MICRF506 410MHz and 450MHz ISM Band Transceiver General Description The MICRF506 is a true single-chip, frequency shift keying (FSK) transceiver intended for use in half-duplex, bidirectional RF links. The multi-channeled FSK transceiver is intended for UHF radio equipment in compliance with the European Telecommunication Standard Institute (ETSI) specification, EN300 220. The transmitter consists of a PLL frequency synthesizer and power amplifier. The frequency synthesizer consists of a voltage-controlled oscillator (VCO), a crystal oscillator, dual modulus prescaler, programmable frequency dividers, and a phase-detector. The loop-filter is external for flexibility and can be a simple passive circuit. The output power of the power amplifier can be programmed to seven levels. A lock-detect circuit detects when the PLL is in lock. In receive mode, the PLL synthesizer generates the local oscillator (LO) signal. The N, M, and A values that give the LO frequency are stored in the N0, M0, and A0 registers. The receiver is a zero intermediate frequency (IF) type which makes channel filtering possible with low-power, integrated low-pass filters. The receiver consists of a low noise amplifier (LNA) that drives a quadrature mix pair. The mixer outputs feed two identical signal channels in phase quadrature. Each channel includes a pre-amplifier, a third order Sallen-Key RC low-pass filter that protects the following switched-capacitor filter from strong adjacent channel signals, and a limiter. The main channel filter is a switched-capacitor implementation of a six-pole elliptic low pass filter. The cut-off frequency of the Sallen-Key RC filter can be programmed to four different frequencies: 100kHz, 150kHz, 230kHz, and 340kHz. The I and Q channel outputs are demodulated and produce a digital data output. The demodulator detects the relative phase of the I and the Q channel signal. If the I channel signal lags behind the Q channel, the FSK tone frequency is above the LO frequency (data '1'). If the I channel leads the Q channel, the FSK tone is below the LO frequency (data '0'). The output of the receiver is available on the DataIXO pin. A receive signal strength indicator (RSSI) circuit indicates the received signal level. All support documentation can be found on Micrel’s web site at www.micrel.com. July 2006 RadioWire® Features • • • • • • • • • • True single chip transceiver Digital bit synchronizer Received signal strength indicator (RSSI) RX and TX power management Power down function Reference crystal tuning capabilities Frequency error estimator Baseband shaping Three-wire programmable serial interface Register read back function Applications • • • • • • • 1 Telemetry Remote metering Wireless controller Remote data repeater Remote control systems Wireless modem Wireless security system M9999-092904 +1 408-944-0800 Micrel MICRF506BML/YML General Description ....................................................................................................................................................1 Features......................................................................................................................................................................1 Applications ................................................................................................................................................................1 RadioWire® RF Selection Guide ................................................................................................................................4 Ordering Information...................................................................................................................................................4 Block Diagram ............................................................................................................................................................4 Pin Configuration ........................................................................................................................................................5 Pin Description............................................................................................................................................................5 Absolute Maximum Ratings(1) .....................................................................................................................................6 Operating Ratings(2) ....................................................................................................................................................6 Electrical Characteristics(4) .........................................................................................................................................6 Programming ..............................................................................................................................................................9 Writing to the control registers in MICRF506 ...........................................................................................................10 Writing to a Single Register ......................................................................................................................................10 Writing to All Registers .............................................................................................................................................11 Writing to n Registers having Incremental Addresses..............................................................................................11 Writing to n Registers having Non-Incremental Addresses......................................................................................12 Reading from the control registers in MICRF506 .....................................................................................................12 Programming interface timing...................................................................................................................................12 Power on Reset ........................................................................................................................................................13 Programming summary ............................................................................................................................................14 Frequency Synthesizer.............................................................................................................................................15 Crystal Oscillator (XCO)........................................................................................................................................16 VCO ......................................................................................................................................................................17 Charge Pump ........................................................................................................................................................18 PLL Filter...............................................................................................................................................................18 Lock Detect ...........................................................................................................................................................18 Modes of Operation ..............................................................................................................................................18 Transceiver Sync/Non-Synchronous Mode ..............................................................................................................19 Data Interface ...........................................................................................................................................................19 Receiver....................................................................................................................................................................20 Front End ..............................................................................................................................................................20 Sallen-Key Filters ..................................................................................................................................................20 Switched Capacitor Filter ......................................................................................................................................21 RSSI......................................................................................................................................................................21 FEE .......................................................................................................................................................................22 Bit Synchronizer ....................................................................................................................................................23 Transmitter................................................................................................................................................................24 Power Amplifier .....................................................................................................................................................24 Modulator ..............................................................................................................................................................26 Using the XCO-tune Bits ..........................................................................................................................................28 Typical Application....................................................................................................................................................30 July 2006 2 M9999-092904 +1 408-944-0800 Micrel MICRF506BML/YML MICRF506BML/YML Land pattern ...........................................................................................................................31 Layout Considerations ..............................................................................................................................................32 Package Information MICRF506BML.......................................................................................................................33 Package Information MICRF506YML.......................................................................................................................34 Overview of programming bit....................................................................................................................................35 Table 1: Detailed description of programming bit.....................................................................................................35 Table 2: Main Mode bit .............................................................................................................................................40 Table 3: Synchronizer mode bit................................................................................................................................40 Table 4: Modulation bit .............................................................................................................................................40 Table 5: Prefilter