6 10 MHz if Circuit Main Unit | Icom IC-910H guide

4-1-6 10 MHz IF CIRCUIT (MAIN UNIT)

The 10 MHz IF signal from the mixer circuit is passed through a monolithic filter (Fl51 [Main], Fl651 [Sub]) to sup- press out-of-band signals. The filtered signal is amplified at the IF amplifier (Q51 [Main], Q651 [Sub]). The IF amplifier provides 20 dB gain.

The amplified signal is then applied to the different circuits depending on the selected mode.

(1) FM mode

The signal is applied to an FM IF IC pin 16 (IC401 [Main] or IC951 [Sub]).

(2) SSB and CW mode

The signal is passed through a 10 MHz IF filter (FI151/10.85 MHz [Main] or Fl751/10.95 MHz [Sub]) or optional CW nar- row filters. The filtered signal is amplified at the IF amplifiers (Q350–Q352 [Main] or Q850–Q852 [Sub]) and then applied to a demodulator circuit.

4-1-7 DEMODULATOR CIRCUIT (MAIN UNIT)

(1) FM mode

The 10 MHz IF signal from an IF amplifier (Q51 [Main] or Q651 [Sub]) is applied to the mixer section of the FM IF IC (IC401 [Main], IC951 [Sub], pin 16), and is mixed with a LO signal (10.395 MHz [Main], 10.495 MHz [Sub]) to produce a 455 kHz IF signal. The LO signal is generated by the BFO circuit (PLL unit; IC601 [Main], IC701 [Sub]).

The FM detector circuit employs the quadrature detection method, which uses a ceramic discriminator (X401 [Main], X951 [Sub]) for phase delay to obtain a non-adjusting circuit.

The detected signals are output from pin 9, and applied to the squelch control and center indication detector circuits, etc.

(2) SSB and CW modes

The amplified signal from the IF amplifier circuit (Q51 [Main], Q651 [Sub]) is applied to the balanced mixer circuit (IC351 [Main], IC851 [Sub]) to demodulate into AF signals. Demodulated audio signals are output from pin 1, and applied to the squelch control gate (IC452 [Main], IC1002 [Sub]).

BFO circuit (PLL unit; IC601 [Main] and IC701 [Sub]) gener- ates BFO signals for using in the balanced mixers.

•BFO frequencies

Mode	for MAIN band	for SUB band

USB	10.8485 MHz	10.9485 MHz

LSB	10.8515 MHz	10.9515 MHz

CW	10.8483 MHz	10.9483 MHz

4-1-8 SQUELCH CONTROL CIRCUIT (MAIN UNIT)

The demodulated AF signals from the balanced mixer circuit or FM IF IC are applied to the squelch control gate (IC452 [Main], IC1002 [Sub]). This consists of 4 analog switches which are selected with a mode signal and squelch control signal from the CPU (DISPLAY board; IC1) via the expander IC (IC1491). The switched AF signals are applied to the AF circuit.

4-1-9 SQUELCH CIRCUIT (MAIN UNIT)

(1) FM mode

A squelch circuit cuts out AF signals when no RF signal is received or the S-meter signal is lower than the [SQL] con- trol setting level. By detecting noise components in the AF signals, the CPU switches the squelch control gate.

A portion of the AF signals from the FM IF IC pin 9 (IC401 [Main], IC951 [Sub]) passes through the active filter section of FM IFIC (pin 8). The active filter section amplifies and fil- ters noise components. The filtered signals are applied to the noise detector section for conversion into DC voltage and output from pin 14 (IC401 [Main], IC951 [Sub]) as the “NSQM [Main]/NSQS [Sub]” signal. The “NSQM [Main]/ NSQS [Sub]” signal is applied to the DISPLAY board.

The DC voltages are passed through the analog multiplexer (DISPLAY board; IC5, pins 15 and 2) and then applied to the CPU (DISPLAY board; IC1, pins 93, 94) via the MP1Y and MP1X signal lines. The [SQL] level signal is also applied to the CPU via the analog multiplexer (DISPLAY board; IC3, pins 14, 5) as a reference voltage for comparison with the noise signals. Also, an S-meter signal is applied to the CPU from FM IF IC pin 12 (IC401 [Main], IC951 [Sub]) via the meter amplifier (IC1804c [Main], IC1804a [Sub]) and analog multiplexer (DISPLAY board; IC4, pins 12 and 1). The CPU compares these signals, then outputs a control signals to the squelch control gate.

