By Bitget CEO Sandra Derivatives products have been playing a
significant role in the global finance market. As the concept of
decentralization experienced rapid development and gradually gained
wider recognition among users in recent years, decentralized
derivatives trading has naturally become one of the most promising
markets. So is it possible for decentralized derivatives exchanges
to disrupt their centralized counterparts in the short to medium
term? Here are some of my thoughts and I’d like to share them with
you. In the traditional financial sector, derivatives are
classified into the following categories by different product
forms: forwards, futures, options and swaps. Their underlying
assets can be stocks, interest rates, currencies and commodities.
The notional value of the overall derivatives market in 2020 is
roughly $840 trillion, compared to $56 trillion for the equity
market and $119 trillion for the bond market. And the size of the
derivatives market is four to five times larger than that of its
underlying assets. While in the crypto world, most of the
derivatives transactions happen in centralized exchanges in the
forms of quarterly futures, perpetual futures (also called
perpetual swaps) and options. According to Coingecko, Binance,
OKEx, Huobi, Bybit, FTX, Bitget and BitMEX are the world’s top7
derivatives exchanges. Take Binance as an example, its spot
trading volume in the last 24h reached $23 billion while the
derivatives trading volume hit $77.5, or 3.37 times the former.
Things are quite different in decentralized exchanges (DEX). With a
combined 24-hour trading volume of $1.25 billion for Uniswap V2 and
V3 and $96 million for the decentralized derivatives exchange
represented by Perpetual Protocol, futures trading volume accounts
for only one-fourteenth of spot trading. The world’s top7
derivatives exchanges. Source: Coingecko The volume of derivatives
trading vs. spot trading across different markets. Source:
Foresight Ventures Assuming that decentralized derivatives can also
reach four times the volume of spot trading as in centralized
exchanges, the room for growth is enormous. However, from what we
see now, the business development of decentralized derivatives
exchanges is far from satisfying. Trading data of
decentralized derivatives exchanges. Source: Dune Advantages and
Disadvantages of Decentralized Derivatives Exchanges In the
decentralized world, there are mainly two types of derivatives:
futures and options. Though index products, structured products and
insurances are also derivatives, they are not the focus for our
purpose here. Compared to centralized institutions in the crypto
space, decentralized derivatives exchanges have the following
advantages: Asset custody: The assets of decentralized derivatives
projects are hosted on the chain. It is transparent and traceable,
avoiding irregularities and default risks of centralized
institutions. Fairness: Set by smart contracts in advance, the
trading rules can not be tampered with in the back office,
providing greater fairness for both parties to the transaction.
Self-governance: In decentralized derivatives exchanges, things
like the fees to be charged, coins to be listed and development
plans can all be determined through community governance. People
involved in the decision-making process could enjoy the benefits of
project growth. However, there are also urgent problems to be
solved. Performance: Derivatives trading requires real-time
transactions, which are difficult to achieve through the current
on-chain solutions. Price discovery: Derivatives trading is
extremely price-sensitive. However, the mark prices and transaction
prices are dependent on the prediction of oracles. Risk control:
Liquidation is a major issue for both decentralized and centralized
exchanges. Decentralized platforms also need to address the
on-chain congestion caused by extreme price volatility to ensure
the liquidation process is reasonable and efficient, which is
essential for the continued existence of derivatives platforms.
Cost and liquidity: Margin trading with high leverages demands high
liquidity of underlying assets. The platform needs to avoid the
impact cost of transactions and establish a reasonable fee
schedule. Capital utilization: a core requirement for traders to
participate in derivatives trading is the ability to trade on
margin with additional leverage, but the overcollateralization
mechanism introduced by some synthetic asset projects once again
limits the efficient use of capital. Anonymity: On-chain data are
traceable, yet institutional investors want to keep their positions
and futures contract address anonymous. Different Types of
Decentralized Derivatives Exchanges In today’s market,
decentralized futures derivatives have the largest number of
project types and the most diverse solutions, mainly represented by
perpetual futures, which currently fall into three major genres:
AMM, order book and synthetic assets. AMM represented by Perpetual
Protocol The AMM (Automated Market Making) based exchanges are
mainly reinvented from the AMM model of Uniswap, such as vAMM and
sAMM. It allows traders to interact with the assets in a physical
or virtual asset pool to long or short. GMV Data of mainstream
decentralized derivatives platform. Source: Token terminal This
type is mainly represented by Perpetual Protocol. According to
Messari, Perpetual Protocol takes up 76% of the perpetual futures
market and its revenue size in July was the seventh-largest of all
Defi projects, behind Sushiswap. However, the trading volume and
revenue do not accurately reflect its true market share as it is
difficult to calculate how much is contributed by the wash trading
resulted from the trans-fee mining initiated in February this year.