bit...................................................................................................................................................40 Table 6: Power amplifier bit ......................................................................................................................................41 Table 7:Generation of Bitrate_clk, BitSync_clk and Mod_clk...................................................................................41 Table 8: Test signals.................................................................................................................................................41 Table 10: Frequency Error Estimation control bit .....................................................................................................42 Table 11: Frequency Error Estimation control bit, cont. ...........................................................................................42 July 2006 3 M9999-092904 +1 408-944-0800 Micrel MICRF506BML/YML RadioWire® RF Selection Guide Device Frequency Range Maximum Data Rate Receive Supply Voltage Modulation Type Transmit Package MICRF500 700MHz – 1.1GHz 128k Baud 12mA 2.5 to 3.4V 50mA FSK LQFP-44 MICRF501 300MHz – 440MHz 128k Baud 8mA 2.5 to 3.4V 45mA FSK LQFP-44 MICRF505 850MHz – 950MHz 200k Baud 13mA 2.0 to 2.5V 28mA FSK MLF™-32 MICRF506 410MHz – 450MHz 200k Baud 12mA 2.0 to 2.5V 21.5mA FSK MLF™-32 MICRF405 290-980MHz 200k Baud NA 2.0-3.6V 18mA FSK/ASK MLF™-24 Ordering Information Part Number Junction Temp. Range(1) Package MICRF506YML TR –40° to +85°C Lead free 32-Pin MLFTM MICRF506BML TR –40° to +85°C 32-Pin MLFTM ____________________________________________________________________________________________________ Block Diagram SCLK IFAMP PA-buffer PA RSSI Deviation control DIV 4 CS Control logic LO-Buffer Clock recovery Demodulator LNA Main filter Sallen-key ANT LC Filter CIBIAS IO Modulator IFAMP Main filter Sallen-key DATAIXO DATACLK RSSI LD Frequency Synthesiser VCO XCO PTATBIAS Bias XTALIN XTALOUT CPOUT VARIN Loop filter July 2006 4 M9999-092904 +1 408-944-0800 Micrel MICRF506BML/YML NC VCOVDD VCOGND VARIN GND CPOUT DIGGND DIGVDD Pin Configuration 1 2 3 4 5 6 7 8 32 3130 29 28 27 26 25 24 23 22 21 20 19 18 17 9 10 11 12 13 14 15 16 XTALOUT XTALIN CS SCLK IO DATAIXO DATACLK NC CIBIAS IFVDD IFGND ICHOUT QCHOUT RSSI LD NC RFGND PTATBIAS RFVDD RFGND ANT RFGND GND NC MICRF506BML TM 32-Pin MLF Pin Description Pin Number Pin Name 1 RFGND 2 PTATBIAS Type O Pin Function Pin Number Pin Name Type LNA and PA ground. 18 DATACLK O Connection for bias resistor. RX/TX data clock output. 19 DATAIXO I/O RX/TX data input/output. 20 IO I/O 3-wire interface data in/output. 21 SCLK I 3-wire interface serial clock. 22 CS I 3-wire interface chip select. 3 RFVDD LNA and PA power supply. 4 RFGND LNA and PA ground. 5 ANT 6 RFGND LNA and PA ground. 7 RFGND LNA and PA ground. 8 NC 9 CIBIAS 10 I/O Antenna In/Output. Pin Function No connect. 23 XTALIN I Connection for bias resistor. Crystal oscillator input. 24 XTALOUT O IFVDD IF/mixer power supply. Crystal oscillator output. 25 DIGVDD Digital power supply. 11 IFGND IF/mixer ground. 26 DIGGND Digital ground. 12 ICHOUT Test pin. 27 CPOUT 13 QCHOUT O Test pin. 14 RSSI O Received signal strength indicator. 28 GND 29 VARIN 15 LD O PLL lock detect. 30 VCOGND VCO ground. 16 NC No connect. 31 VCOVDD VCO power supply. 17 NC No connect 32 NC July 2006 O O 5 O PLL charge pump output. Substrate ground. I VCO varactor. No connect. M9999-092904 +1 408-944-0800 Micrel MICRF506BML/YML Absolute Maximum Ratings(1) Operating Ratings(2) Supply Voltage (VDD) ........................................ +2.7V Voltage on any pin (GND = 0V). .....-0.3V to 2.7V Storage Temperature (Ts)................ -55°C to +150°C ESD Rating(3) ....................................................... 2kV Supply voltage (VIN) ............................+2.0V to +2.5V RF Frequencies ..........................410MHz to 450MHz Data Rate ................................................ <200kBaud Ambient Temperature (TA) ................ –40°C to +85°C Package Thermal Resistance MLFTM (θJA) ........................................... 41.7°C/W Electrical Characteristics(4) fRF = 433MHz. Data-rate = 125kbps, Modulation type = closed-loop VCO modulation, VDD = 2.5V; TA = 25°C, bold values indicate –40°C< TA < +85°C, unless noted. Symbol Parameter Condition Min Typ Max Units RF Frequency Operating Range 410 450 MHz Power Supply 2.0 2.5 V 3 µA Power Down Current 0.3 Standby Current 280 µA VCO and PLL Section Reference Frequency (5) 4 40 MHz PLL Lock Time 433.75MHz to 434.25MHz 0.7 1.3 ms 3kHz bandwidth 430MHz to 440MHz 1.3 2 ms 433.75MHz to 434.25MHz 0.3 Rx – Tx 1.0 1.4 ms Tx – Rx 1.0 2.5 ms Standby Rx 1.0 3 ms Standby Tx 1.0 ms 16MHz, 9pF load, 5.6pF loading capacitors 1.0 ms (5) PLL Lock Time ms 20kHz bandwidth Switch Time (5) 3kHz loop bandwidth Crystal Oscillator Start-Up Time Charge Pump Current VCPOUT = 1.1V, CP_HI = 0 100 125 170 µA VCPOUT = 1.1V, CP_HI = 1 420 500 680 µA Transmit Section Output Power Output Power Tolerance Tx Current Consumption RLOAD = 50Ω, Pa2-0-111 11 dBm RLOAD = 50Ω, Pa2-0-001 -7 dBm Over temperature range 1 dB Over power supply range 3 dB RLOAD = 50Ω, Pa2-0-111 21.5 mA RLOAD = 50Ω, Pa2-0-001 10.5 mA 8.0 RLOAD = 50Ω, Pa2-0-000 Binary FSK Frequency Separation(5) Data Rate July 2006 (5) mA Birate = 200kbps 20 500 kHz VCO modulation 20 200 kbps 20 kbps Divider modulation 6 M9999-092904 +1 408-944-0800 Micrel Symbol MICRF506BML/YML Parameter Condition Occupied bandwidth Harmonics 434MHz (5) Min Typ Spurious Emission < 1GHz (5) Units 38.4kbps, β = 2, 20dBc 140 kHz 125kbps, β = 2, 20dBc 550 kHz 200kbps, β = 2, 20dBc 800 (5) Spurious Emission in Restricted bands < 1GHz(5) Max ETSI EN300 220 (Using antenna matching network) Spurious Emission > 1GHz(5) kHz -36 dBm -54 dBm -36 dBm -30 dBm Receive Section All functions turned on Rx Current Consumption Rx Current Consumption Variation 12 mA LNA bypass 10.3 mA Switch cap filter bypass with LNA 9.8 mA Bypass of Switch cap and LNA 8.0 mA 3 mA 2.4kbps, β = 16, BER 10-3 Over temperature -113 dBm 4.8kbps, β = 16, BER 10-3 -111 dBm -3 -106 dBm -3 -104 dBm -3 -101 dBm -100 dBm 200kbps, β = 2, BER 10 -97 dBm 125kbps, 125kHz deviation +12 dBm 20kbps, 40kHz deviation +2 dBm Over temperature 4 dB 19.2kbps, β = 4, BER 10 Receiver Sensitivity 38.4kbps, β = 4, BER 10 76.8kbps, β = 2, BER 10 -3 125kbps, β = 2, BER 10 -3 Receiver Maximum Input Power Receiver Sensitivity Tolerance Over power supply range Receiver Bandwidth Co-Channel Rejection Adjacent Channel Rejection dB 500kHz spacing, 19.2kbps, Main filter cut off frequency 133kHz 48 dB 1MHz ,19.2kbps, Main filter cut off frequency 133kHz 56 dB Offset ±1MHz 61 dB Offset ±2MHz 58 dB Offset ±5MHz 46 dB Offset ±10MHz 62 dB Offset ±30MHz 75 dB -34 dBm -25 dBm -90 dBm 2 tones with 1MHz separation LO Leakage Spurious Emission (5) <1GHz, EN 300 220 -57 dBm >1GHz, EN 300 220 -47 dBm (5) Input Impedance July 2006 kHz -8 1dB Compression Input IP3 dB 350 19.2 kbps, β = 6, SC=133 kHz Desired signal: 19.2 kbps, β =6, 3dB above sens, SC=133 kHz Blocking 1 50 Ω 50 7 M9999-092904 +1 408-944-0800 Micrel Symbol MICRF506BML/YML Parameter Condition Min RSSI Dynamic Range RSSI Output Range Typ Max Units 50 dB Pin = -110dBm 0.9 V Pin = -60dBm 2 V Digital Inputs/Outputs VIH Logic Input High 0.7VDD VDD V VIL Logic Input Low 0 0.3VDD V 10 MHz 55 % (5) Clock/Data Frequency (5) Clock/Data Duty Cycle 45 Notes: 1. Exceeding the absolute maximum rating may damage the device. 2. The device is not guaranteed to function outside its operating rating. 3. Devices are ESD sensitive. Handling precautions recommended. Human body model, 1.5k in series with 100pF. 4. Specification for packaged product only. 5. Guaranteed by design. July 2006 8 M9999-092904 +1 408-944-0800 Micrel MICRF506BML/YML Programming General The MICRF506 functions are enabled through a number of programming bits. The programming bits are organized as a set of addressable control registers, each register holding 8 bits. There are 23 control registers in total in the MICRF506, and they have addresses ranging from 0 to 22. The user can read all the control registers. The user can write to the first 22 registers (0 to 21); the register 22 is a read-only register. All control registers hold 8 bits and all 8 bits must be written to when accessing a control register, or they will be read. Some of the registers do not utilize all 8 bits. The value of an unused bit is “don’t care.” The control register with address 0 is referred to as ControlRegister0, the control register with address 1 is ControlRegister1 and so on. A summary of the control registers is given in the table below. In addition to the unused bits (marked with”-“) there are a number of mandatory bits (marked with “0” or “1”). Always maintain these as shown in the table. The control registers in MICRF506 are accessed through a 3-wire interface; clock, data and chip select. These lines are referred to as SCLK, IO, and CS, respectively. This 3-wire interface is dedicated to control register access and is referred to as the control interface. Received data (via RF) and data to transmit (via RF) are handled by the DataIXO and DataClk (if enabled) lines; this is referred to as the data interface. The SCLK line is applied externally; access to the control registers are carried out at a rate determined by the user. The MICRF506 will ignore transitions on the SCLK line if the CS line is inactive. The MICRF506 can be put on a bus, sharing clock and data lines with other devices. All control registers should be written to after a battery reset. During operation, it is sufficient to write to one register only. The MICRF506 will automatically enter power down mode after a battery reset. Adr Data A6…A0 D7 D6 D5 D4 D3 D2 D1 D0 0000000 LNA_by PA2 PA1 PA0 Sync_en Mode1 Mode0 Load_en 0000001 Modulation1 Modulation0 ‘0’ ‘0’ RSSI_en LD_en PF_FC1 PF_FC0 0000010 CP_HI SC_by ‘0’ PA_By OUTS3 OUTS2 OUTS1 OUTS0 0000011 ‘1’ ‘1’ ‘0’ VCO_IB2 VCO_IB1 VCO_IB0 VCO_freq1 VCO_freq0 0000100 Mod_F2 Mod_F1 Mod_F0 Mod_I4 Mod_I3 Mod_I2 Mod_I1 Mod_I0 0000101 - - ‘0’ ‘1’ Mod_A3 Mod_A2 Mod_A1 Mod_A0 0000110 - Mod_clkS2 Mod_clkS1 Mod_clkS0 BitSync_clkS2 BitSync_clkS1 BitSync_clkS0 BitRate_clkS2 0000111 BitRate_clkS1 BitRate_clkS0 RefClk_K5 RefClk_K4 RefClk_K3 RefClk_K2 RefClk_K1 RefClk_K0 0001000 ‘1’ ‘1’ ‘0’ ScClk4 ScClk3 ScClk2 ScClk1 ScClk0 0001001 ‘0’ ‘0’ ‘1’ XCOtune4 XCOtune3 XCOtune2 XCOtune1 XCOtune0 0001010 - - A0_5 A0_4 A0_3 A0_2 A0_1 A0_0 0001011 - - - - N0_11 N0_10 N0_9 N0_8 0001100 N0_7 N0_6 N0_5 N0_4 N0_3 N0_2 N0_1 N0_0 0001101 - - - - M0_11 M0_10 M0_9 M0_8 0001110 M0_7 M0_6 M0_5 M0_4 M0_3 M0_2 M0_1 M0_0 0001111 - - A1_5 A1_4 A1_3 A1_2 A1_1 A1_0 0010000 - - - - N1_11 N1_10 N1_9 N1_8 0010001 N1_7 N1_6 N1_5 N1_4 N1_3 N1_2 N1_1 N1_0 0010010 - - - - M1_11 M1_10 M1_9 M1_8 0010011 M1_7 M1_6 M1_5 M1_4 M1_3 M1_2 M1_1 M1_0 0010100 ‘1’ ‘0’ ‘1’ ‘0’ ‘0’ ‘0’ ‘1’ ‘1’ 0010101 - - - - FEEC_3 FEEC_2 FEEC_1 FEEC_0 0010110 FEE_7 FEE_6 FEE_5 FEE_4 FEE_3 FEE_2 FEE_1 FEE_0 Names of programming bits, unused bits (“-“) and mandatory bits (“1” or “0”) are shown. Change of mandatory bits may cause malfunction. Table 1. Control Registers in MICRF506 July 2006 9 M9999-092904 +1 408-944-0800 Micrel MICRF506BML/YML The two different ways to “program the chip” are: Writing to the control registers in MICRF506 Writing: A number of octets are