, 50 V 9.1 9.1 pF Murata GRM15 L1 ±5%, 0603 multi-layer chip inductor 180 180 nH Murata LQG18 L2 ±5%, 0603 multi-layer chip inductor 39 22 nH Murata LQG18 D1 D0603, red LED - - - Push buttons - - - SW[7:1] 0.1 Rev 0.8 | Page 2/31 www.hoperf.com CMT2150A Abbreviations Abbreviations used in this data sheet are described below AN Application Notes OOK On-Off Keying BOM Bill of Materials PA Power Amplifier BSC Basic Spacing between Centers PC Personal Computer BW Bandwidth PCB Printed Circuit Board DC Direct Current PLL Phase Lock Loop EEPROM Electrically Erasable Programmable Read-Only PN Phase Noise Memory RBW Resolution Bandwidth ESD Electro-Static Discharge RCLK Reference Clock ESR Equivalent Series Resistance RF Radio Frequency GUI Graphical User Interface RFPDK RF Product Development Kit IC Integrated Circuit RoHS Restriction of Hazardous Substances LDO Low Drop-Out Rx Receiving, Receiver Max Maximum SOT Small-Outline Transistor MCU Microcontroller Unit TBD To Be Determined Min Minimum Tx Transmission, Transmitter MOQ Minimum Order Quantity Typ Typical NP0 Negative-Positive-Zero XO/XOSC Crystal Oscillator OBW Occupied Bandwidth XTAL Crystal Rev 0.8 | Page 3/31 www.hoperf.com CMT2150A Table of Contents 1. Electrical Characteristics ............................................................................................................................................ 5 1.1 Recommended Operating Conditions ................................................................................................................... 5 1.2 Absolute Maximum Ratings................................................................................................................................... 5 1.3 Transmitter Specifications ..................................................................................................................................... 6 1.4 Crystal Oscillator ................................................................................................................................................... 7 2. Pin Descriptions .......................................................................................................................................................... 8 3. Typical Performance Characteristics ......................................................................................................................... 9 4. Typical Application Schematics ............................................................................................................................... 10 4.1 Low-Cost Application Schematic ......................................................................................................................... 10 4.2 FCC/ETSI Compliant Application Schematic....................................................................................................... 11 5. Functional Descriptions ............................................................................................................................................ 12 5.1 Overview ............................................................................................................................................................. 12 5.2 Modulation, Frequency and Symbol Rate ........................................................................................................... 12 5.3 Embedded EEPROM and RFPDK ...................................................................................................................... 13 5.4 Power Amplifier ................................................................................................................................................... 15 5.5 PA Ramping ........................................................................................................................................................ 15 5.6 Working States .................................................................................................................................................... 16 5.7 The Encoder........................................................................................................................................................ 17 5.7.1 1920 Packet Structure............................................................................................................................................17 5.7.2 1527 Packet Structure............................................................................................................................................18 5.7.3 2262 Packet Structure............................................................................................................................................19 5.8 ID Study .............................................................................................................................................................. 20 5.9 Button Modes ...................................................................................................................................................... 20 5.9.1 Normal ......................................................................................................................................................................20 5.9.2 Matrix ........................................................................................................................................................................21 5.9.3 Toggle .......................................................................................................................................................................22 5.9.4 PWM .........................................................................................................................................................................23 5.10 LED Driving Capability ........................................................................................................................................ 24 5.11 Low Battery Detection (LBD) ............................................................................................................................... 24 5.12 Crystal Oscillator and RCLK................................................................................................................................ 24 6. Ordering Information ................................................................................................................................................. 