SI4460-C2A-GM Datasheet, PDF(42/53 Page) Silicon Laboratories – HIGH-PERFORMANCE, LOW-CURRENT TRANSCEIVER

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SI4460-C2A-GM Datasheet, PDF (42/53 Pages) Silicon Laboratories – HIGH-PERFORMANCE, LOW-CURRENT TRANSCEIVER

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Si4463/61/60-C

8.5. Antenna Diversity

To mitigate the problem of frequency-selective fading due to multipath propagation, some transceiver systems use

a scheme known as antenna diversity. In this scheme, two antennas are used. Each time the transceiver enters RX

mode the receive signal strength from each antenna is evaluated. This evaluation process takes place during the

preamble portion of the packet. The antenna with the strongest received signal is then used for the remainder of

that RX packet. The same antenna will also be used for the next corresponding TX packet. This chip fully supports

antenna diversity with an integrated antenna diversity control algorithm. The required signals needed to control an

external SPDT RF switch (such as a PIN diode or GaAs switch) are available on the GPIOx pins. The operation of

these GPIO signals is programmable to allow for different antenna diversity architectures and configurations. The

antdiv[2:0] bits are found in the MODEM_ANT_DIV_CONTROL API property descriptions and enable the antenna

diversity mode. The GPIO pins are capable of sourcing up to 5 mA of current; so, it may be used directly to

forward-bias a PIN diode if desired. The antenna diversity algorithm will automatically toggle back and forth

between the antennas until the packet starts to arrive. The recommended preamble length for optimal antenna

selection is 8 bytes.

8.6. Preamble Sense Mode

This mode of operation is suitable for extremely low power applications where power consumption is important.

The preamble sense mode (PSM) takes advantage of the Digital Signal Arrival detector (DSA), which can detect a

preamble within eight bit times with no sensitivity degradation. This fast detection of an incoming signal can be

combined with duty cycling of the receiver during the time the device is searching or sniffing for packets over the

air. The average receive current is lowered significantly when using this mode. In applications where the timing of

the incoming signal is unknown, the amount of power savings is primarily dependent on the data rate and preamble

length as the Rx inactive time is determined by these factors. In applications where the sleep time is fixed and the

timing of the incoming signal is known, the average current also depends on the sleep time. The PSM mode is

similar to the low duty cycle mode but has the benefit of faster signal detection and autonomous duty cycling of the

receiver to achieve even lower average receive currents. This mode can be used with the low power mode (LP)

which has an active RX current of 10 mA or with the high-performance (HP) mode which has an active RX current

of 13 mA.

Figure 18. Preamble Sense Mode

Table 16. Data Rates

PM length = 4 bytes

PM length = 8 bytes

1.2 kbps

6.48

3.83

Note: Typical values. Active RX current is 13 mA.

Data Rate

9.6 kbps 50 kbps 100 kbps

6.84

8.44

10.43

3.96

4.57

5.33

Rev 1.0

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