entered into MICRF506 followed by a load-signal to activate the new setting. Making these events is referred to as a “write sequence.” It is possible to update all, 1, or n control registers in a write sequence. The address to write to (or the first address to write to) can be any valid address (0-21). The IO line is always an input to the MICRF506 (output from user) when writing. The address of the control register to write to (or if more than 1 control register should be written to, the address of the 1st control register to write to). • A bit to enable reading or writing of the control registers. This bit is called the R/W bit. • The values register(s). to write into the Write to a number of control registers (0-22) when the registers have incremental addresses (write to 1, all or n registers) • Write to a number of control registers when the registers have non-incremental addresses. Writing to a Single Register Writing to a control register with address “A6. A5, …A0” is described here. During operation, writing to 1 register is sufficient to change the way the transceiver works. Typical example: Change from receive mode to power-down. What to write: • • What to write: Field control Comments Address: 7 bit = A6, A5, …A0 (A6 = msb. A0 = lsb) R/W bit: “0” for writing Values: 8 bits = D7, D6, …D0 (D7 = msb, D0 = lsb) Table 3. What to write: Field Comments Address: A 7-bit field, ranging from 0 to 21. MSB is written first. R/W bit: A 1-bit field, = “0” for writing Values: A number of octets (1-22 octets). MSB in every octet is written first. The first octet is written to the control register with the specified address (=”Address”). The next octet (if there is one) is written to the control register with address = “Address + 1” and so on. “Address” and “R/W bit” together make 1 octet. In addition, 1 octet with programming bits is entered. In total, 2 octets are clocked into the MICRF506. How to write: • Bring CS high • Use SCLK and IO to clock in the 2 octets • Bring CS low CS Table 2. SCLK How to write: IO Bring CS active to active to start a write sequence. The active state of the CS line is “high.” Use the SCLK/IO serial interface to clock “Address” and “R/W” bit and “Values” into the MICRF506. MICRF506 will sample the IO line at negative edges of SCLK. Make sure to change the state of the IO line before the negative edge. Refer to figures below. Bring CS inactive to make an internal load-signal and complete the write-sequence. Note: there is an exception to this point. If the programming bit called “load_en” (bit0 in ControlRegister0) is “0”, then no load pulse is generated. July 2006 A6 A5 A0 Address of register i RW D7 RW D6 D2 D1 D0 Data to write into register i Internal load pulse made here Figure 1. In Figure 1, IO is changed at positive edges of SCLK. The MICRF506 samples the IO line at negative edges. The value of the R/W bits is always “0” for writing. 10 M9999-092904 +1 408-944-0800 Micrel MICRF506BML/YML Writing to n Registers having Incremental Addresses In addition to entering all bytes, it is also possible to enter a set of n bytes, starting from address i = “A6, A5, … A0”. Typical example: Clock in a new set of frequency dividers (i.e. change the RF frequency). “Incremental addresses”. Registers to be written are located in i, i+1, i+2. Writing to All Registers After a power-on, all writable registers should be written. This is described here. Writing to all register can be done at any time. To get the simplest firmware, always write to all registers. The price to pay for the simplicity is increased write-time, which leads to increased time to change the way the MICRF506 works. What to write What to write Field Comments Field Comments Address: Address: ‘000000’ (address of the first register to write to, which is 0) 7 bit = A6, A5, …A0 (A6 = msb. A0 = lsb) (address of first byte to write to) R/W bit: “0” for writing R/W bit: “0” for writing Values: n* 8 bits = D7, D6, …D0 (D7 = msb, D0 = lsb) (written to control reg. with address ”i”) D7, D6, …D0 (D7 = msb, D0 = lsb) (written to control reg. with address ”i+1”) st Values: 1 Octet: wanted values for ControlRegister0. 2nd Octet: wanted values for ControlRegister1 and so on for all of the nd octets. So the 22 octet wants values for ControlRegister21. Refer to the specific sections of this document for actual values. D7, D6, …D0 (D7 = msb, D0 = lsb) (written to control reg. with address ”i+n-1”) Table 4. “Address” and “R/W bit” together make 1 octet. In addition, 22 octets with programming bits are entered. In total, 23 octets are clocked into the MICRF506. Table 5. “Address” and “R/W bit” together make 1 octet. In addition, n octets with programming bits are entered. Totally, 1 +n octets are clocked into the MICRF506. How to write: • Bring CS high • Use SCLK and IO to clock in the 23 octets How to write: • Bring CS low Refer to the figure in the next section, “Writing to n registers having incremental addresses”. • Bring CS high • Use SCLK and IO to clock in the 1 + n octets • Bring CS low In Figure 1, IO is changed at positive edges of SCLK. The MICRF506 samples the IO line at negative edges. The value of the R/W bits is always “0” for writing. CS SCLK IO A6 A5 A0 Address of first register to write to, register i RW D7 D6 D2 RW Data to write into register i D1 D0 Data to write into register i+1 Internal load pulse made here Figure 2. July 2006 11 M9999-092904 +1 408-944-0800 Micrel MICRF506BML/YML Reading n registers from MICRF506 Writing to n Registers having Non-Incremental Addresses Registers with non-incremental addresses can be written to in one write-sequence as well. Example of non-incremental addresses: “0,1,3”. However, this requires more overhead, and the user should consider the possibility to make a “continuous” update, for example, by writing to “0,1,2,3” (writing the present value of “2” into “2”). The simplest firmware is achieved by always writing to all registers. Refer to previous sections. This write-sequence is divided into several subparts: • CS SCLK A6 IO A5 A0 RW D7 Address of register i D0 D6 RWData read from reg. i Simple time IO Input IO Output Figure 3. In the figure, 1 register is read. The address is A6, A5, … A0. A6 = msb. The data read out is D7, D6, …D0. The value of the R/W bit is always “1” for reading. SCLK and IO together form a serial interface. SCLK is applied externally for reading as well as for writing. Disable the generation of load-signals by clearing bit “load_en” (bit0 in ControlRegister0) • Repeat for each group of register having incremental addresses: o Bring CS active o Enter first address for this group, R/W bit and values o Bring CS inactive o Finally, enable and make a loadsignal by setting “load_en” Refer to the previous sections for how to write to 1 or n (with incremental addresses) registers in the MICRF506. Reading from the control registers in MICRF506 The “read-sequence” is: 1. Enter address and R/W bit 2. Change direction of IO line 3. Read out a number of octets and change IO direction back again. It is possible to read all, 1 or n registers. The address to read from (or the first address to read from) can be any valid address (0-22). Reading is not destructive, i.e. values are not changed. The IO line is output from the MICRF506 (input to user) for a part of the read-sequence. Refer to procedure description below. A read-sequence is described for reading n registers, where n is number 1-23. • Bring CS active • Enter address to read from (or the first address to read from) (7 bits) and • The R/W bit = 1 to enable reading • Make the IO line an input to the user (set pin in tristate) • Read n octets. The first rising edge of SCLK will set the IO as an output from the MICRF506. MICRF will change the IO line at positive edges. The user should read the IO line at the negative edges. • Make the IO line an output from the user again. Programming interface timing Figure 4 and Table 6 shows the timing specification for the 3-wire serial programming interface. Tcsr traise tfall Tper Thigh Tread Tlow Tscl Twrite SCLK CS IO A6 A5 A0 RW Address Register D7 D6 D2 D1 D0 Data Register LOAD Figure 4. July 2006 12 M9999-092904 +1 408-944-0800 Micrel MICRF506BML/YML Values Symbol Parameter Tper Min. period of SCLK 50 ns Thigh Min. high time of SCLK 20 ns Tlow Min. low time of SCLK 20 ns tfall Max. time of falling edge of SCLK 1 µs trise Max. time of rising edge of SCLK 1 µs Tcsr Max. time of rising edge of CS to falling edge of SCLK 0 ns Tcsf Min. delay from rising edge of CS to rising edge of SCLK 5 ns Twrite Min. delay from valid IO to falling edge of SCLK during a write operation 0 ns Tread Min. delay from rising edge of SCLK to valid IO during a read operation (assuming load capacitance of IO is 25pF) 75 ns Min. Typ. Max. Units Power on Reset When applying voltage to the MICRF506 a power on reset state is entered. During the time period of power on reset, the MICRF506 should be considered to be in an unknown state and the user should wait until completed (See Table 6). The power on reset timing given in table 6 is covering all conditions and should be treated as a maximum delay time. In some application it might be beneficial to minimize the power on reset time. In these cases we recommend to follow below procedure: Table 6. Timing Specification for the 3-wire Programming Interface July 2006 13 M9999-092904 +1 408-944-0800 Micrel MICRF506BML/YML Enter/read msb in every octet first. Programming summary • Use CS, SCLK, and IO to get access to the control registers in MICRF506. • SCLK is user-controlled. • Write to the MICRF506 at positive edges (MICRF506 reads at negative edges). • Read from the MICRF506 at negative edges (MICRF506 writes at positive edges) • After power-on: Write to the complete set of control registers. • Address field is 7 bits long. Enter msb first. • R/W bit is 1 bit long (“1” for read, “0” for write) • Address and R/W bit together make 1 octet • All control registers are 8 bits long. July 2006 14 • Always write 8 bits to/read 8 bits from a control register. This is the case for registers with less than 8 used programming bits as well. • Writing: Bring CS high, write address and R/W bit followed by the new values to fill into the addressed control register(s) and bring CS low for loading, i.e. activation of the new control register values (“load_en” = 1). • Reading: Bring CS high, write address and R/W bit, set IO as an input, read present contents of the addressed control register(s), bring CS low and set IO an output. M9999-092904 +1 408-944-0800 Micrel MICRF506BML/YML Frequency Synthesizer The MICRF506 frequency synthesizer consists of a voltage-controlled oscillator (VCO), a crystal oscillator, dual modulus prescaler, programmable frequency dividers and a phase-detector. The loop-filter is external for flexibility and can be a simple passive circuit. The phase detector compares frequencies of two signals and produces an error signal which is proportional to the difference between the input frequencies. The error signal is used to control a voltage-controlled oscillator (VCO) which creates an output frequency. The output frequency is fed through a frequency divider back to the input of the phase detector, producing a feedback loop. If the output frequency drifts, the error signal will increase, driving the frequency in the opposite direction so as to reduce the error. Thus the