26 7. Package Outline......................................................................................................................................................... 27 8. Top Marking ............................................................................................................................................................... 28 8.1 CMT2150A Top Marking ..................................................................................................................................... 28 9. Other Documentations .............................................................................................................................................. 29 10. Document Change List.............................................................................................................................................. 30 11. Contact Information .................................................................................................................................................. 31 Rev 0.8 | Page 4/31 www.hoperf.com CMT2150A 1. Electrical Characteristics VDD = 3.3 V, TOP = 25 ℃, FRF = 433.92 MHz, output power is +10 dBm terminated in a matched 50 Ω impedance, unless otherwise noted. 1.1 Recommended Operating Conditions Table 2. Recommended Operation Conditions Parameter Symbol Conditions Min Typ Max Unit Operation Voltage Supply VDD 1.8 3.6 V Operation Temperature TOP -40 85 ℃ Supply Voltage Slew Rate 1 mV/us 1.2 Absolute Maximum Ratings Table 3. Absolute Maximum Ratings Parameter Symbol Conditions [1] Min Max Unit Supply Voltage VDD -0.3 3.6 V Interface Voltage VIN -0.3 VDD + 0.3 V Junction Temperature TJ -40 125 ℃ Storage Temperature TSTG -50 150 ℃ Soldering Temperature TSDR 255 ℃ Lasts at least 30 seconds ESD Rating Human Body Model (HBM) Latch-up Current @ 85 ℃ -2 2 kV -100 100 mA Note: [1]. Stresses above those listed as “absolute maximum ratings” may cause permanent damage to the device. This is a stress rating only and functional operation of the device under these conditions is not implied. Exposure to maximum rating conditions for extended periods may affect device reliability. Caution! ESD sensitive device. Precaution should be used when handling the device in order to prevent permanent damage. Rev 0.8 | Page 5/31 www.hoperf.com CMT2150A 1.3 Transmitter Specifications Table 4. Transmitter Specifications Parameter [1] Frequency Range Synthesizer Frequency Symbol Conditions FRF Min Typ 240 Max Unit 480 MHz FRES 198 Hz Maximum Output Power POUT(Max) +13 dBm Minimum Output Power POUT(Min) -10 dBm Output Power Step Size PSTEP 1 dB Resolution [2] PA Ramping Time Current Consumption[3] @ 315 MHz Current Consumption [3] @ 433.92 MHz tRAMP IDD-315 IDD-433.92 ISLEEP Symbol Rate SR Phase Noise Harmonics Output for 315 [4] MHz tTUNE PN H2315 H3315 Harmonics Output for [4] 433.92 MHz H2433.92 H3433.92 315 MHz Occupied Bandwidth @ 433.92 MHz FOBW315 FOBW433.92 us 5.9 mA +10 dBm 8.1 mA +13 dBm 8.8 mA 6 mA +10 dBm 8.5 mA +13 dBm 10.2 mA 20 nA 0.5 From XO stable to ready to transmit, 40 ksps 370 us 100 kHz offset from FRF -80 dBc/Hz 200 kHz offset from FRF -81 dBc/Hz 400 kHz offset from FRF -91 dBc/Hz 600 kHz offset from FRF -96 dBc/Hz 1.2 MHz offset from FRF -108 dBc/Hz harm @ 630 MHz, +13 dBm POUT -60 dBm 3 harm @ 945 MHz, +13 dBm POUT -65 dBm -52 dBm -57 dBm 60 dB 6 kHz 7 kHz include the frequency calibration nd 2 rd nd 2 harm @ 867.84 MHz, +13 dBm POUT rd 3 harm @ 1301.76 MHz, +13 dBm POUT OOK Extinction Ration Occupied Bandwidth @ 1024 0 dBm 0 dBm, Sleep Current Frequency Tune Time 0 Measured @ -20 dBc, RBW = 1 kHz, SR = 1.2 ksps, tRAMP = 256 us Measured @ -20 dBc, RBW = 1 kHz, SR = 1.2 ksps, tRAMP = 256 us Notes: [1]. The frequency range is continuous over the specified range. [2]. 0 and 2n us, n = 0 to 10, when set to “0”, the PA output power will ramp to its configured value in the shortest possible time. [3]. The working currents are tested with: 1527 packet format/Normal button mode/ 4 push buttons/Sync ID = 0/No LED. [4]. The harmonics output is measured with the application shown as Figure 10. Rev 0.8 | Page 6/31 www.hoperf.com CMT2150A 1.4 Crystal Oscillator Table 5. Crystal Oscillator Specifications Parameter [1] Crystal Frequency Symbol Conditions FXTAL Min 26 Crystal Tolerance[2] [3] Load Capacitance Crystal ESR Typ Max Unit 26 26 MHz ±20 CLOAD 12 Rm [4] XTAL Startup Time tXTAL ppm 20 pF 60 Ω 400 us Notes: [1]. The CMT2150A can directly work with external 26 MHz reference clock input to XTAL pin (a coupling capacitor is required) with amplitude 0.3 to 0.7 Vpp. [2]. This is the total tolerance including (1) initial tolerance, (2) crystal loading, (3) aging, and (4) temperature dependence. The acceptable crystal tolerance depends on RF frequency and channel spacing/bandwidth. [3]. The required crystal load capacitance is integrated on-chip to minimize the number of external components. [4]. This parameter is to a large degree crystal dependent. Rev 0.8 | Page 7/31 www.hoperf.com CMT2150A 2. Pin Descriptions LED 1 14 XTAL VDD 2 13 CLK GND 3 12 DATA RFO 4 11 K1 K7 5 10 K2 K6 6 9 K3 K5 7 8 K4 Figure 2. CMT2150A Pin Assignments Table 6. CMT2150A Pin Descriptions Pin Number Name I/O Descriptions 1 LED O LED driver, active low 2 VDD I Power supply input 3 GND I Ground 4 RFO O Power amplifier output 5 - 11 K[7:1] I Push button 7 to 1 12 DATA IO 13 CLK I 14 XTAL I Data pin to access the embedded EEPROM, internally pulled up to VDD Clock pin to access the embedded EEPROM, internally pulled up to VDD 26 MHz single-ended crystal oscillator input or External 26 MHz reference clock input Rev 0.8 | Page 8/31 www.hoperf.com CMT2150A 3. Typical Performance Characteristics Phase Noise Harmonics of 433.92 MHz 20 20 13.4dBm @ 433.92 MHz 13.6 dBm @ 433.92 MHz 10 0 0 Power (dBm) Power (dBm) -10 -10 -20 -30 3rd Harmonic -50 Power (dBm) 10 -20 -57 dBm @1301.76 MHz -60 -70 -80 -90 -30 1301.72 -56.8 dBm @ 435.12 MHz -50 1301.78 1301.81 -52.0 dBm @ 867.84 MHz -50 -40 1301.75 Freq (MHz) (RBW = 1 kHz) -40 -60 -70 -60 250 432.42 432.72 433.02 433.32 433.62 433.92 434.22 434.52 434.82 435.12 435.42 365 480 595 710 825 940 1055 1170 1285 Figure 3. Phase Noise, FRF = 433.92 MHz, Figure 4. Harmonics of 433.92 MHz, POUT = +13 dBm, RBW = 10 kHz, Un-encoded POUT = +13 dBm Spectrum of Various PA Ramping Options OOK Spectrum 10 20 