Based on a virtual liquidity pool called vAMM. The Perpetual
Protocol uses the equation of X*Y=K to simulate pricing. Traders
can input USDC as collateral to the Vault. So external liquidity
providers are not required. It is also a way to mint synthetic
assets. With the only USDC in the pool, there is no actual exchange
between two actual currencies. The amount of funds flowing in and
out of the Vault, as well as the returns, are calculated using a
mathematical formula based on the price of the trading pair at the
time of their entry and exit. Let’s walk through an example trade
explained by the project white paper. X*Y=K,The price ratio of ETH
and USDC is Y/X=100 Assuming there are 10000 USDC in the Vault.
X=100,K=100*10000. Alice uses 100 USDC as the margin to open a 2x
leveraged long position on ETH; After that, the amount of USDC in
the vAMMs will become 10,200 (10,000+100*2), the amount of ETH/USDC
will become 98.04 (100*10,000/10,200), and the position Alices
opens is 1.96 ETH (100-98.04). Following Alice, Bob also uses 100
USDC to open a long position with 2x leverage. His position size
will be 1.89 ETH (98.03-96.15) using the same calculation. Note
that the price of ETH increases due to Alice’s opening, therefore
the average holding cost of Bob is higher than that of Alice. After
Bob gets his long position, the price of ETH further climbs. Alice
closes her position and realizes a profit of 7.84 USDC (10400 –
96.15*10,400/(96.15+1.96)- 200) Seeing Alice makes a profit, Bob
wants to close his position too, only to find out that he lost
-7.84 USDC (10192.15-98.11 * 10192.15 / (98.11+ 1.88)-200) after
closing his position. From the above example, we can see that one
trader’s gain equals another trader’s loss. All traders in the pool
are counterparties with their revenues calculated based on the
virtual AMM model. This model has the following features: AMM model
does not require the use of an external Oracle for price discovery.
Instead, the price will reach equilibrium through the balanced
activities of arbitrageurs between CEX and DEX. Though the approach
can avoid the risk of Oracles, there could be an extreme deviation
between asset prices in the exchange and outside market in the
absence of arbitrageurs, leading to the liquidation of margin
traders. In the Perpetual project, the K-value is a floating value
set by the team. If the K-value is too small, the depth of the pool
will be reduced. But if the value is too large, the price
fluctuation in the exchange will be too minor to match the outside
price. Therefore, the setting of the K value will significantly
impact the operation of the AMM model. In the AMM model, large
orders will incur greater impact costs to the pool, especially for
price-sensitive futures traders, whose revenue will be
significantly influenced by the size and sequence of the orders. To
address the above issues, Perpetual Protocol launched a V2 “Curie”.
The major improvements include: It built Uniswap V3 into the
original vAMM pool and created a liquidity pool in the form of
v-token (such as vETH/vUSDC). When traders deposit USDC to open a
position, the leverage liquidity provider will generate and input
the amount equivalent to that of the position. This is also a way
of minting synthetic assets. The only difference is that it uses a
liquidity pool consisted of actual tokens to replace the original
mathematic formulas. Introducing the role of makers to provide
liquidity management for Uni V3 can improve its liquidity to some
extent. But the liquidity of the pool depends on the funds and
market-making capacity of the makers. The Insurance Fund could be
used to cover abnormal settlements and serve as the counter-party
when there is an imbalance between long and short positions to
provide more liquidity to the pool. It seems that the AMM solution
used by Perpetual V1 can provide unlimited liquidity, but it will
suffer from inevitable impact cost when a larger amount of funds is
involved. The upgraded V2 model is also subject to the ability of
makers. Liquidity providers who employ the active market-making
strategy of Uni V3 may also bear the impermanent losses. Although
the AMM model has tackled the long tail problem of the derivatives
market, its impact cost is still high for large-scale and
price-sensitive traders. Order book model represented by dYdX The
locked amount and profit statistics of dYdX. Source: Token terminal
As one of the earliest trading platforms for decentralized
derivatives, dYdX launched its first BTC-USDC perpetual futures
last May. It went on to co-built a Layer 2 solution for cross
margin perpetuals on the StarkEX engine together with StarkWare
this April. Apart from supporting perpetuals, dYdX also offers
lending, spot trading and margin trading. Its futures trading
volume ranks second in the decentralized perpetuals market,
accounting for 12%. Adopting the order book model with Wintermute
as its leading maker to provide liquidity, dYdX combines off-chain
matching with on-chain settlements. Therefore, the transaction
model is basically the same as CEX, with the transaction price
determined by the market price, which is in turn set by the maker.
