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In telephony, on-hook and off-hook are two states of a communication circuit. On subscriber telephones the states are produced by placing the handset onto or off the hookswitch. Placing the circuit into the off-hook state is also called seizing the line. Off-hook originally referred to the condition that prevailed when telephones had a separate earpiece (receiver), which hung from its switchhook until the user initiated a telephone call by removing it. When off hook the weight of the receiver no longer depresses the spring-loaded switchhook, thereby connecting the instrument to the telephone line.

Off-hook

[edit]
Off hook telephone.

The term off-hook has the following meanings:

  • The condition that exists when a telephone or other user instrument is in use, i.e., during dialing or communicating.
  • A general description of one of two possible signaling states at an interface between telecommunications systems,[1] such as tone or no tone and ground connection versus battery connection. Note that if off-hook pertains to one state, on-hook pertains to the other.
  • The active state (i.e., a closed loop (short circuit between the wires) of a subscriber line or PBX user loop)
  • An operating state of a communications link in which data transmission is enabled either for (a) voice or data communications or (b) network signaling.[2][3]

On an ordinary two-wire telephone line, off-hook status is communicated to the telephone exchange by a resistance short across the pair. When an off-hook condition persists without dialing, for example because the handset has fallen off or the cable has been flooded, it is treated as a permanent loop or permanent signal.

The act of going off-hook is also referred to as seizing the line or channel.

On-hook

[edit]
On hook telephone handset

The term on-hook has the following meanings:

  • The condition that exists when a telephone or other user instrument is not in use, i.e., when idle waiting for a call. Note: on-hook originally referred to the storage of an idle telephone receiver, i.e., separate earpiece, on a switchhook. The weight of the receiver depresses the spring-loaded switchhook thereby disconnecting the idle instrument (except its bell) from the telephone line.
  • One of two possible signaling states, such as tone or no tone, or ground connection versus battery connection. Note: if on-hook pertains to one state, off-hook pertains to the other.
  • The idle state, i.e., an open loop of a subscriber line or PBX user loop.
  • An operating state of a telecommunication circuit in which transmission is disabled and a high impedance, or "open circuit", is presented to the link by the end instrument(s). Note: during the on-hook condition, the link is responsive to ringing signals.

The act of going on-hook is also referred to as releasing the line or channel, and may initiate the process of clearing.

See also

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References

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

On- and off-hook

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from Grokipedia
In telephony, on-hook and off-hook are fundamental states that describe whether a telephone device is idle or actively connected to a communication circuit. The on-hook state occurs when the handset rests on its cradle or base, opening the electrical circuit (with typical line voltage around -48 V DC) to disconnect the phone from the line, thereby preventing outgoing calls while permitting the ringer to signal incoming ones. Conversely, the off-hook state is activated by lifting the handset from the cradle or pressing a talk button on cordless or mobile devices, which closes the circuit, seizes the telephone line from the central exchange, and delivers a dial tone to initiate or receive calls. These states have been integral to telephone operation since the device's invention in the 1870s, originating from the physical design where the receiver "hung" on a hook to rest. The transition between on-hook and off-hook is controlled by the hook switch (also known as the switchhook), a mechanical or electronic component embedded in the phone's cradle that detects the handset's position. In traditional analog telephones, the off-hook state closes the local loop circuit, drawing a typical DC current of 20 to 50 milliamperes at 6 to 12 volts from the central office battery supply, signaling the exchange that the line is in use and suppressing the ringer. These principles persist in modern telephony, including digital private branch exchanges (PBXs) and Voice over IP (VoIP) systems, where on-hook and off-hook are implemented as software-mediated signals for call control, though without the physical loop current. The terminology remains standard across global telecommunication protocols, ensuring compatibility in hybrid analog-digital environments.

Definitions and Basics

In analog POTS systems, the following describe the fundamental on-hook and off-hook states.