10 128 us 64 us 32 us 16 us 8 us 4 us 0 0 Power (dBm) -10 Power (dBm) 1400 Frequency (MHz) (RBW = 10 kHz) Frequency (MHz) -10 -20 -30 -20 -30 -40 -40 -50 -50 -60 433.17 432.92 433.12 433.32 433.52 433.72 433.92 434.12 434.32 434.52 434.72 434.92 433.37 433.57 433.77 434.17 434.37 434.57 Figure 5. OOK Spectrum, Figure 6. Spectrum of PA Ramping, POUT = +10 dBm, tRAMP = 32 us SR = 9.6 ksps, POUT = +10 dBm Spectrum of Various PA Ramping Options POUT vs. VDD 10 16 -10 14 12 SR = 1.2 ksps Power (dBm) 1024 us 512 us 256 us 128 us 64 us 32 us 0 Power (dBm) 433.97 Frequency (MHz) Frequency (MHz) -20 10 8 13 dBm 6 10 dBm 4 -30 0 dBm 2 -40 0 -2 -50 433.17 433.37 433.57 433.77 433.97 434.17 Frequency (MHz) 434.37 434.57 1.6 1.8 2 2.2 2.4 2.6 2.8 3 3.2 3.4 3.6 3.8 Supply Voltage (V) Figure 8. Spectrum of PA Ramping, Figure 7. Output Power vs. Supply SR = 1.2 ksps, POUT = +10 dBm Voltages, FRF = 433.92 MHz Rev 0.8 | Page 9/31 www.hoperf.com CMT2150A 4. Typical Application Schematics 4.1 Low-Cost Application Schematic CMT2150A X1 D1 VDD 1 ANT 2 L1 L2 C2 C0 C1 3 4 SW7 5 SW6 6 SW5 7 VDD CLK GND DATA RFO 14 XTAL LED U1 K1 K7 K2 K6 K3 K5 K4 J1 1 VDD 13 CLK 12 DATA CLK 2 DATA 11 SW1 3 10 SW2 4 9 SW3 8 SW4 Note: Connector J1 is for EEPROM Programming Figure 9. Low-Cost Application Schematic Notes: 1. Connector J1 is a must for the CMT2150A EEPROM access during development or manufacture phase. 2. The general layout guidelines are listed below. For more design details, please refer to “AN111 CMT215x Schematic and PCB Layout Design Guideline”  Use as much continuous ground plane metallization as possible.  Use as many grounding vias (especially near to the GND pins) as possible to minimize series parasitic inductance between the ground pour and the GND pins. 3.  Avoid using long and/or thin transmission lines to connect the components.  Avoid placing the nearby inductors in the same orientation to reduce the coupling between them.  Place C0 as close to the CMT2150A as possible for better filtering. The table below shows the BOM of 315/433.92 MHz Low-Cost Application. For the BOM of more applications, please refer to “AN111 CMT215x Schematic and PCB Layout Design Guideline”. Table 7. BOM of 315/433.92 MHz Low-Cost Application Value Designator Unit Manufacturer - - CMOSTEK 26 MHz EPSON Descriptions 315 MHz U1 CMT2150A, 240 – 480 MHz OOK stand-alone transmitter with encoder 433.92 MHz X1 ±20 ppm, SMD32*25 mm crystal C0 ±20%, 0402 X7R, 25 V uF Murata GRM15 C1 ±5%, 0402 NP0, 50 V 82 82 pF Murata GRM15 C2 ±5%, 0402 NP0, 50 V 9.1 9.1 pF Murata GRM15 L1 ±5%, 0603 multi-layer chip inductor 180 180 nH Murata LQG18 L2 ±5%, 0603 multi-layer chip inductor 39 22 nH Murata LQG18 D1 D0603, red LED - - - Push buttons - - - SW[7:1] 0.1 Rev 0.8 | Page 10/31 www.hoperf.com CMT2150A 4.2 FCC/ETSI Compliant Application Schematic CMT2150A X1 D1 VDD 1 ANT 2 L1 L2 L3 C3 C0 3 C1 C2 4 SW7 5 SW6 6 SW5 7 LED XTAL VDD CLK GND DATA RFO U1 K1 K7 K2 K6 K3 K5 K4 J1 1 VDD 14 13 CLK CLK 12 DATA DATA 11 SW1 10 SW2 9 SW3 8 SW4 2 3 4 Note: Connector J1 is for EEPROM Programming Figure 10. FCC/ETSI Compliant Application Schematic Notes: 1. Connector J1 is a must for the CMT2150A EEPROM access during development or manufacture phase. 2. The general layout guidelines are listed below. For more design details, please refer to “AN111 CMT215x Schematic and PCB Layout Design Guideline”.  Use as much continuous ground plane metallization as possible.  Use as many grounding vias (especially near to the GND pins) as possible to minimize series parasitic inductance between the ground pour and the GND pins. 3.  Avoid using long and/or thin transmission lines to connect the components.  Avoid placing the nearby inductors in the same orientation to reduce the coupling between them.  Place C0 as close to the CMT2150A as possible for better filtering. The table below shows the BOM of 315/433.92 MHz FCC/ETSI Compliant Application. For the BOM of more application, please refer to “AN111 CMT215x Schematic and PCB Layout Design Guideline”. Table 8. BOM of 315/433.92 MHz FCC/ETSI Compliant Application Value Designator 315 MHz U1 Unit CMT2150A, 240 – 480 MHz OOK stand-alone 433.92 MHz - transmitter with encoder CMOSTEK X1 ±20 ppm, SMD32*25 mm crystal C0 ±20%, 0402 X7R, 25 V C1 ±5%, 0402 NP0, 50 V 68 68 C2 ±5%, 0402 NP0, 50 V 18 15 C3 ±5%, 0402 NP0, 50 V 15 L1 ±5%, 0603 multi-layer chip inductor 180 L2 ±5%, 0603 multi-layer chip inductor 51 L3 ±5%, 0603 multi-layer chip inductor 27 D1 D0603, red LED - Push buttons - SW[7:1] Manufacturer Descriptions 26 MHz EPSON uF Murata GRM15 pF Murata GRM15 pF Murata GRM15 15 pF Murata GRM15 180 nH Murata LQG18 36 nH Murata LQG18 18 nH Murata LQG18 - - - - 0.1 Rev 0.8 | Page 11/31 www.hoperf.com CMT2150A 5. Functional Descriptions VDD Bandgap POR LDOs GND XOSC XTAL LED Driver LED PA RFO VCO PFD/CP Loop Filter Frac-N DIV K[7:1] DATA CLK Encoder Modulator EEPROM Ramp-control Interface & Control Logics Figure 11. CMT2150A Functional Block Diagram 5.1 Overview The CMT2150A is a true single-chip, highly flexible, high performance, OOK RF transmitter with embedded data encoder ideal for 240 to 480 MHz wireless applications. It is part of the CMOSTEK NextGenRFTM family, which includes a complete line of transmitters, receivers and transceivers. The device integrates a data encoder that is not only compatible with the most common used encoding format of 1527 and 2262, but also a more efficient, flexible and powerful format of 1920 designed by CMOSTEK. Up to 7 configurable push buttons are supported in multiple button modes. The device is optimized for the low system cost, low power consumption, battery powered application with its highly integrated and low power design. The functional block diagram of the CMT2150A is shown in figure above. The CMT2150A is based on direct synthesis of the RF frequency by means of a fully integrated low-noise fractional-N frequency synthesizer. It uses a 1-pin crystal oscillator circuit with the required crystal load capacitance integrated on-chip to minimize the number of external components. Every analog block is calibrated on each Power-on Reset (POR) to an internal reference voltage source. The calibration can help the chip to finely work under different temperatures and supply voltages. The transmission is triggered by pressing the push button(s). The data is modulated and sent out by a highly efficient PA which output power can be configured from -10 to +13 dBm in 1 dB step size. RF Frequency, PA output power and other product features can be programmed into the embedded EEPROM by the RFPDK and USB Programmer. This saves the cost and simplifies the product development and manufacturing effort. Alternatively, in stock product of 433.92 MHz is available for immediate demands without the need of EEPROM programming. The CMT2150A operates from 1.8 to 3.6 V so that it can finely work with most batteries to their useful power limits. It only consumes 8.5 mA when transmitting +10 dBm power at 433.92 MHz under 3.3 V supply voltage. 