output is locked to the frequency at the other input. This input is called the reference and is derived from a crystal oscillator, which is very stable in frequency. The block diagram below shows the basic elements and arrangement of a PLL based frequency synthesizer. The MICRF506 has a dual modulus prescaler for increased frequency resolution. In a dual modulus prescaler the main divider is split into two parts, the main part N and an additional divider A, where A < N. Both dividers are clocked from the output of the dual-modulus prescaler, but only the output of the N divider is fed into the phase detector. The prescaler will first divide by 16. Both N and A count down until A reaches zero, at which point the prescaler is switched to a division ratio 16+1. At this point, the divider N has completed A counts. Counting continues until N reaches zero, which is an additional N-A counts. At this point the cycle repeats. Loop filter 1800MHz A-Divider VCO Prescaler PA N-Divider Charge pump Div/4 Phase detector XCO M-Divider A6…A0 D7 D6 D5 D4 0001010 - - A0_5 A0_4 A0_3 A0_2 A0_1 A0_0 0001011 - - - - N0_11 N0_10 N0_9 N0_8 0001100 N0_7 N0_6 N0_5 N0_4 N0_3 N0_2 N0_1 N0_0 0001101 - - - - M0_11 M0_10 M0_9 M0_8 0001110 M0_7 M0_6 M0_5 M0_4 M0_3 M0_2 M0_1 M0_0 0001111 - - A1_5 A1_4 A1_3 A1_2 A1_1 A1_0 0010000 - - - - N1_11 N1_10 N1_9 N1_8 0010001 N1_7 N1_6 N1_5 N1_4 N1_3 N1_2 N1_1 N1_0 0010010 - - - - M1_11 M1_10 M1_9 M1_8 0010011 M1_7 M1_6 M1_5 M1_4 M1_3 M1_2 M1_1 M1_0 July 2006 15 D3 D2 D1 D0 M9999-092904 +1 408-944-0800 Micrel MICRF506BML/YML The lengths of the N, M, and A registers are 12, 12 and 6 respectively The values can be calculated from the following formula: fPhD CL = The parasitic capacitance is the pin input capacitance and PCB stray capacitance. Typically, the total parasitic capacitance is around 6pF. For instance, for a 9pF load crystal the recommended values of the external load capacitors are 5.6pF. It is also possible to tune the crystal oscillator internally by switching in internal capacitance using 5 tune bits XCOtune4 – XCOtun0. When XCOtune4 – XCOtune0 = 0 no internal capacitors are connected to the crystal pins. When XCOtune4 – XCOtune0 = 1 all of the internal capacitors are connected to the crystal pins. Figure 6 shows the tuning range for two different capacitor values, 1.5pF and no capacitors. The crystal used is a TN4-26011 from Toyocom. Specification: Package TSX-10A, Nominal frequency 16.000000 MHz, frequency tolerance ±10ppm, frequency stability ±9ppm, load capacitance 9pF, pulling sensitivity 15ppm/pF. When the external capacitors are set to 1.5pF and the XCOtune=16, the total capacitance will normally be ~9pF. f f VCO fRF × 2 = XCO = = (16 × N + A ) × 2 (16 × N + A ) M M≠0 1≤A<N where fPhD: Phase detector comparison frequency fXCO: Crystal oscillator frequency fVCO: Voltage controlled oscillator frequency fRF: RF carrier frequency There are two sets of each of the divide factors (i.e. A0 and A1). If modulation by using the dividers is selected (that is Modulation1=1, Modulation0=0), the two sets should be programmed to give two RF frequencies, separated by two times the specified frequency deviation. For all other modulation methods, and also in receive mode, the 0-set will be used. Crystal Oscillator (XCO) Adr D7 D6 D5 0001001 ‘0’ ‘0’ ‘1’ D4 D3 D2 XCOtune4 XCOtune3 XCOtune2 D1 D0 XCOtune1 XCOtune0 1 + Cparasitic 1 1 + C10 C11 100,0 80,0 60,0 40,0 [ppm] The crystal oscillator is a very critical block. As the crystal oscillator is a reference for the RF output frequency and also for the LO frequency in the receiver, very good phase and frequency stability is required. The schematic of the crystal oscillator’s external components for 16MHz are shown in Figure 5. 2x1.5pF 20,0 2x0pF 0,0 -20,0 -40,0 -60,0 0 8 16 24 32 XCO bitvalue Y1 TSX-10A Pin 24 XTALOUT C10 5.6pF Pin 23 XTALIN Figure 6. XCO Tuning The start up time is given in Table 7. As can be seen, more capacitance will slow down the start up time. The start-up time of a crystal oscillator is typically around a millisecond. Therefore, to save current consumption, the XCO is turned on before any other circuit block. During start-up the XCO amplitude will eventually reach a sufficient level to trigger the Mcounter. After counting 2 M-counter output pulses the rest of the circuit will be turned on. The current consumption during the prestart period is approximately 280µA. C11 5.6pF Figure 5. Crystal Oscillator Circuit The crystal should be connected between pins XTALIN and XTALOUT (pin 23 and 24). In addition, loading capacitors for the crystal are required. The loading capacitor values depend on the total load capacitance, CL, specified for the crystal. The load capacitance seen between the crystal terminals should be equal to CL for the crystal to oscillate at the specified frequency. July 2006 16 M9999-092904 +1 408-944-0800 Micrel MICRF506BML/YML XCOtune Start-up Time (µs) 0 590 A6..A0 D7 D6 D5 D4 D3 D2 D1 D0 1 590 0000011 ‘1’ ‘1’ ‘0’ VCO_IB2 VCO_IB1 VCO_IB0 VCO_freq1 VCO_freq0 2 700 4 700 8 810 16 1140 31 2050 VCO The VCO has no external components. If has three bit to set the bias current and two bit to set the VCO frequency. These five bit are set by the RF frequency, as follows: Table 7. Typical values with CEXT = 1.5pF If an external reference is used instead of a crystal, the signal shall be applied to pin 24, XTALOUT. Due to internal DC setting in the XCO, an AC coupling is recommended to be used between the external reference and the XTALOUT-pin. RF freq. VCO_IB2 VCO_IB1 VCO_IB0 410MHz 1 0 1 VCO_freq1 VCO_freq0 0 1 410-423MHz 1 0 1 0 1 423-436MHz 1 0 0 1 0 436-450MHz 0 1 1 1 1 Table 8. VCO Bit Setting The bias bit will optimize the phase noise, and the frequency bit will control a capacitor bank in the VCO. The tuning range, the RF frequency versus varactor voltage, is dependent on the VCO frequency setting, and can be shown in Figure 7. When the tuning voltage is in the range from 0.9V to 1.4V, the VCO gain is at its maximum, approximately 32 to 35MHz/V. It is recommended that the varactor voltage stays in this range. The input capacitance at the varactor pin must be taken into consideration when designing the PLL loop filter. This is most critical when designing a loop filter with high bandwidth, which gives relatively small component values. The input capacitance is approximately 6pF. VCO frequency gain, Vdd=2.5V 480 470 460 Freq [MHz] 450 11 10 01 00 440 430 420 410 400 390 380 0 0.4 0.8 1.2 1.6 2 2.4 V_varactor [V] Figure 7. RF Frequency vs. Varactor Voltage and VCO Frequency bit (VDD = 2.25V) July 2006 17 M9999-092904 +1 408-944-0800 Micrel MICRF506BML/YML Table 9 shows three different loop filters, the two first for VCO modulation and the last one for modulation using the internal dividers. The component values are calculated with RF frequency = 434MHz, VCO gain = 32MHz/V and charge pump current = 125µA. Other settings are shown in the table. The varactor pin capacitance (pin 29) of 5pF does not influence on the component values for the two filters with lowest bandwidth. Charge Pump A6..A0 D7 D6 D5 D4 D3 D2 D1 D0 0000010 CP_HI SC_by ‘0’ PA_by OUTS3 OUTS2 OUTS1 OUTS1 The charge pump current can be set to either 125µA or 500µA by CP_HI (‘1’ → 500µA). This will affect the loop filter component values, see “PLL Filter” section. In most cases, the low current is best suited. For applications using phase detector frequency and high PLL bandwidth, the 500µA can be a better choice. Baud Rate (kbaud/sec) PLL Filter The design of the PLL filter will strongly affect the performance of the frequency synthesizer. The PLL filter is kept externally for flexibility. Input parameters when designing the loop filter for the MICRF506 are mainly the modulation method and the bit rate. These choices will also affect the switching time and phase noise. The frequency modulation can be done in two different ways with the MICRF506, either by VCO modulation or by modulation with the internal dividers (see chapter Frequency modulation for further details). In the first case, the PLL needs to lock on a new carrier frequency for every new data bit. Now the PLL bandwidth needs to be adequately high. It is recommended to use a third order filter to suppress the phase detector frequency, as this is not suppressed as much as when doing modulation on the VCO with a lower bandwidth filter. A schematic for a second (R2=0 and C3=NC) and third order loop filter is shown in Figure 8. Pin 27 CP_OUT C1 C2 C1 C2 R1 R2 C3 NC VCO >38.4 0.8 56 100 10nF 100nF 6.2kΩ 0 VCO >125 3,2 56 100 680pF 6.8nF 22kΩ 0 NC Divider <20 13 86 500 150pF 10nF 18kΩ 82kΩ 4.7pF Table 9. Loop Filter Components Values Lock Detect A6..A0 D7 D6 D5 D4 D3 D2 D1 D0 0000001 Modulation1 Modulation0 ‘0’ ‘0’ RSSI_en LD_en PF_FC1 PF_FC0 A lock detector can be enabled by setting LD_en = 1. When pin LD is high, it indicates that the PLL is in lock. Modes of Operation Pin 29 VARIN R2 Phase PLL Detector Phase BW Margin(˚) Freq. (kHz) (kHz) A6..A0 D7 D6 D5 D4 D3 D2 D1 D0 0000000 LNA_by PA2 PA1 PA0 Sync_en Mode1 Mode0 Load_en Mode1 Mode0 State 0 0 Power down Keeps register configuration Comments 0 1 Standby Only crystal oscillator running 1 0 Receive Full receive 1 1 Transmit Full transmit ex PA state C3 R1 Figure 8. Second and Third Order Loop Filter July 2006 18 M9999-092904 +1 408-944-0800 Micrel MICRF506BML/YML Transceiver Sync/Non-Synchronous Mode A6..A0 D7 D6 D5 D4 D3 D2 D1 D0 0000000 LNA_by PA2 PA1 PA0 Sync_en Mode1 Mode0 Load_en 0000110 - Mod_clkS2 Mod_clkS1 Mod_clkS0 BitSync_clkS2 BitSync_clkS1 BitSync_clkS0 BitRate_clkS2 0000111 BitRate_clkS1 BitRate_clkS0 RefClk_K5 RefClk_K4 RefClk_K3 RefClk_K2 RefClk_K1 RefClk_K0 Sync_en State Comments 0 Rx: Bit synchronization off Transparent reception of data 0 Tx: DataClk pin off Transparent transmission of data 1 Rx: Bit synchronization on Bit-clock is generated by transceiver 1 Tx: DATACLK pin on Bit-clock is generated by transceiver MICRF506 is defined as “Master” and provides a data clock that allows users to utilize low cost micro controller reference frequency. The data interface is defined in such a way that all user actions should take place on falling edge and is illustrated Figure 9 and 10. The two figures illustrate the relationship between DATACLK and DATAIXO in receive mode and transmit mode. MICRF506 will present data on rising edge and the “USER” sample data on falling edge in receive mode. When Sync_en = 1, it will enable the bit synchronizer in receive mode. The bit synchronizer clock needs to be programmed, see chapter Bit synchronizer. The synchronized clock will be set out on pit DATACLK. In transmit mode, when Sync_en = 1, the clock signal on pin DATACLK is a programmed bit rate clock. Now the transceiver controls the actual data rate. The data to be transmitted will be sampled on rising edge of DATACLK. The micro controller can therefore use the negative edge to change the data to be transmitted. The clock used for this purpose, BITRATE_CLK, is programmed in the same way as the modulator clock and the bit synchronizer clock: fBITRATE_CL K = DATAIXO fXCO DATACLK Refclk_K × 2(7-BitRate_cl kS ) Figure 10. Data interface in Receive Mode where: fBITRATE_CLK: The clock frequency used to control the bit rate, should be equal to the bit rate (bit rate of 20 kbit/sec requires a clock requency of 20kHz) fXCO: Crystal oscillator frequency Refclk_K: 6 