DEVELOPMENT KIT (Info Click here) DNT90 * 900 MHz Frequency Hopping Spread Spectrum Transceiver * Point-to-point, Point-to-multipoint, Peer-to-peer and Store & Forward Capabilities * Transmitter Power Configurable to 40 or 158 mW * 100 kbps RF Data Rate * Serial Port Data Rate up to 230.4 kbps, SPI Port Data Rate up to 500 kbps * 128-Bit AES Encryption * Separate Serial Port for Diagnostics * Analog and Digital I/O for Sensor Applications The DNT90 FHSS transceiver module provides a low-cost, versatile solution for wireless data communications in the 900 MHz ISM band. The DNT90 RF output power can be set at 40 or 158 mW. The DNT90 receiver input is protected by low-loss SAW filter, providing an excellent combination of receiver sensitivity and out-of-band interference rejection. The DNT90 module includes analog, digital and serial I/O, providing the flexibility to serve applications ranging from cable replacements to sensor networks. The DNT90 transceiver module is easy to integrate and provides reliable wireless communications up to 5 miles in line-of-sight installations. Low Cost 900 MHz FHSS Transceiver Module with I/O DNT90 Absolute Maximum Ratings Rating Value Units Power Supply Input -0.5 to +6.5 V All Input/Output Pins -0.5 to +3.3 V 0 dBm Input Power to RFIO Port Non-Operating Ambient Temperature Range -40 to +85 o C DNT90 Electrical Characteristics Characteristic Sym Notes Operating Frequency Range Hop Duration 1 Number of RF Channels 1 Modulation Minimum Maximum Units 902.76 Typical 927.24 MHz 8 100 ms 25, 26 or 52 FSK RF Data Transmission Rate 100 kbps Receiver Sensitivity @ 10-5 BER -100 dBm 40 or 158 mW mW 50 W Transmitter RF Output Power Optimum Antenna Impedance RF Connection System Topologies Access Scheme www.RFM.com E-mail: info@rfm.com (c)2010 by RF Monolithics, Inc. 1 U.FL Coaxial Connector Point-to-Point, Point-to-Multipoint, Peer-to-Peer and Store & Forward Ad Hoc TDMA Page 1 of 7 DNT90 - 11/29/10 DNT90 Electrical Characteristics Characteristic Sym ADC Input Range Notes Minimum 2 0 Typical ADC Input Resolution ADC Sample Rate Maximum Units 2.5 V 12 bits 100 Signal Source Impedance for ADC Reading ADC External Reference Voltage Range DAC Output Range Hz 10 KW 1.0 2.7 V 0 3.3 V 12 bits DAC Output Resolution 1.2, 2.4, 4.8, 9.6, 14.4, 19.2, 28.8, 38.4, 57.6, 115.2, 230.4 Primary and Diagnostic Serial Port Baud Rates Serial Peripheral Interface Data Rate kbps 125 500 kbps Logic Low Input Level -0.5 0.8 V Logic High Input Level 2.45 3.3 V Digital I/O: Logic Input Internal Pull-up Resistor Power Supply Voltage Range 20 VCC +3.3 KW +5.5 Vdc Power Supply Voltage Ripple 10 mVP-P Peak Transmit Mode Current, 158 mW Output 170 mA Average Operating Receive Current: Base, Continuous Data Stream 110 mA Remote, Linked, No Data Transmission 15 mA Remote, Continuous Data Stream 25 mA Sleep Current 3 3 DNT90C Mounting 6 A Reflow Soldering DNT90P Mounting Socket Operating Temperature Range -40 85 o Operating Relative Humidity Range, Non-condensing 10 90 % C Notes: 1. The DNT90 achieves regulatory certification under FHSS rules. 2. ADC full-scale reading is 4095 minus the zero calibration offset. 