5.2 Modulation, Frequency and Symbol Rate The CMT2150A supports OOK modulation with the symbol rate up to 40 ksps. It continuously covers the frequency range from 240 to 480 MHz, including the license free ISM frequency band around 315 MHz and 433.92 MHz. The device contains a high spectrum purity low power fractional-N frequency synthesizer with output frequency resolution better than 198 Hz. See Table 9 for the modulation, frequency and symbol rate specifications. Rev 0.8 | Page 12/31 www.hoperf.com CMT2150A Table 9. Modulation, Frequency and Symbol Rate Parameter Value Unit Modulation OOK - Frequency 240 to 480 MHz 198 Hz 0.5 to 40 ksps Frequency Resolution Symbol Rate 5.3 Embedded EEPROM and RFPDK The RFPDK (RF Products Development Kit) is a very user-friendly software tool delivered for the user configuring the CMT2150A in the most intuitional way. The user only needs to fill in/select the proper value of each parameter and click the “Burn” button to complete the chip configuration. No register access and control is required in the application program. See figure below for the accessing of the EEPROM and Table 10 for the summary of all the configurable parameters of the CMT2150A on the RFPDK. CMT2150A RFPDK EEPROM CLK Interface DATA CMOSTEK USB Programmer Figure 12. Accessing Embedded EEPROM For more details of the CMOSTEK USB Programmer and the RFPDK, please refer to “AN113 CMT2150A/2250(1)A One-Way RF Link Development Kits User’s Guide”. For the detail of CMT2150A configurations with the RFPDK, please refer to “AN112 CMT2150A Configuration Guideline”. Table 10. Configurable Parameters in RFPDK Category Parameters Descriptions Default To input a desired transmitting radio frequency in Frequency the range from 240 to 480 MHz. The step size is 433.92 MHz 0.001 MHz. To select a proper transmitting output power from Tx Power -10 dBm to +14 dBm, 1 dBm margin is given +13 dBm above +13 dBm. RF Settings Xtal Cload Symbol Rate PA Ramping LED Driving Capability On-chip XOSC load capacitance options: from 10 to 22 pF. To determines the symbol rate of the transmitted data: from 0.5 to 40 ksps. To control PA output power ramp up/down time, options are 0 and 2n us (n from 0 to 10). This defines the driving current of the LED pin. The options are: Disable, 5, 10, 15 or 20 mA. Rev 0.8 | Page 13/31 15.00 pF 4.8 Mode Basic Advanced Basic Advanced Basic Advanced Basic Advanced 0 us Advanced 5 mA Advanced www.hoperf.com CMT2150A Category Parameters LBD Threshold Descriptions Default Mode 2.4 V Advanced This defines the Low Battery Detection threshold. The options are: Disable, 1.7, 1.8, 1.9, 2.0, 2.1, 2.2, 2.3, 2.4, 2.5, 2.6, 2.7 or 2.8 V. Select the packet encoding format, the options Encoder are: 1920, 1527 and 2262. See Table 13, Table 14 and Table 15 for the configurable parameters in 1527 Basic Advanced each packet. This tells the device how many symbols are used to construct a single bit in the 1920 mode. The Bit Format options are: 3, 4, 5 or 6 sym/bit. The Bit Format is 3 fixed at 4 sym/bit in 1527 mode and 8 sym/bit in Encoder 2262 mode. It is only available in 1920 mode. Settings This defines the minimum number of packet(s) Number of Packets Basic Advanced being transmitted during each button pressing action. It also defines the number of packet(s) 1 Advanced being transmitted during each periodic transmission. The range is from 1 to 256. This defines the time interval amount two Packet consecutive transmitted packets. The unit is in 0 symbols of Basic Interval symbol, the range is from 0 to 255 symbols of zero Advanced zero. Select the button encoding mode, the options are: Normal, Matrix, Toggle and PWM. For 1920 and Button Mode 1527 format, all these button modes are Normal supported; For 2262 format, only Normal button Basic Advanced mode is supported. On/Off Button(s) Select the numbers of on/off button for Toggle and PWM button modes, the options are: Single or Single Separated. Basic Advanced This option is only available in Normal Button Push Button Number of Mode, and Encoder is set to 1920 and 1527. It Button(s) defines the number of activated button(s) to be 4 Basic Advanced used in the application. The range is from 1 to 7. Settings Data Inversion Periodic Transmission Allow the user to select whether or not to inverse the transmitted data bits values in the Normal and No Advanced Off Advanced 1.000 s Advanced Off Advanced Toggle Button Mode. The options are: No or Yes. Turn on/off the periodic transmission mode of the device. The options are: On or Off. This parameter is only available when Periodic Transmission is turned on. It defines the periodic Periodic Time time for transmitting a fixed set of data. The range is from 2 to 7683.512 s, accurate to 3 decimal points. It is only available when Periodic Transmission is on. Turn on/off the Sync ID study function, the options Study Settings ID Study are: On or Off. The ID Study is only supported in 1920 and 1527 mode. Rev 0.8 | Page 14/31 www.hoperf.com CMT2150A Category Parameters Descriptions Default Mode 5s Advanced Pin 11 (K1) Advanced This parameter is only available when ID Study is Study Trigger Time turned on. It defines the time from the instance of pressing the study button to the instance at which the device starts to transmit the study packets. The range is from 1 to 15 second(s). This parameter is only available when ID Study is turned on. It defines which button is used to trigger Study Button the transmission of the study packets. The options are the current buttons used in the Push Button Settings. This parameter is only available when ID Study is Study Power turned on. It defines the PA power when the device is transmitting the study packets. The -6 dBm Basic Advanced range is from –10 to +14 dBm. 5.4 Power Amplifier A highly efficient single-ended Power Amplifier (PA) is integrated in the CMT2150A to transmit the modulated signal out. Depending on the application, the user can design a matching network for the PA to exhibit optimum efficiency at the desired output power for a wide range of antennas, such as loop or monopole antenna. Typical application schematics and the required BOM are shown in “Chapter 4 Typical Application Schematic”. For the schematic, layout guideline and the other detailed information please refer to “AN111 CMT215x Schematic and PCB Layout Design Guideline”. The output power of the PA can be configured by the user within the range from -10 dBm to +13 dBm in 1 dB step size using the CMOSTEK USB Programmer and RFPDK. 