Off-hook State

In , the off-hook state refers to the active condition that occurs when a handset is lifted from its hookswitch, closing the local circuit loop between the tip and ring conductors and thereby signaling the that the subscriber intends to place a call. This action, known as line seizure, completes the DC path and alerts the central office (CO) to allocate resources for the connection. The term "off-hook" originates from early designs, where the receiver was physically suspended on a hook; lifting it disconnected the idle state and initiated service by mechanically closing the switch. Upon going off-hook, the draws loop current from the exchange battery, typically ranging from 20 to 50 mA depending on line length and equipment resistance, which powers the telephone's speech network and establishes a two-way audio path by coupling the hybrid transformer to the line. This current flow also disables the ringing circuit, preventing further incoming call alerts while the line remains seized. The CO responds by providing to indicate readiness for dialing. The exchange detects the off-hook condition by monitoring for loop current flow above a threshold (typically 20-25 mA), confirming the loop closure and distinguishing it from the high-impedance on-hook idle state. If the off-hook persists without dialing activity for an extended period (typically 30-60 seconds), the exchange may issue a receiver off-hook (ROH) warning tone to alert the user.

On-hook State

In telephony, the on-hook state refers to the condition where the telephone handset is placed on the hookswitch, thereby opening the local loop circuit and indicating to the central office exchange that the line is and available. This physical action of the hookswitch mechanically interrupts the (DC) path between the tip and ring conductors of the subscriber line. A primary effect of the on-hook state is that the telephone presents an open circuit at DC, resulting in very —typically exceeding 400 kΩ—to prevent any DC loop current from flowing and to block audio transmission over the line. However, this configuration still permits the passage of (AC) ringing signals, which are superimposed on the line by the exchange, without closing the DC loop. These ringing signals consist of 40–90 V AC at 20 Hz in North American systems, enabling the ringer to activate while maintaining the status. The detects the on-hook state by monitoring the absence of DC loop current across the line, which typically ranges from 20–120 mA when off-hook; this open-circuit condition signals the exchange to release the line for other calls or to initiate incoming ringing. During an incoming call, the exchange applies the AC ringing voltage to the line while the hookswitch remains open for the voice path, but the ringer circuit—connected in series with a —temporarily bridges the line for AC detection and activation without seizing the full DC loop or transitioning to off-hook. The on-hook mechanism originated in the 1870s with the development of early switchhooks, such as the automatic switch patented by Hilborne Roosevelt in 1879, which physically separated the receiver to break the circuit and standardized the idle state in nascent telephone systems. This innovation eliminated manual switching and became integral to commercial telephones introduced by the in 1878. The off-hook state represents the inverse transition, occurring when the handset is lifted to close the loop.

Historical Development

Origins in Early Telephony

The concepts of on-hook and off-hook states in originated in the 1870s amid the rapid development of the following Alexander Graham Bell's foundational U.S. Patent 174,465 for "Improvement in Telegraphy," granted on March 7, 1876, which enabled voice transmission over wires. Early telephone designs integrated a switchhook to cradle the receiver—initially a combined earpiece and transmitter—doubling as a simple circuit breaker to disconnect the line when not in use, preventing unintended connections and conserving battery power at the nascent central offices. further advanced practical telephony in 1877 by patenting an improved carbon-button transmitter that amplified voice signals, facilitating clearer communication in these early hook-based systems. A key advancement came with the automatic switch-hook, patented by inventor and organ builder Hilborne L. Roosevelt under U.S. Patent 215,837 for "Improvement in Telephone-Switches," issued on May 27, 1879, based on an application filed October 3, 1877. This device allowed the circuit to open and close automatically upon lifting or replacing the receiver, eliminating the need for manual toggles and improving usability in the growing network of exchanges. Roosevelt's design gained recognition for its role in standardizing subscriber-end control, though multiple inventors, including Bell's associate , claimed contributions to similar mechanisms during this period. The early mechanism relied on a gravity-fed supporting the receiver's weight, which depressed a spring-loaded metal contact to open the circuit in the on-hook position; lifting the receiver released the spring, closing the contact and completing the loop for voice transmission or magneto-generated ringing signals to alert the operator at the exchange. In 1877, practical implementations of this hookswitch appeared in models produced by , the primary manufacturer for Bell's systems, marking a pivotal step toward reliable residential and business use. Initial challenges included the lack of standardized detection for hook states across varying regional systems, requiring human operators to manually monitor lines for busy signals or requests through direct intervention, such as listening for clicks or using test sets—a labor-intensive process that persisted until the advent of automatic exchanges in the 1890s. As automation advanced, these foundational hook mechanisms laid the groundwork for more refined analog systems in the late 19th century.