3. Maximum sleep current occurs at +85 oC. CAUTION: Electrostatic Sensitive Device. Observe precautions when handling. www.RFM.com E-mail: info@rfm.com (c)2010 by RF Monolithics, Inc. Page 2 of 7 DNT90 - 11/29/10 D N T 9 0 B lo c k D ia g r a m 1 G N D 2 A C T (D IA G _ T X ) /D C D 3 (D IA G _ R X ) IR Q 0 4 G P IO 0 R A D IO _ T X D 5 R A D IO _ R X D 6 IR Q 1 /D C L K D A T A G P IO 4 (/H O S T _ C T S ) 7 G P IO 5 (/H O S T _ R T S ) 8 D A C 0 9 P L L _ L O C K G P IO 2 1 0 G P IO 1 1 1 G P IO 3 (D A V ) 1 2 D A C 1 1 3 V C C 1 4 G N D 1 5 + 3 .3 V S C K M ic r o c o n tr o lle r S D I T R C 1 0 3 S A W F ilte r a n d P o w e r A m p S D O n S S _ D A T A n S S _ C O N F IG R e g 2 8 2 9 3 0 G N D 2 7 G N D 2 6 R S V D 2 5 R S V D 2 4 A D C _ E X T _ R E M O S I 2 3 R S V D A D C 1 2 2 3 .3 V _ O U T 2 1 /S S 2 0 S C L K 1 9 M IS O 1 8 /R E S E T G N D 1 7 A D C 0 1 6 Figure 1 DNT90 Hardware The major components of the DNT90 include an RFM TRC103 900 MHz FHSS transceiver, and a low current 8-bit microcontroller. The DNT90 operates in the 902 to 928 MHz ISM band. There are three selectable hopping patterns providing compatibility with frequency allocations in the US, Canada, South America, Australia and New Zealand. The DNT90 also has two selectable RF output power levels: +16 dBm (40 mW) and +22 dBm (158 mW). The DNT90 receiver is protected by a low-loss SAW filter, providing an excellent blend of receiver sensitivity and out-of-band interference rejection that is especially important in outdoor applications. The DNT90 provides a variety of hardware interfaces. There are two serial ports plus one SPI port. Either the primary serial port or the SPI port can be selected for data communications. The second serial port is dedicated to diagnostics. The primary and diagnostic serial ports support most standard baud rates up to 230.4 kbps. The SPI port supports data rates up to 500 kbps. The DNT90 also includes three 12-bit ADC inputs, two 12-bit DAC outputs, and six general-purpose digital I/O ports. Two of the digital I/O ports support an optional interrupt-from-sleep mode www.RFM.com E-mail: info@rfm.com (c)2010 by RF Monolithics, Inc. when configured as inputs. The radio is available in two mounting configurations. The DNT90C is designed for solder reflow mounting. The DNT90P is designed for plug-in connector mounting. DNT90 Firmware DNT90 firmware operates using hybrid Ad Hoc TDMA channel access optimized for periodic burst transmissions. DNT90 firmware operates "out of the box" using point-topoint transparent serial mode, with point-to-multipoint, peer-to-peer and store & forward system topologies also supported. DNT90 firmware provides the user with a rich set of configuration options including a choice of hopping patterns, hopping dwell times, serial and/or SPI data port operation, serial and SPI data rate selection, RF output power selection, plus configurable analog and digital I/O lines. Data integrity is protected by 24-bit error detection, with optional ACK and automatic transmission retries or redundant transmissions. 128-bit AES encryption provides a high level of data security for sensitive applications. Sensor networks can take advantage of timer or event-based data reporting and remote node sleep cycling for extended battery life. Page 3 of 7 DNT90 - 11/29/10 DNT90 I/O Descriptions Pin Name I/O 1 GND - 2 ACT (DIAG_TX) O (O) This pin's default configuration is data activity output. On a base, this signal blinks when a valid packet is received. On a remote, this signal blinks when a packet is transmitted. On a router, this signal blinks when a valid upstream packet is received or a downstream packet is transmitted. Alternate pin function is the diagnostic serial port output. 