5.5 PA Ramping When the PA is switched on or off quickly, its changing input impedance momentarily disturbs the VCO output frequency. This phenomenon is called VCO pulling, and it manifests as spectral splatter or spurs in the output spectrum around the desired carrier frequency. By gradually ramping the PA on and off, PA transient spurs are minimized. The CMT2150A has built-in PA ramping configurability with options of 0, 1, 2, 4, 8, 16, 32, 64, 128, 256, 512 and 1024 us, as shown in Figure 13. When the option is set to “0”, the PA output power will ramp up to its configured value in the shortest possible time. The ramp down time is identical to the ramp up time in the same configuration. CMOSTEK recommends that the maximum symbol rate should be no higher than 1/2 of the PA ramping “rate”, as shown in the formula below: SRMax ≤ 0.5 * ( 1 tRAMP ) In which the PA ramping “rate” is given by (1/tRAMP). In other words, by knowing the maximum symbol rate in the application, the PA ramping time can be calculated by: tRAMP ≤ 0.5 * ( 1 ) SRMAX The user can select one of the values of the tRAMP in the available options that meet the above requirement. If somehow the tRAMP is set to be longer than “0.5 * (1/SRMax)”, it will possibly bring additional challenges to the OOK demodulation of the Rx device. For more detail of calculating tRAMP, please refer to “AN112 CMT2150A Configuration Guideline”. Rev 0.8 | Page 15/31 www.hoperf.com RFO Amplitude CMT2150A 0 us 1 us 2 us 4 us 8 us 512 us 1024 us Data Time Logic 1 Logic 0 Time Figure 13. PA Ramping Time 5.6 Working States The CMT2150A has following 4 different working states: SLEEP, XO-STARTUP, TUNE and TRANSMIT. The device stays in the SLEEP state when no transmission is performed. Once the button(s) is/are pressed, the device goes through the sequence of SLEEP  XO-STARTUP  TUNE  TRANSMIT to transmit the data. After the transmission the device goes back to the SLEEP state. When the device works in the periodic transmission mode, the device periodically wakes up from the SLEEP state, goes the same sequence, performs the transmission and goes back to the SLEEP state. All the details of push button(s) function and periodic transmission can be referred to “AN112 CMT2150A Configuration Guideline”. SLEEP When the CMT2150A is in the SLEEP state, all the internal blocks are turned off and the current consumption is minimized to 20 nA typically. XO-STARTUP Once the CMT2150A detects the valid button-pressing event, it will go into the XO-STARTUP state, and the internal XO starts to work. The tXTAL is the time for the XO to get stable, it is to a large degree crystal dependent. A typical value of tXTAL is provided in the Table 11. TUNE The frequency synthesizer will tune the CMT2150A to the desired frequency in the time tTUNE. The PA can be turned on to transmit the data generated by the embedded encoder only after the TUNE state is done. TRANSMIT The CMT2150A starts to modulate and transmit the data. The data packets being transmitted are generated by the embedded encoder, and they are determined by the encoder selected, the button mode and the button being pressed. Table 11. Main Timing Spec in Different Working States Parameter XTAL Startup Time Symbol [1] [2] Time to Tune to Desired Frequency Min Typ Max Unit tXTAL 400 us tTUNE 370 us Notes: [1]. This parameter is to a large degree crystal dependent. [2]. From XO stable to ready to transmit. Rev 0.8 | Page 16/31 www.hoperf.com CMT2150A 5.7 The Encoder The device supports 3 types of encoding formats: 1920, 1527 and 2262. The packets of these 3 modes have different structures which will be introduced in below sub-sections. The table below summarizes the major features of the 3 encoding formats. Table 12. Feature Summary of the 3 Encoding Formats Bit Format Sync ID Length Data Length (sym/bit) (bits) (bits) 1920 3/4/5/6 1 – 32 1–7 Support Support All 1527 4 20 1–7 NA Support All 2262 8 6 – 11 1–6 NA Not Support Normal Mode Format CRC Button Modes[1] ID Study Note: [1]. Button Modes include Normal Mode, Matrix Mode, Toggle Mode and PWM Mode. All the details of these 3 types of encoding formats are given in the document “AN112 CMT2150A Configuration Guideline”. The following sections only give the abstracts of these formats. In the below explanations, some elements in the packet are measured in the unit of “symbol”, while some of them are measured in the unit of “bit”. For those which have the unit of “bit”, one “bit” is constructed (encoded) by several “symbols”. In the figures, “SYM” represents the word “symbol”. 5.7.1 1920 Packet Structure Two types of packet structures are supported for 1920 format: Normal Packet and Study Packet. The following configurable parameters are shared by the two structures. Table 13. Configurable Parameters in 1920 Packet Parameter Preamble Address (Sync ID) Length Address (Sync ID) Value Descriptions Default The size of the valid preamble, the options are: None or 16-symbol. The range of the Sync ID Length is from 1 to 32 bits. None 32-bit The value of the Sync ID has the range from 0 to 2Length-1. 0 Mode Basic Advanced Basic Advanced Basic Advanced Normal Packet The normal packet is used to control the data pins of the CMOSTEK receiver CMT2250A or PWM output of the CMT2251A. It contains a 16-symbol Preamble, a 32-symbol Head_N (which indicates that the current packet is a normal packet rather than a study packet), a Sync ID, a Configurable Data Field and an 8-symbol CRC. Preamble 16 symbols Head_N 32 symbols Address (Sync ID) configurable 1-32 bits D0 1 bit D1 1 bit D2 1 bit D3 1 bit CRC 8 symbols Figure 14. 