bit divider, values between 1 and 63 BitRate_clkS: Bit rate setting, values between 0 and 6 The User presents data on falling edge and MICRF506 samples on rising edge in transmit mode. DATAIXO DATACLK Figure 11. Data interface in Transmit Mode When entering transmit mode it is important to keep DATAIXO in tri-state from the time Tx-mode is entered until user starts sending data. The data is provided directly to the modulation circuit and violation of this may/will cause abnormal behavior. Depending upon the chosen FSK modulation, some sort of encoding might be needed. The different modulation types and encoding is described in chapter Frequency modulation. Data Interface The MICRF506 interface can be divided in to two separate interfaces, a “programming interface” and a “Data interface”. The “programming interface” has a three wire serial programmable interface and is described in chapter Programming. The “data interface” can be programmed to sync/non-synchronous mode. In synchronous mode the July 2006 19 M9999-092904 +1 408-944-0800 Micrel MICRF506BML/YML Receiver The receiver is a zero intermediate frequency (IF) type in order to make channel filtering possible with low-power integrated low-pass filters. The receiver consists of a low noise amplifier (LNA) that drives a quadrature mixer pair. The mixer outputs feed two identical signal channels in phase quadrature. Each channel include a pre-amplifier, a third order SallenKey RC lowpass filter from strong adjacent channel signals and finally a limiter. The main channel filter is a switched-capacitor implementation of a six-pole elliptic lowpass filte. The elliptic filter minimizes the total capacitance required for a given selectivity and dynamic range. The cut-off frequency of the SallenKey RC filter can be programmed to four different frequencies: 100kHz, 150kHz, 230kHz and 340kHz. The demodulator demodulates the I and Q channel outputs and produces a digital data output. If detects the relative phase of the I and Q channel signal. If the I channel signal lags the Q channel, the FSK tone frequency lies above the LO frequency (data ‘1’). If the I channel leads the Q channel, the FSK tone lies below the LO frequency (data ‘0’). The output of the receiver is available on the DataIXO pin. A RSSI circuit (receive signal strength indicator) indicates the received signal level. Figure 12. LNA Input Impedance Sallen-Key Filters A6..A0 D7 D6 D5 D4 D3 D2 D1 D0 LNA_by PA2 PA1 PA0 Sync_en Mode1 Mode0 Load_en A low noise amplifier in RF receivers is used to boost the incoming signal prior to the frequency conversion process. This is important in order to prevent mixer noise from dominating the overall front-end noise performance. The LNA is a twostage amplifier and has a nominal gain of approximately 23dB at 434MHz. The front end has a gain of about 35dB to 38dB. The gain varies by 11.5dB over a 2.0V to 2.5V variation in power supply. The LNA can be bypassed by setting bit LNA_by to ‘1’. This can be useful for very strong input signal levels. The front-end gain with the LNA bypassed is about 12dB. The mixers have a going of about 10dB at 434MHz. The differential outputs of the mixers can be made available at pins IchOut and QchOut. The output impedance of each mixer is about 8kΩ. The input impedance is close to 50Ω as shown in Figure 12, giving an input reflection of about -20dB. The receiver does not require any matching network to optimize the gain. However, a matching network is recommended for harmonic suppression in Tx and for improved selectivity in Rx. July 2006 D7 D6 D5 D4 D3 D2 D1 D0 0000001 Modulation1 Modulation0 ‘0’ ‘0’ RSSI_en LD_en PF_FC1 PF_FC0 Each channel includes a pre-amplifier and a prefilter, which is a three-pole Sallen-Key lowpass filter. It protects the following switched-capacitor filter from strong adjacent channel signals, and it also works as an anti-aliasing filter. The preamplifier has a gain of 22dB. The maximum output voltage swing is about 1.4Vpp for a 2.25V power supply. In addition, the IF amplifier also performs offset cancellation. Gain varies by less than 0.5dB over a 2.0 – 2.5V variation in power supply. The third order Sallen-Key lowpass filter is programmable to four different cut-off frequencies according to the table below: Front End 0000000 A6..A0 20 PF_FC1 PF_FC0 Cut-off Freq. (kHz) 0 0 100 0 1 150 1 0 230 1 1 340 M9999-092904 +1 408-944-0800 Micrel MICRF506BML/YML Baudrate: The baud rate given is bit/sec Switched Capacitor Filter A6..A0 D7 D6 D5 D4 D3 D2 D1 D0 0001000 ‘1’ ScClk_X2 ‘0’ ScClk4 ScClk3 ScClk2 ScClk1 ScClk0 RSSI The main channel filter is a switched-capacitor implementation of a six-pole elliptic low pass filter. The elliptic filter minimized the total capacitance required for a given selectivity and dynamic range. The cut-off frequency of the switched-capacitor filter is adjustable by changing the clock frequency. The clock frequency is designed to be 20 times the cut-off frequency. The clock frequency is derived from the reference crystal oscillator. A programmable 6-bit divider divides the frequency of the crystal oscillator. To generate the correct nonoverlapping clock-phases needed by the filter this frequency is then divided by 4. The cut-off frequency of the filter is given by: A6..A0 D7 D6 D5 D4 D3 D2 D1 D0 0000001 Modulation1 Modulation0 ‘0’ ‘0’ RSSI_en LD_en PF_FC1 PF_FC0 RSSI 33kohm, 1nF, 125kbps, BW=200kHz, Vdd=2.5V 2.2 2 RSSI [V] 1.8 1.6 1.4 1.2 1 0.8 0.6 -125 -115 -105 -95 -85 -75 -65 -55 -45 -35 -25 Pin [dBm] Figure 13. RSSI Voltage fCUT = fXCO 40 ⋅ ScClk Pin 14 RSSI fCUT: Filter cutoff frequency fXCO: Crystal oscillator frequency ScClk: Switched capacitor filter clock, bits ScClk5-0 For instance, for a crystal frequency of 16MHz and if the 6 bit divider divides the input frequency by 4 the cut-off frequency of the SC filter is 16MHz/(40 x 4) = 100kHz. 1st order RC low pass filters are connected to the output of the SC filter-to-filter the clock frequency. The lowest cutoff frequency in the pre- and the main channel filter must be set so that the received signal is passed with no attenuation, which is frequency deviation plus modulation. If there are any frequency offset between the transmitter and the receiver, this must also be taken into consideration. A formula for the receiver bandwidth can be summarized as follows: R2 33k C10 1nF Figure 14. RSSI Network A Typical plot of the RSSI voltage as function of input power is shown in Figure 13. The RSSI has a dynamic range of about 50dB from about -110dBm to -60dBm input power. The RSSI can be used as a signal presence indicator. When a RF signal is received, the RSSI output increases. This could be used to wake up circuitry that is normally in a sleep mode configuration to conserve battery life. Another application for which the RSSI could be used is to determine if transmit power can be reduced in a system. If the RSSI detects a strong signal, if could tell the transmitter to reduce the transmit power to reduce current consumption. fBW = + fOFFSET + fDEV + Baudrate / 2 where fBW: Needed receiver bandwidth, fcut above should not be smaller than fBW [Hz] fOFFSET: Total frequency offset between receiver and transmitter [Hz] fDEV: Single-sided frequency deviation, see chapter Modulator on how to calculate [Hz] July 2006 RSSI 21 M9999-092904 +1 408-944-0800 Micrel MICRF506 where FEE is the value stored in the FEE register, (Fp is the single sided frequency deviation, P is the number of symbols/data bit counted and R is the symbol/data rate. A positive Foffset means that the received signal has a higher frequency than the receiver frequency. To compensate for this, the receivers XCO frequency should be increased (see ANNEX A) on how to tune the XCO frequency based on the FEE value). It is recommended to use Mode UP+DN for two reasons, you do not need to know the actual frequency deviation and this mode gives the best accuracy. FEE A6..A0 D7 D6 D5 D4 D3 D2 D1 D0 0010101 - - - - FEEC_3 FEEC_2 FEEC_1 FEEC_0 0010110 FEE_7 FEE_6 FEE_5 FEE_4 FEE_3 FEE_2 FEE_1 FEE_0 The Frequency Error Estimator (FEE) uses information from the demodulator to calculate the frequency offset between it’s receive frequency and the transmitter frequency. The output of the FEE can be used to tune the XCO frequency, both for production calibration and for compensation for crystal temperature drift and aging. The inputs to the FEE circuit are the up and down pulses from the demodulator. Every time a ‘1’ is updated, an UP-pulse is coming out of the demodulator, and the same with the DN-pulse every time the ‘0’ is updated. The expected number of pulses for every received symbol is 2 times the modulation index (∆). The FEE can operate in three different modes; counting only UP-pulses, only DN-pulses or counting UP+DN pulses. The number of received symbols to be counted is either 8, 16, 32 or 64. This is set by the FEEC_0…FEEC_3 control bit, as follows: FEEC_1 FEEC_0 0 0 FEE Mode Off 0 1 Counting UP pulses 1 0 Counting DN pulses 1 1 Counting UP and DN pulses. UP increments the counter, DN decrements it. FEEC_3 FEEC_2 0 0 8 0 1 16 1 0 32 1 1 65 No. of symbols used for the measurement Table 10. FEEC Control Bit The result of the measurement is the FEE value, this can be read from register with address 0010110b. Negative values are stored as a binary no between 0000000 and 1111111. To calculate the negative value, a two’s complement of this value must be performed. Only FEE modes where DN-pulses are counted (10 and 11) will give a negative value. When the FEE value has been read, the frequency offset can be calculated as follows: Mode UP: Foffset = R/(2P)x(FEE-∆Fp) Mode DN: Foffset = R/(2P)x(FEE+∆Fp) Mode UP+DN: Foffset = R/(4P)x(FEE) July 2006 22 M9999-092904 +1 408-944-0800 Micrel MICRF506BML/YML Bit Synchronizer A6..A0 D7 D6 D5 D4 D3 D2 D1 D0 0000110 - ModclkS2 ModclkS1 ModclkS0 BitSync_clkS2 BitSync_clkS1 BitSync_clkS0 BitRate_clkS2 0000111 BitRate_clkS1 BitRate_clkS0 RefClk_K5 RefClk_K4 RefClk_K3 RefClk_K2 RefClk_K1 RefClk_K0 A bit synchronizer can be enabled in receive mode by selecting the synchronous mode (Sync_en=1). The DataClk pin will output a clock with twice the frequency of the bit rate (a bit rate of 20 kbit/sec gives a DataClk of 20 kHz). A received symbol/bit on DataIXO will be output on rising edge of DataClk. The micro controller should therefore sample the symbol/bit on falling edge of DataClk. The bit synchronizer uses a clock which needs to be programmed according to the bit rate. The clock frequency should be 16 times the actual bit rate (a bit rate of 20 kbit/sec needs a bit synchronizer clock with frequency of 320 kHz). The clock frequency is set by the following formula: fBITSYNC_CLK = July 2006 where fBITSYNC_CLK: The bit synchronizer clock frequency (16 times higher than the bit rate) fXCO: Crystal oscillator frequency Refclk_K: 6 bit divider, values between 1 and 63 BitSync_clkS: Bit synchronizer setting, values between 0 and 7 Refclk_K is also used to derive the modulator clock and the bit rate clock. At the beginning of a received data package, the bit synchronizer clock frequency is not synchronized to the bit rate. When these two are maximum offset to each other, it takes 22 bit/symbols before synchronization is achieved. fXCO Refclk_K × 2 (7-BITSYNC_clk S ) 23 M9999-092904 +1 408-944-0800 Micrel MICRF506 Transmitter Power Amplifier A6..A0 D7 D6 D5 D4 D3 D2 D1 