Evolution Through Analog Systems

The refinement of on- and off-hook mechanisms in analog telephony during the focused on enhancing reliability, , and within step-by-step switching systems. By the early 1900s, the Strowger automatic exchange, introduced in 1891, employed loop closure—where lifting the receiver (off-hook) completed the electrical circuit to signal the exchange—for detecting subscriber initiation of calls, replacing manual operator intervention and enabling scalable automatic routing. This loop-based detection became foundational, as off-hook states closed the subscriber line circuit to alert the central office, a practice formalized in early standards that supported growing urban networks. In the 1920s, the further standardized these processes through common-battery systems, where the hookswitch automated circuit closure upon off-hook to provide and supervisory signals, ensuring consistent operation across manual and exchanges. Key advancements included the integration of dial detection, which relied on timed interruptions from hookswitch flashes during rotary dialing; each digit corresponded to a specific number of brief loop openings (e.g., 10 s per second), allowing exchanges to interpret and route calls without electronic computation. By , anti-tinkle circuits were introduced to suppress unintended bell ringing from transient off-hook conditions during dialing or external disturbances, often combining with speech-muting functions to maintain clear audio paths in multi-party lines. World War II accelerated adaptations for rugged field use, with military emphasizing reliable hookswitch designs in devices like the EE-8 , adopted in the late and standardized for tactical reliability amid harsh conditions, influencing civilian analogs. These efforts culminated in the 1980s peak of analog systems, where Federal Standard 1037C—published in 1996 but drawing on 1984 practices—specified loop supervision for (POTS) lines, defining on-hook as an open loop for idle states and off-hook as a closed loop for active supervision via current detection. Analog reached its zenith around the 1984 divestiture, which dismantled the Bell monopoly and separated services into regional companies, spurring competition but also hastening the transition to digital technologies as infrastructure investments shifted.

Technical Implementation

Analog Circuit Mechanisms

In traditional analog telephone circuits, the on- and off-hook states are managed through a two-wire subscriber loop consisting of the tip and ring conductors, with (DC) power supplied by a battery at the central office, typically providing -48 V DC. When the telephone is on-hook, the hookswitch contacts remain open, presenting a high DC impedance across the loop, approximately 10 MΩ or greater, which prevents significant current flow and allows the central office to detect an idle state. Off-hook occurs when the user lifts the , closing the hookswitch and dropping the loop resistance to around 600 Ω, completing the circuit and drawing loop current to signal the central office for service. The loop current II in the off-hook state follows , given by the equation I=VRline+Rphone,I = \frac{V}{R_{\text{line}} + R_{\text{phone}}}, where VV is the central battery voltage (approximately 48 V DC), RlineR_{\text{line}} is the resistance of the subscriber loop (varying by length, e.g., around 300 Ω for shorter lines or up to 900 Ω for average loops), and RphoneR_{\text{phone}} is the telephone set's DC resistance (typically 300–600 Ω). For example, with a total loop resistance of around 1200 Ω under average conditions, this results in a typical loop current of about 40 mA, sufficient to operate the telephone's components while staying within the system's 20-120 mA range. The supervisory at the central office monitors this current to confirm the off-hook condition and initiate dialing tone. Key components include the hookswitch, a double-pole double-throw mechanical device in the cradle that connects the transmitter, receiver, and line when closed (off-hook) and isolates them when open (on-hook). In parallel with the hookswitch path, the circuit—often a high-impedance coil or capacitor-based network—allows AC ringing voltage (typically 20 Hz at 86 V rms superimposed on the DC) to alert the user without drawing DC current during the on-hook state. At the central office, the supervisory relay energizes upon detecting loop current, managing call supervision and preventing unauthorized access. Fault handling in these circuits distinguishes between loop start and ground start configurations. Loop start, common for residential lines, relies on simple loop closure for signaling but can suffer from (simultaneous seizure by both ends); ground start, used for business trunks and PBX, mitigates this by grounding one conductor (e.g., ring) to request service, providing clearer status detection. To address permanent loop conditions, such as a stuck hookswitch, the central office implements timeout mechanisms; for example, after a period of continuous off-hook without progress, it may trigger a to release the line and alert maintenance. These mechanisms ensure reliable operation, with the standard voice-frequency impedance matched at 600 Ω for optimal transmission, as detailed in Bell System engineering practices.