1920 Normal Packet Structure Study Packet The study packet is used for the CMT2250/51A to learn the Sync ID from the CMT2150A in order to pair the two devices. It contains an optional Preamble, a 32-symbol Head_S, a Sync ID and an 8-symbol CRC. Rev 0.8 | Page 17/31 www.hoperf.com CMT2150A Preamble (Optional) 16-symbol Address (Sync ID) configurable 1-32 bits Head_S 32-symbol CRC 8-symbol Figure 15. 1920 Study Packet Structure Bit Format In 1920 packet, a single bit can be constructed (encoded) by 3, 4, 5 or 6 symbols. The user can select the desired value of the “Bit Format” parameter on the RFPDK. Please note that only the Sync ID field and the D0, D1, D2, D3, D4, D5, D6 have the unit of “bit”. 1 SYM 2 SYM 2 SYM 1 SYM 3 Symbols/Bit Bit 1 Bit 0 3 SYM 1 SYM 1 SYM 3 SYM 4 Symbols/Bit Bit 1 Bit 0 2 SYM 3 SYM 3 SYM 2 SYM 5 Symbols/Bit Bit 1 1 SYM 1 SYM Bit 0 2 SYM 2 SYM 1 SYM 1 SYM 1 SYM 3 SYM 6 Symbols/Bit Bit 1 Bit 0 Figure 16. 1920 Bit Format Options 5.7.2 1527 Packet Structure Two types of packet structures are supported for 1527 format: Normal Packet and Study Packet. The following configurable parameter is shared by the two structures. Table 14. Configurable Parameters in 1527 Packet Parameter Address (Sync ID) Value Descriptions Default 20 The range of the Sync ID value is from 0 to 2 -1. This is Basic 0 because the Sync ID Length is fixed at 20 for 1527. Mode Advanced In the traditional 1527 format, 8 OSC clocks are equal to 1 LCK, 4 LCK are equal to 1 symbol. By using the CMT2250A pairing with CMT2150A, the user does not need to adjust the OSC to determine the symbol rate, because the symbol rate is directly programmed. The Bit Format is fixed at 4 symbols (16 LCK) per bit. Normal Packet The traditional 1527 packet contains a 32-symbol Sync, a 20-bit Address (Sync ID) and 4-bit Data. CMOSTEK define a 1527 Study Packet to support the ID study in 1527 mode. The traditional packet introduced here is called the “Normal Packet”. Sync 32 symbols Address (Sync ID) configurable 20 bits D0 1 bit D1 1 bit D2 1 bit D3 1 bit Figure 17. 1527 Normal Packet Structure Rev 0.8 | Page 18/31 www.hoperf.com CMT2150A Study Packet The 1527 Study packet contains a 32-symbol Head_S and a 20-bit Address (Sync ID), as shown below. Head_S 32-symbol Address (Sync ID) 20 bits Figure 18. 1527 Study Packet Structure Bit Format In 1527 packet, a single bit is constructed by 4 symbols, as shown below. The user can select the desired value of the “Bit Format” parameter on the RFPDK. Please note that only the Sync ID field and the D0, D1, D2, D3, D4, D5, D6 field have the unit of “bit”. 3 SYM 1 SYM 1 SYM 3 SYM Bit 0 Bit 1 Figure 19. 1527 Bit Format Options 5.7.3 2262 Packet Structure ID Study is not supported in 2262 mode. Only one packet structure is supported. Table 15. Configurable Parameters in 2262 Packet Parameter Descriptions Default Mode This is the range of the Sync ID Length. The range is from Address (Sync ID) 6 to 11 bits. This parameter also defines the number of Length data bits, because the total number of Sync ID and Data Basic 8-bit Advanced bits is fixed at 12. Address (Sync ID) Value The value of each bit of the Sync ID can only be represented by 0, 1 or f. Basic 00000000 Advanced In the traditional 2262 format, 4 OSC clocks (1 OSC clock cycle is notated as 1 α) are equal to 1 symbol. By using the CMOSTEK products, the user does not need to adjust the OSC to define the symbol rate, because the symbol rate is directly programmed. The Bit Format is fixed at 8 symbols per bit. Normal Packet The traditional 2262 packet contains an 8 to 11-bit Address (Sync ID), a 1 to 4-bit Data, and a 32-symbol Sync. Address (Sync ID) configurable 8-11 bits Data 4-1 bit(s) Sync 32 symbols Figure 20. 2262 Packet Structure Bit Format In 2262 packet, a single bit is constructed by 8 symbols, as shown below. Please note that only the Address (Sync ID) field and the Data field have the unit of “bit”. In the below diagram, 1 OSC clock cycle is notated as 1 α referring to the original 2262 timing descriptions. Rev 0.8 | Page 19/31 www.hoperf.com CMT2150A 3 SYM (12 α) 3 SYM (12 α) 1 SYM (4 α) 1 SYM (4 α) 1 SYM (4 α) 3 SYM (12 α) 3 SYM (12 α) 3 SYM (12 α) Bit 0 Bit 1 1 SYM (4 α) 1 SYM (4 α) 3 SYM (12 α) 1 SYM (4 α) Bit f Figure 21. 2262 Bit Format Options 5.8 ID Study The ID Study function, which is supported in 1920 and 1527 modes, allows the CMT2250/51A to receive the Sync ID sent by the CMT2150A and burns it into the local EEPROM automatically. Since then, the CMT2250/51A’s Sync ID is identical to that of the CMT2150A and therefore two devices are paired. The lengths of the Sync ID are different in the different packet formats. In 1920 format, it is from 1 to 32 bits. In 1527 format, it is fixed at 20 bits. The ID Study is initialized by the CMT2150A. It is done by executing the following steps: 1. Press the Study Button on the CMT2150A and hold it over the time defined by the “Study Trigger Time”. 2. CMT2150A starts to transmit the Study Packets, wait 1-2 seconds then release the Study Button. 3. Try to press a certain button on the CMT2150A to check if the CMT2250/51A react correctly. The figure below shows the timing characteristic after pressing down a study button. The Study Power is always independently configured from the TX Power. In this example, the Study Power is set smaller than the TX Power. One Normal Packet Packet Interval TX Power = 0 dBm One Study Packet Packet Interval Study Power = -6 dBm time Study Time (Default is 5 s) Study Button Pressed Study Button Released Figure 22. Timing of Study Button Pressing Event More information about the ID Study can be found in the document “AN112 CMT2150A Configuration Guideline”. 5.9 Button Modes The button modes define the functions of the input pins K1 – K7. The CMT2150A supports 4 different button modes: Normal, Matrix, Toggle and PWM, which are configured on the RFPDK. The following sections give the abstract of each button mode. All the details of the button modes are given in the document “AN112 CMT2150A Configuration Guideline”. 