According to data released by Wintermute, 95% of the current
transactions on dYdX are quoted by makers, making them the core
strength for order-book-based platforms. This is the reason why
most critics criticize dYdX for being too centralized. The order
book model is very demanding on the performance of matching and
transactions. It basically operates like this: StarkEX will obtain
a sequence from dYdX, runs them internally, and ensures that
everything is checked out and meaningful. Then, it moves the
transaction to the Cairo program. The Cairo compiler will
compile the Cairo program, and then the prover will convert it into
a STARK proof. Then, the proof will be sent on this chain to
the verifier for verification. The proof is legal if it is accepted
by the verifier. So everyone can check the account balance of all
users on Layer 1 but the transaction data is not created on the
chain. In this way, it protects the privacy of the transaction
strategy and reduces transaction costs. At the same time, the gas
fee on Layer2 will be borne by the dYdX team. Users only need to
pay a transaction fee. As Layer2 and other scaling solutions
improve over time, the user experience of order-book transactions
will very much resemble that of a DEX. In addition, more advanced
orders have been launched by dYdX, including market orders, limit
orders, Take profit and Stop loss, Good-Till-Date, Fill Or Kill or
Post-Only, offering traders futures trading services that are
increasingly similar to those of centralized exchanges. For a
future exchange, there are different priorities at various stages.
For example, relying solely on makers is a necessary approach to
maintain liquidity in the early days. As professional investors
entering the market, the entire ecosystem will evolve and become
less centralized. Synthetic assets model represented by Synthetix
The locked amount and profit statistics of Synthetix. Source: Token
terminal As the earliest and largest synthetic assets platform, the
development of Synthetix is well known to most of the readers and
will not be elaborated here. On Synthetix, users stake SNX to
generate sUSD based on a collateralization ratio of 500%, and then
exchange the sUSD into any synthetic assets within the system
through transaction. They can go long on sToken, or go short on
iToken. The assets to be transacted are not limited to
cryptocurrencies, but include Forex, stock and commodities. In our
discussion, synthetic asset is listed as one of the transaction
models for decentralized derivatives because it is also a kind of
futures contract traded with collateral, or margin. The transaction
model of SNX is fairly new in that it introduces the concept of a
“dynamic debt pool”. The debt borne by the users and the system
will change in real-time. When a user stake SNX to mint sUSD, the
sUSD becomes the debt of the system. When the users convert the
sUSD into sToken, the debt of the system will evolve as the value
of the sToken changes. And such debt is shared proportionately by
all users who have staked SNX. Let’s look at an example: Suppose
there are only A and B in the system. They each minted 100 sUSD.
A’s debt B’s debt Total debt Mint 100 sUSD 100 sUSD 100 sUSD
200 sUSD A uses them to buy sBTC; B holds them 100 sUSD 100 sUSD
200 sUSD BTC price doubles(before debt distribution) 200 sUSD 100
sUSD 300 sUSD BTC price doubles(after debt distribution) 150 sUSD
150 sUSD 300 sUSD Eventually, their debts are both 150 sUSD, but
A’s asset value reached 200 sUSD while B’s asset remained 100 sUSD.
At this point, if A sells sBTC to get 200 sUSD, then he will only
need 150 sUSD to redeem SNX, while B will need to buy 50 sUSD
before redemption. From this point of view, Synthetix’s debt pool
model is actually a dynamic zero-sum game. The profit may come from
the rise in the price of one’s own assets, or the fall in the price
of other people’s assets; vice versa. Or we can say, stakers on
Synthetix are actually going long on “their own investment
capability/the investment capability of other participants” You may
also hold sUSD in the long term, but this will put you at the risk
of “I may lose money because other investors are too capable.” As
Taleb says, by staking SNX to generate sUSD, users have skin in the
game. The bold design of risk-sharing turn all users into real
“stakeholders”. Source: Mint Ventures
https://www.chainnews.com/articles/894865830615.htm This bold and
creative design of SNX is essentially similar to the zero-sum game
built in the AMM model. And for vAMM, its process of inputting
virtual assets as per the amount of open positions also resembles
the minting of synthetic assets. The difference is that Synthetix,
fed by an oracle machine, does not have to worry about price
slippage or the flow of assets. In this way, it provides the users
with truly unlimited liquidity. Current Problems for Decentralized
Derivatives Exchanges After illustrating on how decentralized
derivatives products operate, let’s get back to the problems listed
at the beginning of this article. Can they be solved by the above
projects? What’s the future of decentralized derivatives products?