3 /DCD (DIAG_RX) O (I) This pin's default configuration is data carrier detect output. On a base, this signal is asserted when any valid packet is received, and is cleared if no packets are heard for the configured router/remote registration time-out interval. On a router or remote, this signal is asserted when the radio obtains hopping pattern synchronization, and remains asserted until no beacons are heard for 50 hops. Alternate pin function is the diagnostic serial port input. I/O Configurable digital I/O port 0. When configured as an input, an internal pull-up resistor can be selected and direct interrupt from sleep can be invoked. When configured as an output, the power-on state is configurable. In sleep mode the pin direction, input pull-up selection or output state are also separately configurable. 4 GPIO0 Description Power supply and signal ground. Connect to the host circuit board ground. 5 RADIO_TXD O Serial data output from the radio. 6 RADIO_RXD I Serial data input to the radio. 7 GPOI4 (/HOST_CTS) I/O (O) Default pin function is GPIO4 with the same configuration options as GPIO2. Alternate pin function is UART/SPI flow control output. The module sets this line low when it is ready to accept data from the host on the RADIO_RXD or MOSI input. When the line goes high, the host must stop sending data. 8 GPOI5 (/HOST_RTS) I/O (I) Default pin function is GPIO5 with the same configuration options as GPIO2. Alternate pin function is UART/SPI flow control input. The host sets this line low to allow data to flow from the module on the RADIO_TXD pin. When the host sets this line high, the module will stop sending data to the host. 9 DAC0 O 12-bit DAC 0 output. Full scale output can be referenced to the voltage at pin 25, the internal 1 V band-gap reference, or the 3.3 V regulated module bus voltage. 10 GPIO2 I/O Configurable digital I/O port 2. Same configuration options as GPIO0 except interrupt from sleep is only tested at the sleep mode ADC sampling interval. 11 GPIO1 I/O Configurable digital I/O port 1. Same configuration options as GPIO0. 12 GPIO3 (DAV) I/O (O) Default pin function is GPIO3 with the same configuration options as GPIO2. When SPI slave mode operation is enabled, a logic high on this pin indicates when data is available to be clocked out by the SPI master. 13 DAC1 O 12-bit DAC 1 output. Same specifications and configuration options as DAC0. 14 VCC I Power supply input, +3.3 to +5.5 Vdc. 15 GND - Power supply and signal ground. Connect to the host circuit board ground. 16 GND - Power supply and signal ground. Connect to the host circuit board ground. 17 /RESET I Active low module hardware reset. 18 ADC0 I 12-bit ADC input 0. Full scale reading can be referenced to Pin 25 for ratiometric measurements. For absolute measurements, the ADC can use either an internal 1 V band-gap reference, the regulated buss voltage divided by 1.6 (about 2.06 V), or an external voltage applied to Pin 25. The ADC full-scale reading is equal to 4095 minus the zero calibration offset, or nominally 2.5 V. 19 ADC1 I 12-bit ADC input 1. Same configuration options as ADC0. 20 MISO I/O This pin is the SPI master mode input or slave mode output. 21 MOSI I/O This pin is the SPI master mode output or slave mode input. 22 /SS I/O SPI active low slave select. This pin is an output when the module is operating as a master, and an input when it is operating as a slave. 23 SCLK I/O SPI clock signal. This pin is an output when operating as a master, and an input when operating as a slave. www.RFM.com E-mail: info@rfm.com (c)2010 by RF Monolithics, Inc. Page 4 of 7 DNT90 - 11/29/10 Pin Name I/O Description 24 ADC2 I 25 ADC_EXT_ REF I/O 26 RSVD - Reserved pin. Leave unconnected. 27 RSVD - Reserved pin. Leave unconnected. 