Digital and VoIP Adaptations

In digital telephony, such as Integrated Services Digital Network (ISDN), on- and off-hook states are managed through signaling messages on the dedicated D-channel, eliminating the need for physical loop closure. The D-channel, with a bitrate of 16 kbit/s for (BRI) or 64 kbit/s for (PRI), transmits control information including supervision signals between the and the network. An off-hook condition is initiated by the terminal sending a SETUP message to seize a B-channel for the call, while on-hook is signaled via a RELEASE or DISCONNECT message to clear the connection. Similar channel-based signaling applies to (DSL) implementations of digital (POTS), where packetized voice services use protocol messages to emulate hook states without analog loops, often via standards like V5.2 for access networks. Voice over IP (VoIP) systems adapt these states using the Session Initiation Protocol (SIP) for call control. Off-hook is represented by the user agent sending an INVITE request to establish a session, which, upon acceptance, activates a Real-time Transport Protocol (RTP) stream for bidirectional audio. The on-hook state triggers a BYE request to terminate the session and release resources. To support legacy analog telephones in digital environments, Analog Telephone Adapters (ATAs) detect the physical hookswitch position and convert it into equivalent digital signals, such as SIP messages, while supplying the traditional approximately 48 V DC open-loop voltage and 20-50 mA off-hook current to maintain compatibility. By 2025, advancements in allow browser-based emulation of hook states through APIs, where an off-hook event might invoke the RTCPeerConnection interface to negotiate and start media streams without native hardware. In 5G mobile networks, VoIP relies on the (IMS) for state management, employing SIP signaling over the 5G core to handle transitions like session initiation and release. These adaptations introduce challenges, including detection latency of 100-200 ms for hook state changes in VoIP—due to network propagation, processing, and protocol handshakes—contrasted with near-instantaneous analog responses. Security is addressed through (TLS) for SIP signaling, encrypting messages to mitigate eavesdropping and man-in-the-middle attacks.

Signaling and Detection

Loop Current and Resistance Detection

In loop start signaling, the predominant method for supervising analog telephone lines, the central office detects an off-hook condition through the flow of DC loop current when the telephone's switchhook closes the circuit, completing the loop between the tip and ring conductors. Conversely, the on-hook state is identified by the absence of this current, as the open switchhook interrupts the path. The central office provides a nominal -48 V DC battery across the line for , resulting in typical off-hook currents of 20-50 mA depending on loop length and telephone impedance. Detection relies on resistance thresholds measured at the central : an off-hook is triggered when the total loop resistance drops below approximately 1500 Ω (per Telcordia TR-57 standard), allowing sufficient current to flow and indicating line use; release occurs when resistance exceeds 10 kΩ on-hook, producing negligible current (less than 5 mA). These values account for the set's typical off-hook DC resistance of around 500 Ω plus line , while on-hook presents a high-impedance path due to the ringer's series blocking DC. is facilitated by high-impedance bridge circuits at the central , which monitor or current without significantly loading the line. A variant, ground start signaling, is employed in private branch exchange (PBX) environments where multiple devices share a line. Here, off-hook initiation grounds the ring conductor first via the telephone or key system, signaling intent to seize the line and avoiding simultaneous access conflicts () that can occur in loop start. The central office responds by grounding the tip and applying battery, completing supervision similarly to loop start but with enhanced coordination for shared trunks. Ringing integrates with these mechanisms by superimposing a 20 Hz AC signal, typically 75-105 Vrms, onto the DC battery during incoming calls to activate the telephone's ringer. The ringer, a high-impedance electromechanical or electronic device, responds to this low-frequency AC while blocking DC. An off-hook answer during ringing shunts the ringer by closing the switchhook, abruptly reducing loop resistance and drawing DC current, which the central office detects via the bridge to trip the ring signal and connect the call. These electrical detection methods are vulnerable to noise, such as lightning-induced transients or , potentially causing erroneous seizures or releases. Though largely supplanted by digital protocols in urban and modern networks since the 2000s, loop current and resistance detection remains in use for rural (POTS) lines as of 2025, supporting legacy infrastructure where fiber or VoIP deployment lags.