D0 0000000 LNA_by PA2 PA1 PA0 Sync_en Mode1 Mode0 Load_en 0000001 Modulation1 Modulation0 ‘0’ ‘0’ RSSI_en LD_en PF_FC1 PF_FC0 0000010 CP_HI SC_by ‘0’ PA_By OUTS3 OUTS2 OUTS1 OUTS0 The maximum output power is approximately 10dBm for a 50Ω load. For maximum output power the load seen by the PA must be resistive. Higher output power can be obtained by decreasing the load impedance. However, this will be in conflict with obtaining impedance match in the LNA. The output power is programmable in seven steps, with approximately 3dB between each step. This is controlled by bits PA2 – PA0. Frequency Modulation The power amplifier can be turned off by setting PA2 – PA0 = 0. For all other combinations the PA is on and has maximum power when PA2 – PA0 = 1. D6 D5 D4 D3 D2 D1 D0 Modulation1 Modulation0 ‘0’ ‘0’ RSSI_en LD_en PF_FC1 PF_FC0 Modulation1 Modulation0 L1 12nH 47pF 0 0 Closed loop modulation using modulator 0 1 Not in use 1 0 FSK applied using two sets of dividers 1 1 Not in use 15pF C6 fbaud_min = baud /s 4 fbaud_min: The minimum frequency of the baud rate [Hz] baud/s: Elements per second (encoded data) Figure 15. LC Filter This filter is designed for the 434MHz band with 50Ohm terminations. The component values may have to be tuned to compensate for the layout parasitics. This filter may also increase the receiver selectivity. July 2006 Modulation Type When Modulation1 and Modulation0 is 00, the modulator needs to be programmed properly, see “Modulator” section. The modulation signal will now be applied directly on the phase locked VCO. It is therefore important that the PLL bandwidth is not too high, as this will remove the modulation. See “PLL Filter” section on how to calculate the PLL components. When using the modulator the modulation signal is applied to the VCO and therefore some sort of encoding is needed. The level of encoding is determined by the PLL loop filter bandwidth and data rate. Two of the most common encoding techniques are Manchester encoding and 3B4B. Other encoding schemes may also be used. Manchester encoding is when one bit is encoded in to a two-bit word and is shown in Table 10. When using Manchester encoding the maximum overhead is 100%. When selecting PLL loop filter it is important to note that the min baud rate is equal to: ANT C4 18pF D7 0000001 Table 11. Modulation Bit Setting The PA will be bypassed if PA_by=1. Output power will drop ~22dB. It is still possible to control the power by PA2 – PA0. The output power varies about 3dB over power supply 2.0V to 2.5V and about 2dB over temperature -40˚C to +85˚C. The 2nd and 3rd harmonic of the PA are as follows: 2nd harmonic: <-16dBm 3rd harmonic: <-8dBm To reduce the emission of harmonics, an LC filter can be added between the ANT pin and the antenna as shown in Figure 15. C5 A6..A0 24 Data Word “0” “10” “1” “01” M9999-092904 +1 408-944-0800 Micrel MICRF506BML/YML When Modulation1 Modulation0 is 10, two sets of divider values need to be programmed. The formula for calculating the M, N and A values is given in chapter Frequency synthesizer. The divider values stored in the M0-, N0-, and A0- registers will be used when transmitting a ‘0’ and the M1-, N1-, and A1registers will be used to transmit a ‘1’. The difference between the two carrier frequencies corresponds to the double sided frequency modulation. Opposite from the modulation with the modulator, the PLL shall now lock on a new frequency for every change in the transmitted data. The PLL bandwidth therefore needs to be relatively high, higher bit rate requires a higher PLL bandwidth and vice versa. The data to be transmitted shall be applied to pin DataIXO (see chapter Transceiver sync-/non-synchronous mode on how to use the pin DataClk). The DataIXO pin is set as input in transmit mode and output in receive mode. When set as input, a weak voltage divider will set the level to Vdd/2, when it is not pulled up or down by the controller. When using the modulator, it is important that the DataIXO is kept tristated until the transmission shall begin (when PLL is in lock and the PA is turned on). When Data IXO is tristated, the PLL will lock on the LO frequency (used in receive mode). When DataIXO is set either high or low, the RF frequency will be shifted up or down, centered around the LO-frequency. This is only important when using the modulator, for the other modulation method, if DATAIXO is tristated, the M0-, N0- and A0-registers will be used. Table 12. Manchester Encoding Another much more efficient encoding type is 3B4B where three data bits are encoded into a four-bit word. The reason for encoding is to minimize the DC component in the modulated data. To have minimum DC component each four bit word should include two elements of “1” and two elements of “0”. Following this guidance only 6 out of 8 word complies and two encoded words needs special precaution. Whenever 000 and 111 data appear, the user must set/clear a flag that indicate if last encoded word was “Word A” and select the respective encoded word shown in Table 11. Data Word A Word B 000 1011 0100 001 1100 010 0011 011 1010 100 0101 101 1001 110 0110 111 1101 0010 Table 13. 3B4B Encoding Data bits Encoded words Comments 000 000 000 000 000 1011 0100 1011 0100 1011 A Flag indicates if “Word A” has been used 111 111 010 110 000 1101 0010 0011 0110 1011 A Flag indicates if “Word A” has been used Table 14. Example of 3B4B encoding July 2006 25 M9999-092904 +1 408-944-0800 Micrel MICRF506BML/YML Modulator A6..A0 D7 D6 D5 D4 D3 D2 D1 D0 0000100 Mod_F2 Mod_F1 Mod_F0 Mod_I4 Mod_I3 Mod_I2 Mod_I1 Mod_I0 0000101 - - ‘0’ ‘1’ Mod_A3 Mod_A2 Mod_A1 Mod_A0 0000110 - Mod_clkS2 Mod_clkS1 Mod_clkS0 BitSync_clkS2 BitSync_clkS1 BitSync_clkS0 BitRate_clkS2 0000111 BitRate_clkS1 BitRate_clkS0 RefClk_K5 RefClk_K4 RefClk_K3 RefClk_K2 RefClk_K1 RefClk_K0 The modulator will create a waveform with programmable amplitude and frequency. This waveform is fed into a modulation varactor in the VCO, which will create the desired frequency modulation. The frequency spectrum can be narrowed by increasing the rise-and fall times of the waveform. The modulator waveform is created by charging and discharging a capacitor. A modulator clock controls the timing, as shown in Figure19. For every rise-and fall edge, 4 clock periods are being used. The charging current during these 4 clock periods are not equal, this is to reduce the high frequency components in the waveform, which in turn will narrow the frequency spectrum. The frequency deviation can be set in three different ways, as will be explained below. A formula for setting the desired deviation is given at the end of this chapter. Mod_clka Mod_clkb Mod_clkb > Mod_clka Figure 20. Two Different Modulator Clock Setting A fMOD_CLK of 8 times the bit rate (as in Figure 20) corresponds to a signal filtered in a Gaussian filter with a Bandwidth Period product (BT) of 1. When BT is increased, the waveform will be less filtered. Minimum BT is 1 (fMOD_CLK is 8 times the bitrate). Figure 20 shows two waveforms with BT=1 and BT=2, i.e. the fMOD_CLK is 8 and 16 times higher than the bit rate. When changing the BT factor, the charge-and discharge times will also be changed, and therefore the frequency deviation, as shown in Figure 19. Modulator Clock Modulator Current The current used during the rise- and fall times can be programmed with the Mod_I4..Mod_I0 bit, the last one being LSB. Figure 21 shows two waveforms generated with two different currents, where Mod _ Ia > Mod _ Ib . Higher current will give a higher frequency deviation and vice versa. The effect of modulator clock and MOD_1 is illustrated by: Modulator Waveform Figure 19. Modulator Waveform and Clock Modulator Clock The modulator clock frequency is set by: f MPOD_CLK = fDEVIATION × f XCO Refclk_K × 2(7 − Mod_clkS ) To avoid saturation in the modulator it is important not to exceed maximum Mod_I. Maximum Mod_I for a given fMOD_clk is given by: where fMOD_CLK is the modulator clock shown in Figure 19, fXCO is the crystal oscillator frequency Refclk_K is a 6 bit number and Mod_clkS is a 3 bit number. Mod_clkS can be set to a value between 0 and 7. The modulator clock frequency should be set according to the bit rate and shaping. July 2006 MOD_1 fMOD_CLK MOD_IMAX = INT(fMOD_CLK ⋅ 28 × 10 6 ) - 1 where INT() returns the integer part of the argument. 26 M9999-092904 +1 408-944-0800 Micrel MICRF506BML/YML Mod_la Mod_filter on Mod_lb Mod_filter off Mod_la > Mod_lb Figure 23. Modulator Waveform with and without Filtering Figure 21. Two Different Modulator Current Settings Mod_F=0 disables the modulator filter and Mod_F=7 gives most filtering. Figure 22 shows a waveform with and without the filter. Modulator Attenuator A third way to set the deviation is by programming the modulator attenuator, Mod_A2..Mod_A0, the last being LSB. The purpose of the attenuator is to allow small deviations when the bit rate is small and/or the BT is small (these settings will give a relatively slow modulator clock, and therefore long rise- and fall times, which in turn results in large frequency deviations). In addition, the attenuator will improve the resolution in the modulator. Calculation of the Frequency Deviation The parameters influencing the frequency deviation can be summarized in the following equations: fMOD_CLK = Mod_Aa fDEV = Mod_Ab fXCO: fRF: Refclk_K: Figure 22. Two Different Modulator Attenuator Settings The effect of the attenuator is given by: fDEVIATION × Mod_clkS: 1 1+ Mod_A fMOD_CLK: b A _ d o M a A _ d o M Figure 22 shows two waveforms with different attenuator setting: < . If Mod_A is increased, the frequency deviation is lowered and vice versa. Mod_I: Mod_A: C1: C2: Modulator Filter To reduce the high-frequency components in the generated waveform, a filter with programmable cutoff frequency can be enabled. This is done using Mod_F2..Mod_F0, the least one being LSB. The Mod_F should be set according to the formula: July 2006 Mod_I 1 × × (C1 + C 2 × fRF ) fMOD_CLK 1+ Mod_A Where: fDEV: Mod_Ab > Mod_Ab 27 fXCO Refclk_K × 2 (7−Mod_clkS ) Single sided frequency deviation [Hz] Crystal oscillator frequency [Hz] Center frequency [Hz] 6 bit divider, values between 1 and 63 Modulator clock setting, values between 0 and 7 Modulator clock frequency, derived from the crystal frequency, Refclk_K and Mod_clkS Modulator current setting, values between 0 and 31 Modulator attenuator setting, values between 0 and 15 -2.17·1010 82 M9999-092904 +1 408-944-0800 Micrel MICRF506BML/YML If FEE > 0: LO is too low, increase LO by decreasing XCO_tune value v.v. for FEE < 0 The modulator filter will not influence on the frequency deviation as long as the programmed cutoff frequency is above the actual bit rate. The frequency deviation must be programmed so that the modulation index (2 x single sided frequency deviation/Baudrate [bps]) always is greater than or equal to 2 including the total frequency offset between the receiver and the transmitter: FEE field holds a number in the range -128, … , 127. However, it keeps counting above/below the range, which is: If FEE = -128 and still counting dwn-pulses: 1) =>-129 = +127 2) 126 3) 125 … fDEV = Baudrate + fOFFSET The calculated fDEV should be used to calculate the needed receiver bandwidth, see chapter Switched capacitor filter. Using the XCO-tune Bits The RF chip has a built-in mechanism for tuning the frequency of the crystal oscillator