Performance The performance issues are now being partly addressed,
with various decentralized derivatives platforms adopting different
scaling options: Perpetual Protocol uses the sidechain solution
xDai; dYdX adopts Layer2 solution based on ZK-rollup technology to
conduct off-chain matching and on-chain record-keeping; SNX
implements a Layer2 scaling solution “Optimisitc”. These scaling
solutions have addressed the demand for real-time transaction and
the front-run problem during transaction execution. Price Discovery
For the AMM model, prices are mainly defined by assets within the
pool and the equation of x*y=k. The execution price is independent
from an external oracle, but the funding fee uses Chainlink’s price
feed as the index price. The Perpetual V2 also will combine Uniswap
oracle after introducing the liquidity pool of Uni V3. The AMM
model is therefore less susceptible to oracle failures. On dYdX,
three different prices are used: index price, oracle price and
mid-market price. Among them, the index price is maintained by the
dYdX team. It is determined by referencing the prices of 6-7 spot
exchanges and is used to trigger conditional orders. The oracle
price is provided by Chainlink and MakerDao for the calculation of
margins and funding fees. The mid-market price is the price
generated by the order book, also used to calculate the funding
fees. The price discovery model of dYdX is similar to CEX where the
execution price is based on the order book while liquidation price
is determined by the oracle. On the whole, the price of dYdX is
mainly influenced by makers and arbitrageurs, but its liquidation
price may be affected by the risks of oracle malfunction. In
comparison, SNX uses Chainlink decentralized oracles to power all
price feed on its platform, including the transaction price, system
debt and liquidation price. Risk Control We can see that almost all
derivatives exchanges rely on oracle prices for liquidation, which
occurs when the position margin ratio falls to a certain level. In
such cases, the users will be compensated through the mechanism of
Insurance Fund. Given that most of the projects are dependent on
the quotes of Chainlink, the risk of oracle attack seems to be
unavoidable. Moreover, the on-chain liquidation congestion problem
caused by violent price swings remains unsolved, yet it may be
mitigated through scaling solutions in the future. Cost and
Liquidity The problem is twofold: small volume traders need to bear
higher gas fees, and large volume traders have to pay higher impact
costs caused by liquidity. While the former has been partly
resolved through Layer2 solutions, the latter is more complex. It
can be quite difficult to dodge in the AMM model; for platforms
based on order books, it may depend on the market-making capacity
and capital size of the makers; for synthetic assets, the impact
cost of a single trader may be smoothed out if the capital size of
the overall protocol is large enough. In addition, transaction fees
can be another concern for derivatives traders with a higher
turnover rate. From the current statistics, the transaction fees of
DEXes are much higher than those of CEXes. For example, Perpetual
Protocol charges 0.1% for each transaction, while dYdX collects a
maker fee of 0.05% and a taker fee of 0.2% for ordinary users,
compared to 0.02%-0.04% in centralized exchanges. Even though all
the above projects have launched the trans-fee mining feature to
compensate the transaction fees, the final transaction cost in
DEXes is still relatively high. Capital Utilization In terms of
capital utilization, the DEXes based on AMM and order books are not
very different from CEXes. The maintenance margin ratio is 6.25%
for Perpetual Protocol and 7.5% for dYdX. But derivatives exchanges
based on synthetic assets, such as SNX, require a 200%
overcollaterization to avoid liquidation. Though SNX can provide
unlimited liquidity, the overcollaterization mechanism puts
significant restrictions on capital utilization, which goes against
the intention of futures trading. Anonymity The current scaling
solutions of all exchanges are moving most of the transaction data
to off-chain. Take dYdX for example, it uses “zero-knowledge proof”
to protect the privacy of users. It can be expected that the
anonymity of futures will be guaranteed as privacy-focused layer2
solutions improve over time. Conclusion From the above comparison
between decentralized derivatives exchanges, we can see that the
order-book platforms represented by dYdX can better solve the major
pain points of currents derivatives products. Their transaction
models and functions are also more in line with the habits and
needs of derivatives traders. Critics may accuse dYdX of not being
decentralized enough, but actually, it is just a strategic choice
between survival and development at different stages. After all,
the primary goal of a decentralized project is to meet the basic
needs of users, while decentralization could be gradually achieved
by engaging more institutions and diversified participants to
enhance the ecosystem. Like fresh produce in e-commerce faced with
various limitations in products, technology, and channels,
derivatives also find it challenging to break barriers. It is
therefore not likely for decentralized derivatives exchanges to
shake up the dominant position of CEXes. However, with the
development of Layer2 and other scaling solutions, their problems
regarding performance, risk control, transaction cost and anonymity
will be partially solved. It is fair to say decentralized
derivatives exchanges will become the biggest beneficiary of Layer2
technology. From a long-term perspective, derivatives trading is
still one of the most promising segments with unlimited
possibilities.
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