Modern Protocol-Based Signaling

In modern , protocol-based signaling has largely supplanted analog electrical detection for on- and off-hook states, particularly in IP-based (VoIP) and cellular networks. The (SIP), defined in RFC 3261, serves as the primary mechanism for VoIP call control, where an off-hook event—such as a user lifting a or activating a —triggers the initiation of a session through an INVITE message sent from the client to the proxy or directly to the callee. This INVITE carries (SDP) attributes in its body, as specified in RFC 4566, which describe the media capabilities and establish the offer/answer model to negotiate session parameters like audio codecs and ports. Conversely, an on-hook event, indicating call termination, prompts the user agent to send a BYE message, which tears down the session and releases resources across the network. As an alternative to SIP, the protocol suite, standardized by the , provides similar functionality through its H.225.0 call signaling component, where off-hook signaling equates to the transmission of a Setup message from the calling endpoint to initiate a connection. For networks employing a for address resolution and bandwidth management, H.323 utilizes Registration, Admission, and Status (RAS) messages to handle endpoint registration and permission requests prior to call setup. On-hook termination in H.323 involves a Release Complete message exchanged between endpoints to cleanly end the call and free up channels. While H.323 was prominent in early VoIP deployments, its usage has declined in favor of SIP due to the latter's simpler architecture and broader interoperability. In cellular networks, particularly those leveraging the (IMS) in architectures, off-hook signaling aligns with SIP procedures transported over IP, as outlined in 3GPP TS 23.228, where a user-initiated call setup sends an INVITE to establish a session with the called party via the IMS core. This process activates the bearer path for media flow, with equivalents to off-hook manifested as "call setup" procedures that allocate resources like QoS flows in the core. On-hook events trigger session release through a BYE message, which deactivates the bearer and notifies the network to deallocate paths, ensuring efficient in high-mobility environments. The transition from legacy Signaling System No. 7 (SS7) to IP-based protocols has further modernized hook state signaling, with the Initial Address Message (IAM) in SS7's ISUP—traditionally used to signal off- and seize a circuit—now transported via protocols like M3UA over SCTP, as defined in RFC 4666, in hybrid networks of the . This migration enables seamless integration of SS7 elements with IP cores, reducing infrastructure costs while preserving compatibility for call initiation and release. By 2025, (RCS), governed by specifications, extends beyond binary on/off- states by incorporating presence-based indicators, allowing users to signal availability through rich metadata like "busy" or "available for chat" integrated into SIP headers for enhanced contextual awareness in messaging and voice sessions.

