C8051F040-GQ Silicon Laboratories Inc, C8051F040-GQ Datasheet - Page 52

C8051F040-GQ

Manufacturer Part Number

C8051F040-GQ

Description

IC 8051 MCU 64K FLASH 100TQFP

Manufacturer

Silicon Laboratories Inc

Series

C8051F04xr

Datasheets

1.C8051F040-TB.pdf (328 pages)

2.C8051F040-TB.pdf (2 pages)

3.C8051F043-GQ.pdf (328 pages)

Specifications of C8051F040-GQ

Program Memory Type

FLASH

Program Memory Size

64KB (64K x 8)

Package / Case

100-TQFP, 100-VQFP

Core Processor

8051

Core Size

8-Bit

Speed

25MHz

Connectivity

CAN, EBI/EMI, SMBus (2-Wire/I²C), SPI, UART/USART

Peripherals

Brown-out Detect/Reset, POR, PWM, Temp Sensor, WDT

Number Of I /o

Ram Size

4.25K x 8

Voltage - Supply (vcc/vdd)

2.7 V ~ 3.6 V

Data Converters

A/D 8x8b, 13x12b; D/A 2x10b, 2x12b

Oscillator Type

Internal

Operating Temperature

-40°C ~ 85°C

Processor Series

C8051F0x

Core

8051

Data Bus Width

8 bit

Data Ram Size

4.25 KB

Interface Type

CAN/SMBus/SPI/UART

Maximum Clock Frequency

25 MHz

Number Of Programmable I/os

Number Of Timers

Operating Supply Voltage

2.7 V to 3.6 V

Maximum Operating Temperature

+ 85 C

Mounting Style

SMD/SMT

3rd Party Development Tools

PK51, CA51, A51, ULINK2

Development Tools By Supplier

C8051F040DK

Minimum Operating Temperature

- 40 C

On-chip Adc

8-ch x 8-bit or 13-ch x 12-bit

On-chip Dac

2-ch x 12-bit

No. Of I/o's

Ram Memory Size

4352Byte

Cpu Speed

25MHz

No. Of Timers

Rohs Compliant

Yes

Data Rom Size

64 KB

A/d Bit Size

12 bit

A/d Channels Available

Height

1 mm

Length

14 mm

Supply Voltage (max)

3.6 V

Supply Voltage (min)

2.7 V

Width

14 mm

Package

100TQFP

Device Core

8051

Family Name

C8051F04x

Maximum Speed

25 MHz

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

For Use With

336-1205 - DEV KIT FOR F040/F041/F042/F043

Eeprom Size

Lead Free Status / Rohs Status

Lead free / RoHS Compliant

Other names

336-1204

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Current page: 52 of 328
Download datasheet (3Mb)

C8051F040/1/2/3/4/5/6/7

5.2.

The High Voltage Difference Amplifier (HVDA) can be used to measure high differential voltages up to 60 V

peak-to-peak, reject high common-mode voltages up to ±60 V, and condition the signal voltage range to be

suitable for input to ADC0. The input signal to the HVDA may be below AGND to –60 volts, and as high as

+60 volts, making the device suitable for both single and dual supply applications. The HVDA provides a

common-mode signal for the ADC via the High Voltage Reference Input (HVREF), allowing measurement

of signals outside the specified ADC input range using on-chip circuitry. The HVDA has a gain of 0.05 V/V

to 14 V/V. The first stage 20:1 difference amplifier has a gain of 0.05 V/V when the output amplifier is used

as a unity gain buffer. When the output amplifier is set to a gain of 280 (selected using the HVGAIN bits in

the High Voltage Control Register), an overall gain of 14 can be attained.

The HVDA uses four available external pins: +HVAIN, –HVAIN, HVCAP, and HVREF. HVAIN+ and HVAIN-

serve as the differential inputs to the HVDA. HVREF should be used to provide a common mode reference

for input to ADC0, and to prevent the output of the HVDA circuit from saturating. The output from the

HVDA circuit as calculated by Equation 5.1 must remain within the “Output Voltage Range” specification

listed in Table 5.3. The ideal value for HVREF in most applications is equal to 1/2 the supply voltage for the

device. When the ADC is configured for differential measurement, the HVREF signal is applied to the AIN-

input of the ADC, thereby removing HVREF from the measurement. HVCAP facilitates the use of a capac-

itor for noise filtering in conjunction with R7 (see Figure 5.3 for R7 and other approximate resistor values).

Alternatively, the HVCAP could also be used to access amplification of the first stage of the HVDA at an

external pin. (See Table 5.3 on page 68 for electrical specifications of the HVDA.)

Note: The output voltage of the HVDA is selected as an input to the AIN+ input of ADC0 via its analog multiplexer

HVAIN+

HVAIN-

(AMUX0). HVDA output voltages outside the ADC’s input range will result in saturation of the ADC input. Allow

for adequate settle/tracking time for proper voltage measurements.

High-Voltage Difference Amplifier

Figure 5.3. High Voltage Difference Amplifier Functional Diagram

Resistor values are

Equation 5.1. Calculating HVDA Output Voltage to AIN+

approximate

k

100k

OUT

5k





HVAIN+

HVREF



–

Rev. 1.5



HVAIN-

HVA0CN



 Gain

5k



HVCAP

Gain Setting

HVREF

(To AMUX0)

Vout

C8051F040-GQ Silicon Laboratories Inc, C8051F040-GQ Datasheet - Page 52

C8051F040-GQ

Specifications of C8051F040-GQ

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