(2) SSB and CW modes

The squelch circuit mutes audio output when the S-meter signal is lower than the [SQL] control setting level.

A portion of the 10 MHz IF signal from the IF amplifier (Q352 [Main], Q852 [Sub]) is converted into DC voltage at the AGC detector (D303, Q305 [Main], D902 Q901 [Sub]) and ampli- fied at the meter amplifier (IC1804d [Main] or IC1804b [Sub]). The amplified signal is passed through the analog multiplexer (DISPLAY board; IC4, pins 12 and 1) via the SMLM [Main]/ SMLS [Sub] signals and then applied to the CPU (DISPLAY board; IC1). The CPU outputs control sig- nals to the squelch control gate when the S-meter signal is low level.

4-1-10 AF AMPLIFIER CIRCUIT (MAIN UNIT)

The AF amplifier circuit amplifiers the demodulated signals to drive a speaker. For the separate speaker function, a stereo power amplifier is used.

AF signals from the squelch control gate are passed through the AF filter (IC451a [Main], IC1001a [Sub]) and AF pre- amplifier (IC451b [Main], IC1001b [Sub]) and then amplified at the voltage controlled amplifier (VCA: IC1808 [Main], IC1809 [Sub]) which functions as a volume control using the [AF] control signal. The amplified AF signals are applied to the AF power amplifier circuit (IC1852, pin 2 [Main], pin 5 [Sub]).

The amplified audio signals of SUB band are output from pin 7, and are applied to the external speaker jack for the SUB band (J1852) via the [PHONE] jack (JACK board; J1). When no plug is connected to the jack, the signals are fed back to the MAIN band audio. The mixed audio is applied to the internal speaker via the [PHONE] jack and external speaker jack for the MAIN band (J1851).

4 - 2

IC-910H specifications

The Icom IC-910H is a highly regarded and versatile transceiver that is designed for amateur radio operators who are particularly interested in V/UHF and microwave communications. Known for its exceptional performance, the IC-910H encompasses a suite of features that make it a standout choice for both casual and dedicated hams.

One of the main features of the IC-910H is its dual-band capability, allowing for simultaneous operation on both 144 MHz (2 meters) and 430 MHz (70 centimeters) bands. This dual operation enables users to engage in various communication modes, including SSB, CW, FM, and digital. Its high frequency stability ensures that users can rely on the transceiver for accurate and consistent transmissions.

The IC-910H is equipped with a high-performance 10 MHz IF filter that improves selectivity and reduces adjacent channel interference. The optional 1.2 GHz module enhances the transceiver’s capabilities, allowing operators to venture into microwave frequencies. This expandability is a significant advantage for users who wish to progress in their amateur radio pursuits.

Another notable aspect of the IC-910H is its large, easy-to-read LCD display, which features various color options for enhanced visibility. The front panel layout is user-friendly, providing quick access to important controls and functions. The built-in DSP (Digital Signal Processing) technology offers noise reduction and filtering capabilities, significantly improving overall audio quality and making weak signals more intelligible.

The transceiver also includes extensive memory functions, with up to 1,000 memory channels available for storing frequencies, modes, and operational settings. Additionally, it supports CTCSS and DCS tones, which facilitate the use of repeater systems and private group communications.

In terms of build quality, the IC-910H features a robust construction designed for durability and long-term use. Its efficient power supply management ensures excellent performance while minimizing heat generation, making it suitable for extended operating sessions.

Overall, the Icom IC-910H is a powerful and feature-rich transceiver that is favored by many amateur radio enthusiasts. With its versatile operating modes, advanced filtering capabilities, and clear display, it stands out as a reliable tool for both casual operators and serious DXers. Its well-thought-out design and comprehensive features make it a valuable addition to any ham's station collection.