28 GND - Connect to the host circuit board ground plane. 29 RSVD - Reserved pin. Leave unconnected. 30 GND - Connect to the host circuit board ground plane. 12-bit ADC input 2. Same configuration options as ADC0. ADC external reference voltage pin. The voltage at this pin can be used by the ADCs as a reference for ratiometric measurements. With no external voltage or load applied, this pin presents a nominal 1.65 V output through a 5 K source resistance. A low impedance external reference voltage in the range of 1 to 2.7 V may be applied to this pin as an option. DNT90 Antenna Connector A U.FL miniature coaxial connector is provided on both DNT90 configurations for connection to the RFIO port. A short U.FL coaxial cable can be used to connect the RFIO port directly to an antenna. In this case the antenna should be mounted firmly to avoid stressing the U.FL coaxial cable due to antenna mounting flexure. Alternately, a U.FL coaxial jumper cable can be used to connect the DNT90 module to a U.FL connector on the host circuit board. The connection between the host circuit board U.FL connector and the antenna or antenna connector on the host circuit board should be implemented as a 50 ohm stripline. Referring to Figure 2, the width of this stripline depends on the thickness of the circuit board between the stripline and the groundplane. For FR-4 type circuit board materials (dielectric constant of 4.7), the width of the stripline is equal to 1.75 times the thickness of the circuit board. Note that other circuit board traces should be spaced away from the stripline to prevent signal coupling, as shown in Figure 3. The stripline trace should be kept short to minimize its insertion loss. C ir c u it B o a r d S tr ip lin e T r a c e D e ta il C o p p e r S tr ip lin e T ra c e C o p p e r G ro u n d P la n e F R -4 P C B M a te r ia l Trace Separation from 50 ohm Microstrip Length of Trace Run Parallel to Microstrip 100 mil 125 mil 150 mil 200 mil 200 mil 290 mil 250 mil 450 mil 300 mil 650 mil Figure 3 F o r 5 0 o h m im p e d a n c e W = 1 .7 5 * H Figure 2 www.RFM.com E-mail: info@rfm.com (c)2010 by RF Monolithics, Inc. Page 5 of 7 DNT90 - 11/29/10 D N T 9 0 C O u tlin e a n d M o u n tin g D im e n s io n s 1 .4 5 0 (3 6 .8 ) 0 .0 5 0 (1 .2 7 ) 1 1 5 0 .9 8 0 (2 7 .9 ) T o p V ie w 1 6 3 0 0 .4 5 0 (1 1 .4 ) 0 .3 0 0 (7 .6 2 ) 0 .1 2 5 (3 .1 8 ) 0 .0 9 0 D im e n s io n s in in c h e s (m m ) Figure 4 D N T 9 0 C S o ld e r P a d D im e n s io n s 1 .4 5 0 (3 6 .8 ) 0 .0 5 0 (1 .2 7 ) 0 .0 6 0 (1 .5 2 ) 1 5 1 0 .0 3 5 (0 .8 9 ) 0 .9 8 0 1 .0 4 0 (2 4 .9 ) (2 6 .4 ) T o p V ie w 1 6 3 0 D im e n s io n s in in c h e s (m m ) Figure 5 www.RFM.com E-mail: info@rfm.com (c)2010 by RF Monolithics, Inc. Page 6 of 7 DNT90 - 11/29/10 D N T 9 0 P O u tlin e a n d M o u n tin g D im e n s io n s 1 .4 5 0 (3 6 .8 ) 0 .0 5 0 (1 .2 7 ) 0 .0 6 0 (1 .5 2 ) 1 5 0 .9 8 0 (2 4 .9 ) 1 1 .1 0 0 (2 7 .9 ) T o p V ie w 1 6 3 0 0 .4 5 0 (1 1 .4 ) 0 .3 0 0 (7 .6 2 ) 0 .1 2 5 (3 .1 8 ) 0 .0 9 0 (2 .2 9 ) 0 .2 2 5 (5 .7 2 ) D im e n s io n s in in c h e s (m m ) Figure 6 0 .1 0 0 (2 .5 4 ) D N T 9 0 P In te r fa c e C o n n e c to r P C B L a y o u t D e ta il 0 .0 5 0 (1 .2 7 ) 0 .8 0 0 (2 0 .3 ) C o n n e c to rs a re S A M T E C S L M -1 1 5 -0 1 -G -S o r E q u iv a le n t 0 .7 0 0 (1 7 .8 ) 0 .9 8 0 (2 4 .9 ) D im e n s io n s a r e in in c h e s (m m ) Figure 7 Note: Specifications subject to change without notice. Part # M-0090-0000, Rev A www.RFM.com E-mail: info@rfm.com (c)2010 by RF Monolithics, Inc. Page 7 of 7 DNT90 - 11/29/10