5.9.1 Normal The Normal Button Mode is supported in 1920, 1527 and 2262 format. In this mode, the buttons are directly mapped to the data field of the packet. Multiple buttons can be pressed at the same time. For 1920 and 1527, the largest number of buttons is 7 which are defined by the parameter “Number of Button(s)”. For 2262, the largest number of buttons is 6, which is determined by the Sync ID Length. The figure below gives an example which 4 push button keys are selected. Rev 0.8 | Page 20/31 www.hoperf.com CMT2150A LED 1 14 XTAL √ XTAL VDD √ VDD 2 13 CLK √ CLK GND √ GND 3 12 K0 × NC RFO √ RFO 4 11 K1 √ D0 LED √ NC × K7 5 10 K2 √ D1 NC × K6 6 9 K3 √ D2 NC × K5 7 8 K4 √ D3 Figure 23. Normal Button Mode In normal button mode, the number of button(s) to be used determines the number of data bits in the packet. The table below shows an example that 4 buttons are used and the pins K1 – K4 are mapped to the data D0 – D3, “1” in the Push Buttons section means the corresponding button(s) is/are pressed down, while the “1” in the Data Bits section means a logic “1” to be transmitted. Table 16. Mapping from K1-K4 to D0-D3 in Normal Button Mode Push Buttons K3 The Data Bits K1 K2 K4 D0 D1 D2 D3 1 0 0 1 0 0 1 0 0 0 0 0 0 1 0 0 1 1 0 0 1 1 0 0 0 0 1 0 0 0 1 0 1 0 1 0 0 1 1 0 1 0 1 0 0 1 1 0 1 1 1 0 1 1 1 0 0 0 0 1 0 0 1 0 0 0 1 1 1 0 0 1 0 1 0 1 0 1 0 1 1 1 0 1 1 1 0 1 0 0 1 1 0 0 1 1 1 0 1 1 1 0 1 1 0 1 1 1 0 1 1 1 1 1 1 1 1 1 1 1 5.9.2 Matrix The Matrix Button Mode is supported in 1920 and 1527 format. In the Matrix Button Mode, the number of buttons is fixed at 5. On the RFPDK, it can be seen that the 5 buttons are assigned to pin 11 (K1) – pin 7 (K5). In this mode, at most two buttons can be pressed at the same time. The figure below gives an example of Matrix mode push button arrangement. Rev 0.8 | Page 21/31 www.hoperf.com CMT2150A LED 1 14 XTAL √ XTAL VDD √ VDD 2 13 CLK √ CLK GND √ GND 3 12 K0 × NC RFO √ RFO 4 11 K1 √ B0 LED √ NC × K7 5 10 K2 √ B1 NC × K6 6 9 K3 √ B2 B4 √ K5 7 8 K4 √ B3 Figure 24. Matrix Button Mode (Button B) The user is able to use the 5 buttons K1(B0) – K5(B4) to generate different combinations of the data D0 – D3 to be transmitted. The number of data bits to be transmitted is fixed at 4. The table below shows the matrix. For the K1 – K5 buttons, “1” in the Push Buttons section means the corresponding button(s) is/are pressed down, while the “1” in the Data Bits section means a logic “1” to be transmitted. Table 17. Mapping from K1-K5 to D0-D3 in Matrix Button Mode Push Buttons The Data Bits K1 K2 K3 K4 K5 D0 D1 D2 D3 1 0 0 0 0 1 0 0 0 0 1 0 0 0 0 1 0 0 0 0 1 0 0 1 1 0 0 0 0 0 1 0 0 0 1 0 0 0 0 0 1 1 0 1 0 1 1 0 0 0 0 1 1 0 1 0 1 0 0 1 1 1 0 1 0 0 1 0 0 0 0 1 1 0 0 0 1 1 0 0 1 0 1 1 0 0 0 1 0 1 0 1 0 1 0 1 1 0 1 0 1 0 0 1 0 0 1 1 0 0 1 1 0 1 0 1 1 0 0 1 0 1 0 1 1 1 0 0 0 1 1 1 1 1 1 5.9.3 Toggle The Toggle Button Mode is supported in 1920 and 1527. In this mode, 5 or 6 buttons are used. Four buttons directly mapped to the data D0 – D3 are used to control the data. Besides, a single button or two separated buttons used to turn on/off the data can be chosen by the parameter “On/Off Button(s)”. In this mode, only one button can be pressed at the same time. Pin 12 (K0) and Pin 5 (K7) are never used in this mode. The figure below gives examples of the pin functions in Toggle mode. Rev 0.8 | Page 22/31 www.hoperf.com CMT2150A LED 1 14 XTAL √ XTAL VDD √ VDD 2 13 CLK GND √ GND 3 12 RFO √ RFO 4 LED √ LED 1 14 XTAL √ XTAL √ CLK VDD √ VDD 2 13 CLK √ CLK K0 × NC GND √ GND 3 12 K0 × NC 11 K1 √ ON/OFF RFO √ RFO 4 11 K1 √ ON LED √ NC × K7 5 10 K2 × NC NC × K7 5 10 K2 √ OFF D3 √ K6 6 9 K3 √ D0 D3 √ K6 6 9 K3 √ D0 D2 √ K5 7 8 K4 √ D1 D2 √ K5 7 8 K4 √ D1 Figure 25. Toggle Button Mode with Single (left) and Separated (right) ON/OFF Button(s) For the 4 data buttons mapped to D0 – D3, every time a button is pressed, the generated data bit toggles. For example, if the default value of D1 is 0, press K4 down, the D1 is set to 1 in the current transmission, release the K4 and press it down again, the D1 is set to 0 in the current transmission, and so on. This is what it means by “Toggle”. See the table below for the examples of toggle button mode. Table 18. Examples of the Toggle Button Mode On/Off Button(s) Pressed Button (Times) D0 D1 D2 D3 st 0 1 0 0 nd 0 0 0 0 Press K4 (D1) – 1 Time Press K4 (D1) – 2 Time rd Single Press K4 (D1) – 3 Time 0 1 0 0 (K1 is On/Off) Press K1 – 1st Time (On) 1 1 1 1 nd 0 0 0 0 rd Press K1 – 3 Time (On) 1 1 1 1 Press K4 (D1) – 1st Time 0 1 0 0 Press K4 (D1) – 2nd Time 0 0 0 0 Press K1 – 2 Time (Off) Separated (K1 is On K2 is Off) rd Press K4 (D1) – 3 Time 0 1 0 0 Press K1 (On) 1 1 1 1 Press K2 (Off) 0 0 0 0 Press K1 (On) 1 1 1 1 5.9.4 PWM The PWM Button Mode is only supported for 1920 and 1527 encoding format. In this mode, 2 buttons are used to send out commands to increase or decrease the duty ratio of the PWM output of the CMT2251A. A single on/off button, or two separated on/off buttons can be chosen by the parameter “On/Off Button(s)”. The “On” command sets the PWM output of the CMT2251A to 100% of duty ratio, while the “Off” command sets the PWM output to 0% of duty ratio. In this mode, only one button can be pressed at the same time. Pin 12 (K0), Pin 9 (K3), Pin 6 (K6) and Pin 5 (K7) are never used in this mode. The commands of On, Off, Increase and Decrease are represented by D0 – D3. The figure below gives examples of the pin functions in PWM mode. Rev 0.8 | Page 23/31 www.hoperf.com CMT2150A LED √ LED 1 14 XTAL √ XTAL VDD √ VDD 2 13 CLK GND √ GND 3 12 RFO √ RFO 4 LED √ LED 1 14 XTAL √ XTAL √ CLK VDD √ VDD 2 13 CLK √ CLK K0 × NC GND √ GND 3 12 K0 × NC 11 K1 √ ON/OFF RFO √ RFO 4 11 K1 √ ON/OFF NC × K7 5 10 K2 × NC NC × K7 5 10 K2 √ OFF NC × K6 6 9 K3 × NC NC × K6 6 9 K3 × NC DEC √ K5 7 8 K4 √ INC DEC √ K5 7 8 K4 √ INC Figure 26. PWM Button Mode with Single (left) and Separated (right) ON/OFF Button(s) If K1 is used as the On/Off Button, press it down once, the “On” command is transmitted, release and press it down again, the “Off” command is transmitted, and so on. In this case, K1 is a “Toggle” button. If the K1 is used as the On Button and K2 is used as the Off Button, pressing K1, the “On” command is transmitted; pressing K2, the “Off” command is transmitted. 5.10 LED Driving Capability This defines the maximum current driving capacity on the LED pin. Once the LED pin is enabled, it will light up or flash to indicate two events:  When the chip is transmitting data, the LED will light up until the transmission is finished to notify the user the chip is working, when the LBD is disabled, or LBD is enabled but there is no low battery detected.  