and is often used in combination with the Frequency Error Estimator (FEE). The XCO tuning is designed to eliminate or reduce initial frequency tolerance of the crystal and/or the frequency stability over temperature. If the value in XCO_tune is increased (adding capacitance), the frequency will decrease. The XCO uses two external capacitors (see figure 5). The value of these will strongly affect the tuning range. With a 16.0 MHz crystal (TN4-26011 from Toyocom), and external capacitor values of 1.5 pF, the tuning range will be approximately symmetrical around the center frequency. A XCO_tune >16 will decrease the frequency and vice versa (see figure 6). A procedure for using the XCO_tune feature in combination with the FEE is given below. The MICRF506 measures the frequency offset between the demodulated signal and the LO and tune the XCO so the LO frequency is equal to received carrier frequency. A procedure like this can be called during production (storing the calibrated XCO_tune value), at regular intervals or implemented in the communication protocol when the frequency has changed. The FEE can count “UP”-pulses and/or “DOWN”pulses (pulses out of the demodulator when a logic “1” or logic “0”, resp.., is received). The FEE can count pulses for n bits, where n = 8, 16, 32 or 64. Example: In FEE, count up+down pulses, counting 8 bits: A perfect case ==> FEE = 0 July 2006 28 M9999-092904 +1 408-944-0800 Micrel MICRF506BML/YML To avoid this situation, always make sure max count is between limits. Suggestion: Count for 8 (or 16) bits only. Procedure description: In the procedure below, UP+DWN pulses are counted, and only the sign of the FEE is used. The value of n is 8 or 16. Assumption: A transmitter is sending a 1010… pattern at the correct frequency and bitrate. The wanted receiver frequency is the mid-point between the “0” and “1” frequencies. Read FEE FEE > 0? Yes --> XCO_Sign = POS No --> XCO_Sing = NEG // negative or == 0 XCO_Step > 1? Yes --> Branch to LOOP No --> XCO_Sing ==POS? Yes --> XCO_Present- = 1 Branch to FIN FIN: RETURN, return-value = XCO_Present Input: Nothing Output The best XCO_tune value (giving the lowest IFEEI) Local variables: XCO_Present: (5-bit) holds present value in XCO_tune bits XCO_Step: (4-bit) holds increment/decrement of XCO_tune bits SCO_Sign: (1 bit) holds POS or NEG (increment/cerement) increasing LO is done by reducing the XCO_tune value XCO TUNE PROCEDURE INT: XCO_Present = 0 XCO_Step = 32 XCO_Sign = NEG Control_Word = Default RX, clocks match transmitter LOOP: XCO_Step = XCO_Step/2 XCO_Sign == POS? Yes --> XCO_Present- = XCO_Step // increase LO No --> XCO_Present+ = XCO_Step // decrease LO XCO_tune bits = CXO_Present Program RFChip Delay > n bits July 2006 29 M9999-092904 +1 408-944-0800 Micrel MICRF506BML/YML V2P5_2 V2P5_2 V2P5_2 Typical Application R1 6k2 C3 nc C2 C1 100nF 10nF 9 V2P5_2 V2P5_3 C10 C11 C12 C13 1nF 10nF 1nF 1nF 25 NC TP1 TP2 3 Y1 2 TSX 10A, 16MHz 22 21 20 19 18 C8 1 DIGGND DIGVDD 26 27 GND CP_OUT 29 28 VARIN VCOGND NC R5 82k V2P5_1 V2P5_0 R7 10R 8 LD nc DATAlXO DATACLK CIBIAS R4 RFVDD RFGND GND 4 1.5pF CS SCLK IO DATAIXO DATACLK 17 NC 7 IO MLF32 24 23 16 18pF 15pF MICRF506 ANT 15 6 QCHOUT 5 C4 RSSI 50ohm line SCLK 14 47pF RFGND 13 12nH C6 CS IFGND C5 RFVDD IFVDD L1 50ohm line ANT XTALIN ICHOUT 4 C9 1.5pF XTALOUT PTATBIAS 12 3 RFGND V2P5_0 10 V2P5_3 2 11 1 R3 27k 30 31 VCOVDD NC 32 V2P5_2 V2P5_1 R2 0R LD RSSI C7 R6 33k 1nF MICRF506 – MLF32 Item Part Value Description Manufacturer Part Numner 1 C1 10nF 10nF X7R ±10% 0603 50V Kyocera CM105X7R103K50A 100nF X7R ±10% 0603 16V Kyocera CM105X7R104K16A 2 C2 100nF 3 C3 NC 4 C4 18pF 18pF COG ±5% 0603 50V Kyocera CM105CG180J50A 5 C5 47pF 47pF COG ±5% 0603 50V Kyocera CM105CG470J50A 6 C6 15pF 15pF COG ±5% 0603 50V Kyocera CM105CG150J50A 7 C7 1nF Optional Kyocera CM105X7R102K50A 8 C8 1.5pF 1.5pF COG ±0.25pF 0603 50V Kyocera CM105CG1R5C50A 9 C9 1.5pF 1.5pF COG ±0.25pF 0603 50V Kyocera CM105CG1R5C50A 10 C10 1nF 1nF X7R ±10% 0603 50V Kyocera CM105X7R102K50A 11 C11 10nF 10nF X7R ±10% 0603 50V Kyocera CM105X7R103K50A 12 C12 1nF 1nF X7R ±10% 0603 50V Kyocera CM105X7R102K50A 13 C13 1nF 1nF X7R ±10% 0603 50V Kyocera CM105X7R102K50A 14 R1 6.2k 6.2k ±1% 0603 50V Kyocera CR10-6201F 15 R2 0Ω 0Ω ±1% 0603 50V Kyocera CJ10-000 16 R3 27k 27k ±1% 0603 50V Kyocera CR10-2702F 17 R5 82k 82k ±1% 0603 50V Kyocera CR10-8202F 18 R6 33k Optional Kyocera CR10-3302F 19 R7 10Ω 10R ±1% 0603 50V Kyocera CR10-10R0F 20 L1 12nH 12nH ±5% 0603 Coilcraft 0603CS-12NXJB 21 Y1 16MHz 16MHz, 9pF, 10/10ppm Toyocom TN4-26011 July 2006 30 M9999-092904 +1 408-944-0800 Micrel MICRF506BML/YML MICRF506BML/YML Land pattern Figure below shows recommended land pattern. Red circles indicate Thermal/RFGND via’s. Recommended size is 0.300-0.350mm with a pitch of 1mm. The recommended minimum number of via’s are 9 and they should be directly connected to ground plane providing the best RF ground and thermal performance. For best yield plugged or open via’s should be used. d D2' X SE E2' e Y SD D2’ E2’ SD SE d 3.4 ±0.02 3.4 ±0.02 4.2 ±0.05 4.2 ±0.05 0.325 ±0.25 Red circle indicates Thermal Via. Size 0.300-0.350mm July 2006 31 e 0.5 X 0.23 ±0.02 Y 0.5 ±0.02 Units mm M9999-092904 +1 408-944-0800 Micrel MICRF506BML/YML Layout Considerations The MICRF506 is a highly integrated RF IC with only a few “hot” pins, however it is suggested to study available reference design on www.micrel.com before starting with schematics and layout. • To ensure the best RF design it is important to plan the layout and dedicate area for the different circuitry. Good RF engineering is to start with the RF circuitry making sure that general RF guidelines are met (following points). Separate noisy circuitry and RF by placing it on the opposite side maximizing the distance between the circuitry. The RF circuitry should be placed as close to what is considered the ground spot (EG battery) to avoid ground currents. Place the RF circuitry in a position that ensure as short and straight trace to the antenna connection to avoid reflections. • Proper ground is needed. If the PCB is 2-layer, the bottom layer should be kept only for ground. Avoid signal traces that split the ground plane. For a 4-layer PCB, it is recommended to keep the second layer only for ground. • A ground via should be placed close to all the ground pins. The bottom ground (heat sink) pad should be penetrated with >9 ground via’s. These via’s should be “open” or “plugged” to avoid air pockets caused by the solder past. If such air pockets appear, the air will expand during the reflow process and may/will cause the device to twist/move. • The antenna pin (pin 5) has an impedance of ~50 ohm. The antenna trace should be kept to 50 ohm to avoid signal reflection and loss of performance. Minor deviations can be compensated by matching the LC filter. Any transmission line calculator can be used to find the needed trace width given a board build up. Ex: A trace width of 75 mil (1.9 mm) gives 50 impedance on a FR4 board (dielectric cons=4.4) with copper thickness of 35µm and height (layer 1-layer 2 spacing) of 1.00 mm. • RF circuitry is sensitive to voltage supply and therefore caution should be taken when choosing power circuitry. To achieve the best performance, low noise LDO’s with high PSSR should be chosen. What is present on the voltage supply will be directly modulated to the RF spectrum causing degradation and regulatory issues. To make sure you have the right selection, please contact local sales for the latest Micrel offerings in power management and guidance. To avoid “pickup” from other circuitry on the VDD lines, it is recommended to route the VDD in a star configuration with decoupling at each circuitry and at the common connection point (see above layout). If there are noisy circuitry in the design, it is strongly recommended to use a separate power supply and/or place low value resistors (10ohms), inductors in series with the power supply line into these circuitry. • It is recommended to connect the PLL loop filter to VDD (C1, C3 and R1). The VDD connection should be placed as close to pin 31 (VCOVDD) as possible. The MICRF506 has a integrated VCO where the resonator circuit (varactor ) has a reference to VDD. With a common reference point, the MICRF506 (PLL) will somewhat compensate for noise present on the VDD. • PLL loop filter components C1, C2, C3, R1 and R2 should have a compact layout and should be placed as close to pin 27 and 29. Avoid signal traces/bus and noisy circuitry around/close/under this area. • Digital high speed logic or noisy circuitry should/must be at a safe distance from RF circuitry or RF VDD as this might/will cause degradation of sensitivity and create spurious emissions. Example of such circuitry is LCD display, charge pumps, RS232, clock / data bus etc. July 2006 32 M9999-092904 +1 408-944-0800 Micrel MICRF506BML/YML Package Information MICRF506BML MICRF505BML 32-Pin MLF (B) July 2006 33 M9999-092904 +1 408-944-0800 Micrel MICRF506BML/YML Package Information MICRF506YML Side view H H2 h L e CPL E2 E b D2 D Top view Bottom view D D2 E E2 e b L CPL H h H2 Units 5.0 3.10±0.10 5.0 3.10±0.10 0.5 0.25 0.4±0.05 0.20 0.00~0.05 0.2 mm July 2006 34 0.85±0.05 M9999-092904 +1 408-944-0800 Micrel MICRF506BML/YML Overview of programming bit Address Data A6..A0 D7 D6 D5 D4 D3 D2 D1 D0 0000000 LNA_by PA2 PA1 PA0 Sync_en Mode1 Mode0 Load_en 0000001 Modulation1 Modulation0 OL_opamp_en (“0”) VCO_by (“0”) VCO_BIAS_s (“0”) PA_LDc_en (”0”) RSSI_en LD_en PF_FC1 PF_FC0 PA_by OUTS3 OUTS2 OUTS1 OUTS0 VCO_IB2 VCO_IB1 VCO_IB0 VCO_freq1 VCO_freq0 0000010 CP_HI SC_by 0000011 IFBias_s (“1”) IFA_HG (“1”) 0000100 Mod_F2 Mod_F1 Mod_F0 Mod_I4 Mod_I3 Mod_I2 Mod_I1 Mod_I0 Mod_shape (“1”) Mod_A3 Mod_A2 Mod_A1 Mod_A0 0000101 - - Mod_FHG (“0”) 0000110 - Mod_clkS2 Mod_clkS1 Mod_clkS0 BitSync_clkS2 BitSync_clkS1 BitSync_clkS0 BitRate_clkS2 0000111 BitRate_clkS1 BitRate_clkS0 RefClk_K5 RefClk_K4 RefClk_K3 RefClk_K2 RefClk_K1 RefClk_K0 0001000 ScClk_X2 (“1”) Prescal_s (“0”) ScSW_en (“0”) XCOAR_en (”1”) ScClk4 ScClk3 ScClk2 ScClk1 ScClk0 0001001 SC_HI (“1”) PrescalMode_s (“0”) XCOtune4 XCOtune3 XCOtune2 XCOtune1 XCOtune0 0001010 - - A0_5 A0_4 A0_3 A0_2 A0_1 A0_0 0001011 - - - - N0_11 N0_10 N0_9 N0_8 0001100 N0_7 N0_6 N0_5 N0_4 N0_3 N0_2 N0_1 N0_0 0001101 - - - - M0_11 M0_10 M0_9 M0_8 0001110 M0_7 M0_6 M0_5 M0_4 M0_3 M0_2 M0_1 M0_0 0001111 - - A1_5 A1_4 A1_3 A1_2 A1_1 A1_0 0010000 - - - - N1_11 N1_10 N1_9 N1_8 0010001 N1_7 N1_6 N1_5 N1_4 N1_3 N1_2 N1_1 N1_0 0010010 - - - - M1_11 M1_10 M1_9 M1_8 0010011 M1_7 M1_6 M1_5 M1_4 M1_3 M1_2 M1_1 M1_0 0010100 Div2_HI (“1”) LO_IB1 (“0”) LO_IB0 (“1”) PA_IB4 (”0”) PA_IB3 (”0”) PA_IB2 (”0”) PA_IB1 (”1”) PA_IB0 (“1”) 0010101 - - - - FEEC_3 FEEC_2 FEEC_1 FEEC_0 0010110 FEE_7 FEE_6 FEE_5 FEE_4 FEE_3 FEE_2 FEE_1 FEE_0 Table 1: Detailed description of programming bit ADR # 0000000 0000001 BIT # 7 6 5 4 3 2 1 0 7 6 5 4 3 July 2006 NAME By_LNA PA2 PA1 PA0 Sync_en Mode1 Mode0 Load_en Modulation1 Modulation0 OL_opamp_en PA_LDc_en RSSI_en DESCRIPTION LNA bypass on/off Power amplifier level, 3.bit Power amplifier level, 2.bit Power amplifier level, 1.bit Synchronizer Mode bit Main Mode selection 2. Bit Main Mode selection 1. Bit Load generation (1=enable) Modulation selection 2.bit Modulation selection 1.bit “0” mandatory. Opamp in OpenLoop circuit (0=disable) “0” mandatory. PA controlled by Lock Detect (0=disable) RSSI function (1=enable) 35 COMMENTS Ref. Table 6 Ref. Table 6 Ref. Table 6 Ref. Table 3 Ref. Table 2 Ref. Table 2 Ref. Table 4 Ref. Table 4 Ref. Table 6 M9999-092904 +1 408-944-0800 Micrel 0000010 0000011 0000100 0000101 0000110 0000111 0001000 July 2006 MICRF506BML/YML 2 1 0 7 6 5 4 3 2 1 0 7 6 LD_en PF_FC1 PF_FC0 CP_HI SC_by VCO_by PA_by OUTS3 OUTS2 OUTS1 OUTS0 IFBias_s IFA_HG 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 VCO_Bias_s VCO_IB2 VCO_IB1 VCO_IB0 VCO_freq1 VCO_freq0 Mod_F2 Mod_F1 Mod_F0 Mod_I4 Mod_I3 Mod_I2 Mod_I1 Mod_I0 ----------------Mod_FHG Mod_shape Mod_A3 Mod_A2 Mod_A1 Mod_A0 --------Mod_clkS2 Mod_clkS1 Mod_clkS0 BitSync_clkS2 BitSync_clkS1 BitSync_clkS0 BitRate_clkS2 BitRate_clkS1 BitRate_clkS0 RefClk_K5 RefClk_K4 RefClk_K3 RefClk_K2 RefClk_K1 RefClk_K0 SC_HI ScClk_X2 ScSw_EN Lock detect function (1=enable) Prefilter corner frequency 2.bit Prefilter corner frequency 1.bit High charge-pump current (0=125uA, 1=500uA) Bypass of Switched Capacitor filter (1=enable) “0” mandatory. Bypass of VCO (1=enable) Bypass of PA (1=enable) Test pins output 4.bit Test pins output 3.bit Test pins output 2.bit Test pins output 1.bit “1” mandatory. “1” mandatory. High gain setting in preamplifier “0” mandatory. Select separate bias for VCO on VCOBias pin (1=enable) VCO bias current setting, 3. bit (111 = highest current) VCO bias current setting, 2. bit VCO bias current setting, 1. bit Frequency setting of VCO, 2. bit (11=highest frequency) Frequency setting of VCO, 1.bit Modulator filter setting, MSB (0=filter active) Modulator filter setting Modulator filter setting, LSB Modulator current setting, MSB Modulator current setting Modulator current setting Modulator current setting Modulator current setting, LSB Reserved/not in use Reserved/not in use “0” mandatory. Modulator Test bit. “1” mandatory. Modulator shape enable Modulator attenuator setting, MSB (1=attenuator active) Modulator attenuator setting Modulator attenuator setting Modulator attenuator setting, LSB Reserved/not in use Modulator clock setting 3.bit, MSB Modulator clock setting 2.bit Modulator clock setting 1.bit, LSB BitSync clock setting 3.bit, MSB BitSync clock setting 2.bit BitSync clock setting 1.bit, LSB Bitrate clock setting 3.bit, MSB Bitrate clock setting 2.bit Bitrate clock setting 1.bit. LSB: Reference clock divider 6.bit, MSB Reference clock divider 5.bit Reference clock divider 4.bit Reference clock divider 3.bit Reference clock divider 2.bit Reference clock divider 1.bit, LSB “1” mandatory. High current in Switched Cap filter “1” mandatory. Switched Cap clock multiplied by two “0” mandatory. Switch cap switch enable 36 Ref. Table 5 Ref. Table 5 Ref. Table 8 Ref. Table 8 Ref. Table 8 Ref. Table 8 M9999-092904 +1 408-944-0800 Micrel 0001001 0001010 0001011 0001100 0001101 0001110 0001111 July 2006 MICRF506BML/YML 4 3 2 1 0 ScClk4 ScClk3 ScClk2 ScClk1 ScClk0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 PrescalMode_s Prescal_s XCOAR_en XCOtune4 XCOtune3 XCOtune2 XCOtune1 XCOtune0 ----------------A0_5 A0_4 A0_3 A0_2 A0_1 A0_0 --------------------------------N0_11 N0_10 N0_9 N0_8 N0_7 N0_6 N0_5 N0_4 N0_3 N0_2 N0_1 N0_0 --------------------------------M0_11 M0_10 M0_9 M0_8 M0_7 M0_6 M0_5 M0_4 M0_3 M0_2 M0_1 M0_0 --------- SwitchCap clock divider 5.bit, MSB SwitchCap clock divider 4.bit SwitchCap clock divider 3.bit SwitchCap clock divider 2.bit SwitchCap clock divider 1.bit, LSB “0” mandatory. Selects A, N and M divider output control of prescaler mode “0” mandatory. Selects pulse swallow prescaler. “1” mandatory. Set XCO amplitude regulation on. Crystal oscillator trimming, LSB Crystal oscillator trimming Crystal oscillator trimming Crystal oscillator trimming Crystal oscillator trimming, MSB Reserved/not in use Reserved/not in use A0-counter 6.bit A0-counter 5.bit A0-counter 4.bit A0-counter 3.bit A0-counter 2.bit A0-counter 1.bit Reserved/not in use Reserved/not in use Reserved/not in use Reserved/not in use N0-counter 12.bit N0-counter 11.bit N0-counter 10.bit N0-counter 9.bit N0-counter 8.bit N0-counter 7.bit N0-counter 6.bit N0-counter 5.bit N0-counter 4.bit N0-counter 3.bit N0-counter 2.bit N0-counter 1.bit Reserved/not in use Reserved/not in use Reserved/not in use Reserved/not in use M0-counter 12.bit M0-counter 11.bit M0-counter 10.bit M0-counter 9.bit M0-counter 8.bit M0-counter 7.bit M0-counter 6.bit M0-counter 5.bit M0-counter 4.bit M0-counter 3.bit M0-counter 2.bit M0-counter 1.bit Reserved/not in use 37 M9999-092904 +1 408-944-0800 Micrel 0010000 0010001 0010010 0010011 0010100 0010101 July 2006 MICRF506BML/YML 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 --------A1_5 A1_4 A1_3 A1_2 A1_1 A1_0 --------------------------------N1_11 N1_10 N1_9 N1_8 N1_7 N1_6 N1_5 N1_4 N1_3 N1_2 N1_1 N1_0 --------------------------------M1_11 M1_10 M1_9 M1_8 M1_7 M1_6 M1_5 M1_4 M1_3 M1_2 M1_1 M1_0 Div2_HI LO_IB1 LO_IB0 PA_IB4 PA_IB3 PA_IB2 PA_IB1 PA_IB0 --------------------------------FEEC_3 FEEC_2 FEEC_1 FEEC_0 Reserved/not in use A1-counter 6.bit A1-counter 5.bit A1-counter 4.bit A1-counter 3.bit A1-counter 2.bit A1-counter 1.bit Reserved/not in use Reserved/not in use Reserved/not in use Reserved/not in use N1-counter 12.bit N1-counter 11.bit N1-counter 10.bit N1-counter 9.bit N1-counter 8.bit N1-counter 7.bit N1-counter 6.bit N1-counter 5.bit N1-counter 4.bit N1-counter 3.bit N1-counter 2.bit N1-counter 1.bit Reserved/not in use Reserved/not in use Reserved/not in use Reserved/not in use M1-counter 12.bit M1-counter 11.bit M1-counter 10.bit M1-counter 9.bit M1-counter 8.bit M1-counter 7.bit M1-counter 6.bit M1-counter 5.bit M1-counter 4.bit M1-counter 3.bit M1-counter 2.bit M1-counter 1.bit “1” mandatory. Sets high bias current in Div2 circuit “0” mandatory. Bias current setting of LObuffer, MSB “1” mandatory. Bias current setting of LObuffer, LSB “0” mandatory. Bias current setting of PA,MSB “0” mandatory. Bias current setting of PA “0” mandatory. Bias current setting of PAbuffer, MSB “1” mandatory. Bias current setting of PAbuffer “1” mandatory. Bias current setting of PAbuffer, LSB Reserved/not in use Reserved/not in use Reserved/not in use Reserved/not in use FEE control bit FEE control bit FEE control bit FEE control bit 38 Ref. Table 9 Ref. Table 9 Ref. Table 9 Ref. Table 11 Ref. Table 11 Ref. Table 10 Ref. Table 10 M9999-092904 +1 408-944-0800 Micrel 0010110 July 2006 MICRF506BML/YML 7 6 5 4 3 2 1 0 FEE_7 FEE_6 FEE_5 FEE_4 FEE_3 FEE_2 FEE_1 FEE_0 FEE value, bit 7, MSB FEE value, bit 6 FEE value, bit 5 FEE value, bit 4 FEE value, bit 3 FEE value, bit 2 FEE value, bit 1 FEE value, bit 0, LSB 39 M9999-092904 +1 408-944-0800 Micrel MICRF506BML/YML Table 2: Main Mode bit Mode1 Mode0 State Comments 0 0 0 Power down Keeps Register configuration 1 Standby Crystal Oscillator running 1 0 Receive Full Receive 1 1 Transmit Full Transmit ex. PA stage Table 3: Synchronizer mode bit Sync_en State Comments 0 Rx: Bit synchronization off Transparent reception of data 0 Tx: DataClk pin off Transparent transmission of data 1 Rx: Bit synchronization on Bit-clock is generated by transceiver 1 Tx: DataClk pin on. Bit-clock is generated by transceiver Table 4: Modulation bit State Comments 0 Closed loop VCO-modulation VCO is phase-locked 1 Open loop VCO-modulation Not recommend 1 0 Modulation by A,M and N Modulation inside PLL 1 1 Not defined Reserved for future use Modulation1 Modulation0 0 0 Table 5: Prefilter bit PF_FC1 PF_FC0 0 0 3 dB filter corner at 100 KHz 0 1 3 dB filter corner at 150 KHz 1 0 3 dB filter corner at 230 KHz 1 1 3 dB filter corner at 340 KHz July 2006 State 40 M9999-092904 +1 408-944-0800 Micrel MICRF506BML/YML Table 6: Power amplifier bit State PA2 PA1 PA0 0 0 0 21dB attenuation/PA off 0 0 1 18dB attenuation 0 1 0 15dB attenuation 0 1 1 12dB attenuation 1 0 0 9dB attenuation 1 0 1 6dB attenuation 1 1 0 3dB attenuation 1 1 1 Max output PALDc_en 0 PA is turned off by PA2=PA1=PA0=0 1 PA is turned on/off by Lock Detect, LD=1 -> PA on PA2=PA1=PA0=0 now gives 21dB attenuation PA_By 0 Power Amplifier enabled 1 Power Amplifier bypassed, approx 20dB reduced output power. Table 7:Generation of Bitrate_clk, BitSync_clk and Mod_clk. S2 0 0 0 0 1 1 1 1 (*) Can not be used as BitRate_clk. Clock frequency (F is crystal frequency, K is RefClk integer) BitRate_clk BitSync_clk Mod_clk S1 0 0 1 1 0 0 1 1 S0 0 1 0 1 0 1 0 1 F/(64K) F/(32K) F/(16K) F/(8K) F/(4K) F/(2K) F/K (*) F (*) Table 8: Test signals OutS3 0 0 0 0 0 0 0 0 1 1 1 1 1 1 1 1 OutS2 0 0 0 0 1 1 1 1 0 0 0 0 1 1 1 1 July 2006 OutS1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 OutS0 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 IchOut Gnd Ip mixer Qp mixer Ip IFamp Qp IFamp Ip SC-filter Qp SC-filter Ip mixer Qp mixer Ip mixer Qp mixer Ip mixer Ip IFamp Ip SC-filter I limiter N-div QchOut Gnd In mixer Qn mixer In IFamp Qn IFamp In SC-filter Qn SC-filter In mixer Qn mixer In mixer Qn mixer Qp mixer Qp IFamp Qp SC-filter Q limiter M-div 41 Ichout2 / RSSI Gnd Ip IFamp Qp IFamp Ip SC-filter Qp SC-filter Gnd Gnd Ip SC-filter Qp SC-filter Gnd Gnd ModIn TI1 DemodUp Demod Phi1n QchOut2 / NC Gnd In IFamp Qn IFamp In SC-filter Qn SC-filter I limiter Q limiter In SC-filter Qn SC-filter I limiter Q limiter PrescalMode TQ1 DemodDn MAout Phi2n M9999-092904 +1 408-944-0800 Micrel MICRF506BML/YML Table 9: PAbuffer bias current setting State PA_IB2 PA_IB1 PA_IB0 0 0 0 PAbuffer uses bias current from PTATBias source, external resistor (Pin 2) 0 0 1 PAbuffer uses bias current from separate bias source, external resistor (Pin 8) 0 1 0 PAbuffer uses bias current from internal bias source, lowest current 0 1 1 PAbuffer uses bias current from internal bias source 1 0 0 PAbuffer uses bias current from internal bias source, typical current 1 0 1 PAbuffer uses bias current from internal bias source 1 1 0 PAbuffer uses bias current from internal bias source 1 1 1 PAbuffer uses bias current from internal bias source, highest current Table 10: Frequency Error Estimation control bit FEEC_1 0 0 1 FEEC_0 0 1 0 1 1 FEE Mode Off Counting UP pulses Counting DN pulses Counting UP and DN pulses. UP increments the counter, DN decrements it. Table 11: Frequency Error Estimation control bit, cont. FEEC_3 FEEC_2 0 0 1 1 0 1 0 1 No. of DEMOD_DT bit used during the measurement. 8 16 32 64 MICREL, INC. 2180 FORTUNE DRIVE, SAN JOSE, CA 95131 USA TEL +1 (408) 944-0800 FAX +1 (408) 474-1000 WEB http:/www.micrel.com The information furnished by Micrel in this data sheet is believed to be accurate and reliable. However, no responsibility is assumed by Micrel for its use. Micrel reserves the right to change circuitry and specifications at any time without notification to the customer. Micrel Products are not designed or authorized for use as components in life support appliances, devices or systems where malfunction of a product can reasonably be expected to result in personal injury. Life support devices or systems are devices or systems that (a) are intended for surgical implant into the body or (b) support or sustain life, and whose failure to perform can be reasonably expected to result in a significant injury to the user. A Purchaser’s use or sale of Micrel Products for use in life support appliances, devices or systems is a Purchaser’s own risk and Purchaser agrees to fully indemnify Micrel for any damages resulting from such use or sale. © 2004 Micrel, Incorporated. July 2006 42 M9999-092904 +1 408-944-0800