SI1011-A-GM Silicon Laboratories Inc, SI1011-A-GM Datasheet - Page 176

SI1011-A-GM

Manufacturer Part Number

SI1011-A-GM

Description

IC TXRX MCU + EZRADIOPRO

Manufacturer

Silicon Laboratories Inc

Datasheets

1.SI1011-A-GM.pdf (1 pages)

2.SI1014-A-GM.pdf (384 pages)

Specifications of SI1011-A-GM

Package / Case

42-QFN

Frequency

240MHz ~ 960MHz

Data Rate - Maximum

256kbps

Modulation Or Protocol

FSK, GFSK, OOK

Applications

General Purpose

Power - Output

20dBm

Sensitivity

-121dBm

Voltage - Supply

1.8 V ~ 3.6 V

Current - Receiving

18.5mA

Current - Transmitting

85mA

Data Interface

PCB, Surface Mount

Memory Size

8kB Flash, 768B RAM

Antenna Connector

PCB, Surface Mount

Number Of Receivers

Number Of Transmitters

Wireless Frequency

240 MHz to 960 MHz

Interface Type

UART, SMBus, SPI, PCA

Output Power

20 dBm

Operating Supply Voltage

0.9 V to 3.6 V

Maximum Operating Temperature

+ 85 C

Mounting Style

SMD/SMT

Maximum Supply Current

4 mA

Minimum Operating Temperature

- 40 C

Modulation

FSK, GFSK, OOK

Protocol Supported

C2, SMBus

Core

8051

Program Memory Type

Flash

Program Memory Size

8 KB

Data Ram Size

768 B

Supply Current (max)

4 mA

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Operating Temperature

Lead Free Status / Rohs Status

Lead free / RoHS Compliant

Other names

336-1872-5

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

Bonase Electronics (HK) Co., Limited

Part Number:

SI1011-A-GM

Manufacturer:

Silicon Laboratories Inc

Quantity:

135

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Si1010/1/2/3/4/5

16.2. High Power Applications

The dc-dc converter is designed to provide the system with 65 mW of output power, however, it can safely

provide up to 100 mW of output power without any risk of damage to the device. For high power applica-

tions, the system should be carefully designed to prevent unwanted VBAT and VDD_MCU/DC+ Supply

Monitor resets, which are more likely to occur when the dc-dc converter output power exceeds 65mW. In

addition, output power above 65 mW causes the dc-dc converter to have relaxed output regulation, high

output ripple and more analog noise. At high output power, an inductor with low DC resistance should be

chosen in order to minimize power loss and maximize efficiency.

The combination of high output power and low input voltage will result in very high peak and average

inductor currents. If the power supply has a high internal resistance, the transient voltage on the VBAT ter-

minal could drop below 0.9 V and trigger a VBAT Supply Monitor Reset, even if the open-circuit voltage is

well above the 0.9 V threshold. While this problem is most often associated with operation from very small

batteries or batteries that are near the end of their useful life, it can also occur when using bench power

supplies that have a slow transient response; the supply’s display may indicate a voltage above 0.9 V, but

the minimum voltage on the VBAT pin may be lower. A similar problem can occur at the output of the dc-dc

converter: using the default low current limit setting (125 mA) can trigger V

Supply Monitor resets if there

is a high transient load current, particularly if the programmed output voltage is at or near 1.8 V.

16.3. Pulse Skipping Mode

The dc-dc converter allows the user to set the minimum pulse width such that if the duty cycle needs to

decrease below a certain width in order to maintain regulation, an entire "clock pulse" will be skipped.

Pulse skipping can provide substantial power savings, particularly at low values of load current. The con-

verter will continue to maintain a minimum output voltage at its programmed value when pulse skipping is

employed, though the output voltage ripple can be higher. Another consideration is that the dc-dc will oper-

ate with pulse-frequency modulation rather than pulse-width modulation, which makes the switching fre-

quency spectrum less predictable; this could be an issue if the dc-dc converter is used to power a radio.

Figure 4.5 and Figure 4.6 on page 53 and 54 show the effect of pulse skipping on power consumption.

16.4. Enabling the DC-DC Converter

On power-on reset, the state of the DCEN pin is sampled to determine if the device will power up in one-

cell or two-cell mode. In two-cell mode, the dc-dc converter always remains disabled. In one-cell mode, the

dc-dc converter remains disabled in Sleep Mode, and enabled in all other power modes. See Section

“14. Power Management” on page 157 for complete details on available power modes.

The dc-dc converter is enabled (one-cell mode) in hardware by placing a 0.68 µH inductor between DCEN

and VBAT. The dc-dc converter is disabled (two-cell mode) by shorting DCEN directly to GND. The DCEN

pin should never be left floating. The device can only switch between one-cell and two-cell mode during a

power-on reset. See Section “18. Reset Sources” on page 185 for more information regarding reset behav-

ior.

Figure 16.2 shows the two dc-dc converter configuration options.

176

Rev. 1.0

SI1011-A-GM Silicon Laboratories Inc, SI1011-A-GM Datasheet - Page 176

SI1011-A-GM

Specifications of SI1011-A-GM

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