When the LBD is enabled and there is valid low battery detection on the button(s) pressing, the LED will flash at least 5 times at the frequency of 6 Hz to notify the user the battery is running out. 5.11 Low Battery Detection (LBD) This defines the Low Battery Detection threshold. Once the LBD is enabled, the chip will automatically check the battery status before each transmission. Once the chip finds that the battery output is less than the detection threshold, the LED will flash at least 5 times at the frequency of 6 Hz to notify the user. Once the LED flashes, the performance of the transmission is not guaranteed. The user should change the batteries to new ones. 5.12 Crystal Oscillator and RCLK The CMT2150A uses a 1-pin crystal oscillator circuit with the required crystal load capacitance integrated on-chip. Figure 27 shows the configuration of the XTAL circuitry and the crystal model. The recommended specification for the crystal is 26 MHz with ±20 ppm, ESR (Rm) < 60 Ω, load capacitance CLOAD ranging from 12 to 20 pF. To save the external load capacitors, a set of variable load capacitors CL is built inside the CMT2150A to support the oscillation of the crystal. The value of load capacitors is configurable with the CMOSTEK USB Programmer and RFPDK. To achieve the best performance, the user only needs to input the desired value of the XTAL load capacitance CLOAD of the crystal (can be found in the datasheet of the crystal) to the RFPDK, then finely tune the required XO load capacitance according to the actual XO frequency. Please refer to “AN113 CMT2150A/2250(1)A One-Way RF Link Development Kits User’s Guide” for the method of choosing the right value of CL. Rev 0.8 | Page 24/31 www.hoperf.com CMT2150A Crystal Model CMT2150A CMT2150A Cc XTAL RCLK 26 MHz 0. 3 – 0. 7 Vpp Rm Cm XTAL C0 CL CL Lm Figure 27. XTAL Circuitry and Crystal Model Figure 28. RCLK Circuitry If a 26 MHz RCLK (reference clock) is available in the system, the user can directly use it to drive the CMT2150A by feeding the clock into the chip via the XTAL pin. This further saves the system cost due to the removal of the crystal. A coupling capacitor is required if the RCLK is used. The recommended amplitude of the RCLK is 0.3 to 0.7 Vpp on the XTAL pin. Also, the user should set the internal load capacitor CL to its minimum value. See Figure 28 for the RCLK circuitry. Rev 0.8 | Page 25/31 www.hoperf.com CMT2150A 6. Ordering Information Table 19. CMT2150A Ordering Information Part Number Descriptions Package Package Operating MOQ / Type Option Condition Multiple SOP14 Tape & Reel SOP14 Tube 240 – 480 MHz OOK CMT2150A-ESR[1] Stand-Alone Transmitter with Encoder 240 – 480 MHz OOK [1] CMT2150A-ESB Stand-Alone Transmitter with Encoder 1.8 to 3.6 V, 2,500 -40 to 85 ℃ 1.8 to 3.6 V, 1,000 -40 to 85 ℃ Note: [1]. “E” stands for extended industrial product grade, which supports the temperature range from -40 to +85 ℃. “S” stands for the package type of SOP14. “R” stands for the tape and reel package option, the minimum order quantity (MOQ) for this option is 2,500 pcs. “B” stands for the tube package option, with the MOQ of 1,000 pcs. The default frequency for CMT2150A is 433.92 MHz, for the other settings, please refer to the Table 10 of Page 13. Visit www.cmostek.com/products to know more about the product and product line. Contact sales@cmostek.com or your local sales representatives for more information. Rev 0.8 | Page 26/31 www.hoperf.com CMT2150A 7. Package Outline D A3 h A2 A 0.25 c θ A1 L L1 E1 b E e Figure 29. 14-Pin SOP Package Table 20. 14-Pin SOP Package Dimensions Size (millimeters) Symbol Min Typ Max A - - 1.75 A1 0.05 - 0.225 A2 1.30 1.40 1.50 A3 0.60 0.65 0.70 b 0.39 - 0.48 C 0.21 - 0.26 D 8.45 8.65 8.85 E 5.80 6.00 6.20 E1 3.70 3.90 4.10 e 1.27 BSC h 0.25 - 0.50 L 0.30 - 0.60 L1 θ 1.05 BSC 0 - Rev 0.8 | Page 27/31 8° www.hoperf.com CMT2150A 8. Top Marking 8.1 CMT2150A Top Marking CMT 2 1 5 0 A Y Y W W ①②③④⑤⑥ Figure 30. CMT2150A Top Marking Table 21. CMT2150A Top Marking Explanation Mark Method : Laser Pin 1 Mark : Circle’s diameter = 1 mm Font Size : 0.35 mm, right-justified Line 1 Marking : CMT2150A, represents part number CMT2150A YYWW is the Date code assigned by the assembly house. YY represents the last two digits of Line 2 Marking : the mold year and WW represents the workweek ①②③④⑤⑥ is the internal tracking number Rev 0.8 | Page 28/31 www.hoperf.com CMT2150A 9. Other Documentations Table 22. Other Documentations for CMT2150A Brief AN111 AN112 AN113 AN115 Name Descriptions CMT215x Schematic and PCB Layout Design Guideline design related issues. CMT2150A Configuration Guideline CMT2150A/2250(1)A One-Way RF Link Development Kits User’s Guide Pairing CMT215x and CMT225x Details of CMT2150/57A PCB schematic and layout design rules, RF matching network and other application layout Details of configuring CMT2150A features on the RFPDK. User’s Guides for CMT2150A/2250(1)A Development Kits, including Evaluation Board and Evaluation Module, CMOSTEK USB Programmer and RFPDK. Provide quick guideline in how to pair the CMT2150/57A with CMT2250/51A. Rev 0.8 | Page 29/31 www.hoperf.com CMT2150A 10. Document Change List Table 23. Document Change List Rev. No. Chapter 0.8 All Description of Changes Initial released version Rev 0.8 | Page 30/31 Date 2015-02-11 www.hoperf.com CMT2150A 11. Contact Information Hope Microelectronics Co., Ltd Address: 2/F,Building3,Pingshan Private Enterprise science and Technology Park,Xili Town,Nanshan District,Shenzhen,China Tel: +86-755-82973805 Fax: +86-755-82973550 Email: sales@hoperf.com hoperf@gmail.com Website: http://www.hoperf.com http://www.hoperf.cn Copyright. CMOSTEK Microelectronics Co., Ltd. All rights are reserved. The information furnished by CMOSTEK is believed to be accurate and reliable. However, no responsibility is assumed for inaccuracies and specifications within this document are subject to change without notice. The material contained herein is the exclusive property of CMOSTEK and shall not be distributed, reproduced, or disclosed in whole or in part without prior written permission of CMOSTEK. CMOSTEK products are not authorized for use as critical components in life support devices or systems without express written approval of CMOSTEK. The CMOSTEK logo is a registered trademark of CMOSTEK Microelectronics Co., Ltd. All other names are the property of their respective owners. Rev 0.8 | Page 31/31 www.hoperf.com