Applications and Modern Usage

Residential and Subscriber Lines

In residential and subscriber lines, the Plain Old Telephone Service (POTS) remains a foundational setup for individual home telephony, utilizing a standard two-wire configuration known as tip and ring to deliver DC power for the telephone device and AC signaling for ringing. When a user lifts the to go off-hook, this action creates a low-resistance loop that seizes the line from the central office, allowing subsequent dialing via Dual-Tone Multi-Frequency (DTMF) tones generated by the telephone to initiate a call. On-hook status, conversely, maintains an open circuit with high impedance, enabling services like to transmit data bursts—typically (FSK) signals—between the first and second rings without interference from the connected device. Hybrid VoIP systems in residential settings often incorporate cordless DECT (Digital Enhanced Cordless Telecommunications) phones, where the base station emulates traditional hook states to bridge analog-like user interactions with internet-based calling. In these setups, going off-hook on the signals the base to initiate a () call over or Ethernet, converting the physical action into digital VoIP signaling without requiring a direct POTS connection. Manufacturers like Grandstream and provide such DECT IP phones, supporting mobility within the home while preserving familiar on- and off-hook behaviors for users transitioning from legacy lines. Consumer-oriented features in residential telephones leverage on- and off-hook transitions to enhance usability, such as the flash hook—a brief on-hook pulse (typically 0.5 to 1 second) during an active off-hook call—to activate , placing the current conversation and switching to the incoming line. Speakerphones in these systems often include auto-answer capabilities, automatically going off-hook and routing audio to the built-in speaker upon detecting an incoming ring signal, which is particularly useful for hands-free operation in environments. Business PBX extensions represent more complex variants of these mechanisms, incorporating additional signaling for multi-line coordination. As of 2025, landline usage in U.S. households has declined significantly, with fewer than 30% maintaining POTS connections amid the rise of and VoIP alternatives, according to (FCC) data reflecting broader shifts toward mobile and internet-based . In 2025, the FCC issued orders accelerating the retirement of copper-based POTS networks, streamlining transitions to digital services and allowing carriers like to cease new POTS orders after October 2025. Softphones on smartphones further emulate hook functions through taps, such as swiping to answer (off-hook equivalent) or ending calls (on-hook), integrating these legacy concepts into modern apps. Some residential telephones and VoIP adapters, particularly assistive devices, incorporate off-hook timeouts, automatically restoring on-hook status after a preset duration (e.g., 20-30 seconds) to free the line and prevent prolonged ties that could block emergency calls.

Business Systems and PBX Integration

In business environments, Private Branch Exchange (PBX) systems manage on- and off-hook states across multiple extensions using internal loops, where an extension going off-hook closes the loop to alert the PBX controller. This internal signaling allows the PBX to route calls efficiently among extensions without immediately involving external lines. For outgoing calls to the central office (CO), the PBX seizes a trunk by simulating an off-hook condition on the selected trunk line, effectively cascading the extension's state to the external network. To prevent signaling conflicts known as glare—where both ends of a trunk attempt simultaneous seizure—many PBX trunks employ ground-start signaling. In ground-start setups, the PBX briefly grounds the ring conductor before fully closing the loop, allowing the CO to detect and respond without collision, a common issue in loop-start configurations for high-traffic enterprise lines. Trunk interfaces in PBX systems often use E&M signaling for reliable on- and off-hook detection between the PBX and CO or other switches. In E&M, the PBX grounds the E (Ear) lead to indicate off-hook and seizure, while the on-hook state leaves the E lead open; the M (Mouth) lead handles the reverse signaling from the far end. This setup supports wink signaling, where the terminating side briefly grounds its E lead (140-290 ms) to confirm readiness after detecting seizure, enabling precise timing for dial tone or further call setup. Hookswitch integration in PBX extensions enhances call handling by linking on- and off-hook transitions to features like hold and transfer; for instance, a brief hookswitch flash places a call or initiates a transfer to another extension without disconnecting. Busy lamp fields (BLFs) further utilize these states by visually indicating extension availability—such as steady illumination for off-hook/busy or flashing for ringing—allowing operators or users to monitor and intervene in real-time across the system. As of 2025, cloud-based PBX solutions like emulate traditional on- and off-hook behaviors through API-driven signaling and SIP gateways, translating legacy analog states into digital equivalents for seamless integration. Hybrid deployments support analog-digital transitions by using gateways to maintain compatibility with existing PBX trunks, ensuring off-hook events from legacy extensions propagate to services for external calls. Large-scale PBX systems in enterprises can accommodate over 1,000 extensions and trunks, with off-hook events from internal lines cascading through shared trunk pools to the CO for external connectivity, optimizing resource use in high-volume environments.

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